For employment in zone 2 (IEC/EN 60079-10-1) II 3G Ex ec IIC T3 Gc Operating Instructions Installation Instructions Low-voltage motor SIMOTICS FD Type 1MH1 Edition 02/2019 www.siemens.com/drives 05.02.2019 15:55 V11.01 Introduction 1 Safety information 2 Low-voltage motor Description 3 SIMOTICS FD Type 1MH1 Preparations for use 4 Assembly 5 Electrical connection 6 Start-up 7 Operation 8 Maintenance 9 Spare parts 10 Disposal 11 Operating Instructions Installation Instructions For employment in zone 2 (IEC/EN 60079-10-1) II 3G Ex ec IIC T3 Gc Edition 02/2019 Service and Support A Technical data and drawings B Quality documents C Legal information Warning notice system This manual contains notices you have to observe in order to ensure your personal safety, as well as to prevent damage to property. The notices referring to your personal safety are highlighted in the manual by a safety alert symbol, notices referring only to property damage have no safety alert symbol. These notices shown below are graded according to the degree of danger. DANGER indicates that death or severe personal injury will result if proper precautions are not taken. WARNING indicates that death or severe personal injury may result if proper precautions are not taken. CAUTION indicates that minor personal injury can result if proper precautions are not taken. NOTICE indicates that property damage can result if proper precautions are not taken. If more than one degree of danger is present, the warning notice representing the highest degree of danger will be used. A notice warning of injury to persons with a safety alert symbol may also include a warning relating to property damage. Qualified Personnel The product/system described in this documentation may be operated only by personnel qualified for the specific task in accordance with the relevant documentation, in particular its warning notices and safety instructions. Qualified personnel are those who, based on their training and experience, are capable of identifying risks and avoiding potential hazards when working with these products/systems. Proper use of Siemens products Note the following: WARNING Siemens products may only be used for the applications described in the catalog and in the relevant technical documentation. If products and components from other manufacturers are used, these must be recommended or approved by Siemens. Proper transport, storage, installation, assembly, commissioning, operation and maintenance are required to ensure that the products operate safely and without any problems. The permissible ambient conditions must be complied with. The information in the relevant documentation must be observed. Trademarks All names identified by (R) are registered trademarks of Siemens AG. The remaining trademarks in this publication may be trademarks whose use by third parties for their own purposes could violate the rights of the owner. Disclaimer of Liability We have reviewed the contents of this publication to ensure consistency with the hardware and software described. Since variance cannot be precluded entirely, we cannot guarantee full consistency. However, the information in this publication is reviewed regularly and any necessary corrections are included in subsequent editions. Siemens AG Process Industries and Drives Postfach 48 48 90026 NURNBERG GERMANY Document order number: A5E32582260 02/2019 Subject to change Copyright (c) Siemens AG 2018. All rights reserved Table of contents 1 2 Introduction.................................................................................................................................................13 1.1 About these instructions.........................................................................................................13 1.2 Compiling personal documents..............................................................................................13 Safety information.......................................................................................................................................15 2.1 The 5 safety rules...................................................................................................................15 2.2 Qualified personnel ................................................................................................................15 2.3 Safe handling .........................................................................................................................16 2.4 For use in hazardous Zone 2 or Zone 22...............................................................................17 2.5 Electrostatic sensitive devices ...............................................................................................18 2.6 Processes that generate high levels of electrostatic charge ..................................................19 2.7 Interference immunity.............................................................................................................20 2.8 Influence on the line power supply through a strongly irregular torque..................................20 2.9 Interference voltages when operating the converter ..............................................................20 2.10 Electromagnetic fields when operating electrical power engineering installations.................21 3 Description..................................................................................................................................................23 4 Preparations for use ...................................................................................................................................33 4.1 Safety-related aspects to consider when configuring the plant..............................................33 4.2 Observing the operating mode...............................................................................................33 4.3 Ensuring cooling.....................................................................................................................33 4.4 4.4.1 4.4.2 4.4.3 4.4.4 4.4.5 Configuration of the cooling circuit and coolant supply ..........................................................33 Material selection for the cooling circuit .................................................................................33 Pressures and differential pressures in the cooling circuit .....................................................34 Components and materials of the cooling circuit ...................................................................35 Potential equalization on the cooling circuit components.......................................................35 Power loss..............................................................................................................................36 4.5 4.5.1 4.5.2 4.5.3 4.5.4 Coolant specification ..............................................................................................................36 General coolant requirements................................................................................................36 Coolant specification (M85 "stainless steel version" option) ..................................................38 Inhibitors, anti-freeze, biocides ..............................................................................................39 Cooling capacity derating.......................................................................................................40 4.6 Thermal motor protection .......................................................................................................41 4.7 Thermal motor protection using PTC thermistors (option) .....................................................41 4.8 Interlock circuit for the automatic regreasing system (option)................................................41 4.9 Interlock circuit for anti-condensation heating........................................................................41 SIMOTICS FD 1MH1 Operating Instructions 02/2019 5 Table of contents 5 6 4.10 IM B5 type of construction with support foot ..........................................................................42 4.11 Noise emissions .....................................................................................................................42 4.12 Rotational speed limit values .................................................................................................42 4.13 Complying with speed-torque curve.......................................................................................43 4.14 Voltage and frequency fluctuations during line operation ......................................................43 4.15 Phase synchronization during supply system switching ........................................................43 4.16 System-inherent frequencies .................................................................................................43 4.17 Torsional load of the drive train..............................................................................................44 4.18 4.18.1 4.18.2 4.18.3 4.18.4 Transport................................................................................................................................44 Safety instructions for transport .............................................................................................44 Checking the delivery.............................................................................................................46 Securing the rotor...................................................................................................................47 Lifting and transporting the machine ......................................................................................49 4.19 4.19.1 4.19.2 4.19.3 Storage...................................................................................................................................49 Storing the machine ...............................................................................................................49 Protecting the cooling water circuit during storage ................................................................52 Protection against corrosion...................................................................................................53 4.20 4.20.1 4.20.2 4.20.3 4.20.4 4.20.5 4.20.6 Converter operation ...............................................................................................................53 Converter operation of explosion-proof machines .................................................................53 Supply line configuration ........................................................................................................54 Converter input voltage ..........................................................................................................54 Reducing bearing currents .....................................................................................................55 Insulated bearings when operating the converter ..................................................................56 Converter operation on a grounded network..........................................................................57 Assembly ....................................................................................................................................................59 5.1 Safety instructions for mounting.............................................................................................59 5.2 5.2.1 5.2.2 5.2.3 5.2.4 5.2.5 5.2.6 Preparations for installation....................................................................................................60 Requirements for installation..................................................................................................60 Insulation resistance and polarization index ..........................................................................61 Testing the insulation resistance and polarization index........................................................61 Prepare the mating faces (IM B3) ..........................................................................................64 Prepare the mating face for a flange connection ...................................................................64 Prepare the mating face for wall mounting ............................................................................64 5.3 5.3.1 5.3.2 5.3.3 5.3.4 5.3.5 5.3.6 5.3.7 5.3.8 5.3.9 5.3.10 Lift the machine to where it will be installed, and position it...................................................64 Preconditions for correct alignment and secure attachment .................................................64 Checking the load handling attachments ...............................................................................65 Removing the rotor shipping brace ........................................................................................65 Removing the rotor shipping brace from machines in vertical type........................................65 Removing anti-corrosion protection .......................................................................................66 Mounting the output elements................................................................................................66 Lifting and transportation........................................................................................................68 Putting the machine down......................................................................................................69 Draining condensation ...........................................................................................................70 Roughly aligning the machine ................................................................................................71 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Table of contents 6 5.4 5.4.1 5.4.2 5.4.3 5.4.4 5.4.5 Installing the machine ............................................................................................................72 Preconditions for smooth, vibration-free operation ................................................................72 Aligning the machine to the driven machine and mounting (IM B3 / IM B35) ........................72 Aligning the machine to the driven machine and attaching it to it (IM B5) .............................74 Aligning the machine to the driven machine and attaching it to it (IM V1, IM V10) ................75 Axial and radial forces............................................................................................................75 5.5 Connecting the cooling water supply .....................................................................................76 Electrical connection...................................................................................................................................79 6.1 Safety instructions for the electrical connection .....................................................................79 6.2 Basic rules..............................................................................................................................79 6.3 6.3.1 6.3.2 6.3.3 6.3.4 6.3.5 6.3.6 6.3.7 6.3.8 Terminal box ..........................................................................................................................80 Terminal box 1XB1621...........................................................................................................81 Terminal box 1XB1631...........................................................................................................81 Terminal box 1XB7730...........................................................................................................82 Terminal box 1XB7731...........................................................................................................83 Terminal box 1XB7740...........................................................................................................83 Terminal box 1XB7750...........................................................................................................84 Rotating the terminal box .......................................................................................................84 Mounting/removing the terminal box ......................................................................................87 6.4 6.4.1 6.4.2 6.4.3 6.4.4 6.4.5 6.4.6 6.4.7 Preparation.............................................................................................................................88 Terminal designation..............................................................................................................88 Selecting cables .....................................................................................................................88 Connecting the grounding conductor .....................................................................................89 Connect metal shield in the terminal box ..............................................................................90 Connection without terminal box ............................................................................................90 Connecting the machine for a specific direction of rotation....................................................91 Undrilled entry plate ...............................................................................................................91 6.5 6.5.1 6.5.2 6.5.3 6.5.4 6.5.5 6.5.6 6.5.7 6.5.8 6.5.9 6.5.10 6.5.11 6.5.12 Inserting and routing the cables .............................................................................................92 Bringing cables into the terminal box 1XB... with sealing insert with break-off ring ...............92 Bringing cables into the terminal box 1XB... with cable gland................................................94 Certified cable entries, thread adapters and sealing plugs ....................................................94 Laying cables .........................................................................................................................95 Connecting cables with cable lugs .........................................................................................95 Connecting cables without cable lugs ....................................................................................96 Use of aluminum conductors..................................................................................................98 Using single-stranded cables .................................................................................................99 Internal equipotential bonding ................................................................................................99 Stepless mating face for the seal in the terminal box cover ..................................................99 Minimum air clearances .......................................................................................................100 Finishing connection work....................................................................................................100 6.6 6.6.1 6.6.2 6.6.3 6.6.4 6.6.5 6.6.6 Connecting the auxiliary circuits...........................................................................................101 Selecting cables ...................................................................................................................101 Bringing cables into the auxiliary terminal box and routing them .........................................101 Intrinsically safe circuits for sensors or probes ....................................................................102 Connect metal shield in the terminal box ............................................................................102 Connecting temperature monitoring for the stator winding ..................................................102 Terminating the connection work (auxiliary circuit) ..............................................................103 SIMOTICS FD 1MH1 Operating Instructions 02/2019 7 Table of contents 7 8 9 Start-up.....................................................................................................................................................105 7.1 Checks to be carried out prior to commissioning ................................................................105 7.2 Converter operation .............................................................................................................107 7.3 Measuring the insulation resistance before commissioning.................................................107 7.4 Greasing the roller bearings prior to commissioning............................................................108 7.5 Setting the automatic regreasing system .............................................................................109 7.6 Setpoint values for monitoring the bearing temperature ......................................................109 7.7 Set values for monitoring the winding temperature..............................................................110 7.8 Test run ................................................................................................................................110 7.9 Switching off.........................................................................................................................112 7.10 7.10.1 7.10.2 7.10.3 Setting the motor parameters at the converter.....................................................................112 Selecting the motor type and motor data in the STARTER program ...................................113 Commissioning at the SINAMICS S/G converter using the AOP30.....................................115 Commissioning at the SINAMICS G120P inverter using the IOP ........................................118 Operation..................................................................................................................................................119 8.1 Safety instructions for operation...........................................................................................119 8.2 Operation in hazardous areas of Zone 2..............................................................................121 8.3 Switching on the machine ....................................................................................................122 8.4 Regreasing roller bearings ...................................................................................................122 8.5 8.5.1 8.5.2 8.5.3 8.5.4 Stoppages ............................................................................................................................122 Avoidance of frost and corrosion damage in the cooling system .........................................123 Avoidance of condensation or formation of condensation within the machine.....................123 Avoidance of damage to roller bearings during stoppages ..................................................124 Measurement of the insulation resistance after an extended stoppage...............................124 8.6 Decommissioning the machine ............................................................................................125 8.7 Switching off the water-cooling system ................................................................................125 8.8 Draining the coolant .............................................................................................................125 8.9 Re-commissioning the machine ...........................................................................................126 8.10 Switching on again after an emergency switching-off ..........................................................126 8.11 8.11.1 8.11.2 8.11.3 8.11.4 8.11.5 faults.....................................................................................................................................127 Inspections in the event of faults..........................................................................................127 Electrical faults .....................................................................................................................128 Mechanical faults .................................................................................................................128 Water cooling faults..............................................................................................................130 Roller bearing faults .............................................................................................................131 Maintenance .............................................................................................................................................133 9.1 9.1.1 9.1.2 9.1.3 8 Inspection and maintenance ................................................................................................133 Safety instructions for inspection and maintenance.............................................................133 Measuring the insulation resistance during the course of maintenance work......................135 Inspections in the event of faults..........................................................................................135 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Table of contents 10 11 9.1.4 9.1.5 9.1.6 9.1.7 9.1.8 9.1.9 9.1.10 9.1.11 9.1.12 9.1.13 9.1.14 First service after installation or repair .................................................................................136 General inspection ...............................................................................................................136 Servicing and maintaining the anti-condensation heating....................................................137 Assessing the roller bearings ...............................................................................................137 Roller bearings with automatic regreasing system...............................................................138 Regreasing intervals and types of grease for operating roller bearings...............................138 Sealing the rolling-contact bearings ("Increased degree of protection" option) ...................142 Cleaning the cooling water ducts .........................................................................................142 Touch up any damaged paintwork .......................................................................................142 Repainting ............................................................................................................................143 Maintaining terminal boxes ..................................................................................................143 9.2 9.2.1 9.2.2 9.2.3 9.2.3.1 9.2.3.2 9.2.3.3 9.2.3.4 9.2.3.5 9.2.3.6 9.2.3.7 9.2.4 Corrective Maintenance .......................................................................................................144 Prepare servicing work.........................................................................................................145 Screws with preCOTE coating .............................................................................................146 Roller-contact bearings ........................................................................................................146 Removing roller bearing .......................................................................................................146 Remove V ring .....................................................................................................................147 Removing the labyrinth sealing ring .....................................................................................148 Installing roller bearings .......................................................................................................149 Install the V ring ...................................................................................................................149 Installing the V ring ("Increased degree of protection" option) .............................................150 Installing the labyrinth sealing ring .......................................................................................151 Seal the motor......................................................................................................................152 Spare parts ...............................................................................................................................................155 10.1 Ordering data .......................................................................................................................155 10.2 Ordering spare parts via the Internet ...................................................................................156 10.3 Anti-condensation heating....................................................................................................157 10.4 Housing, stators and rotors ..................................................................................................158 10.5 Roller bearing cartridge at the drive and non-drive end .......................................................160 10.6 Roller bearing cartridge at the drive and non-drive end .......................................................161 10.7 Terminal box 1XB1621.........................................................................................................162 10.8 Terminal box 1XB1631.........................................................................................................164 10.9 Terminal box 1XB7730.........................................................................................................165 10.10 Terminal box 1XB7731.........................................................................................................166 10.11 Terminal box 1XB7740.........................................................................................................167 10.12 Terminal box 1XB7750.........................................................................................................168 10.13 Auxiliary terminal box 1XB9014 ...........................................................................................169 10.14 Auxiliary terminal box 1XB9015 ...........................................................................................170 10.15 1XB9016 auxiliary terminal box............................................................................................171 10.16 Auxiliary terminal box 1XB302. ............................................................................................172 Disposal....................................................................................................................................................173 11.1 RoHS - restricting the use of certain hazardous substances ...............................................173 SIMOTICS FD 1MH1 Operating Instructions 02/2019 9 Table of contents 11.2 Information according to Article 33 of the REACH regulation ..............................................173 11.3 Preparing for disassembly....................................................................................................174 11.4 Dismantling the machine......................................................................................................174 11.5 Disposal of components.......................................................................................................174 A Service and Support .................................................................................................................................177 B Technical data and drawings....................................................................................................................179 B.1 C Tightening torques for screw and bolt connections..............................................................179 Quality documents....................................................................................................................................181 Index.........................................................................................................................................................183 Tables Table 3-1 Machine design ..........................................................................................................................23 Table 3-2 Machine design with type of protection Ex ec .............................................................................24 Table 3-3 Data on the rating plate ...............................................................................................................27 Table 3-4 Rolling-contact bearing variants ..................................................................................................29 Table 4-1 Materials and components of a cooling circuit ............................................................................35 Table 4-2 Substances that can destroy the cooling system ........................................................................37 Table 4-3 Overview and application of coolant additives ............................................................................39 Table 5-1 Stator winding insulation resistance at 40 C ..............................................................................62 Table 5-2 Permissible deviations for aligning the machine with flexible coupling .......................................73 Table 6-1 Terminal designations using the 1U1-1 as an example ..............................................................88 Table 6-2 Connection technology (with cable lug / connection without cable lug) ......................................92 Table 6-3 Cable entry plate versions...........................................................................................................94 Table 6-4 Minimum air clearance dependent on rms value of the alternating voltage Urms .......................100 Table 7-1 Set values for monitoring the bearing temperatures before commissioning .............................109 Table 7-2 Set values for monitoring the bearing temperatures .................................................................109 Table 7-3 Set value for commissioning .....................................................................................................110 Table 7-4 Set values during normal operation...........................................................................................110 Table 8-1 Electrical faults Table 8-2 Mechanical faults.......................................................................................................................128 Table 8-3 Cooling system faults Table 8-4 Roller bearing faults Table 9-1 Checks after assembly or repair ...............................................................................................136 Table 9-2 Checks that have to be performed during the general inspection .............................................136 Table 9-3 Criteria for selecting rolling bearing greases .............................................................................139 Table 9-4 Rolling bearing greases for vertical and horizontal types of construction ................................140 Table 9-5 Alternative greases with NLGI class 2 for motors of horizontal construction ............................140 10 .....................................................................................................................128 ...........................................................................................................130 .............................................................................................................131 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Table of contents Table 10-1 Spare parts for housing, stators and rotors ...............................................................................158 Table 10-2 Spare parts for the bearing cartridge at the drive end and non-drive end.................................160 Table 10-3 Spare parts for the bearing cartridge at the drive end and non-drive end.................................161 Table 10-4 Terminal box 1XB1621 spare parts...........................................................................................162 Table 10-5 Additional spare parts................................................................................................................163 Table 10-6 Additional spare parts for terminal box 1XB1631 with split cable entry.....................................164 Table 10-7 Main terminal box 1XB7730 spare parts ...................................................................................165 Table 10-8 Additional spare parts................................................................................................................165 Table 10-9 Main terminal box 1XB7731 spare parts ...................................................................................166 Table 10-10 Additional spare parts................................................................................................................166 Table 10-11 Main terminal box 1XB7740 spare parts ...................................................................................167 Table 10-12 Additional spare parts................................................................................................................167 Table 10-13 Terminal box 1XB7750..............................................................................................................168 Table B-1 Tightening torques for bolted connections with a tolerance of 10%........................................179 Figures Figure 3-1 Schematic of the rating plate.......................................................................................................26 Figure 4-1 Axial fastening of the rotor...........................................................................................................48 Figure 4-2 Schematic representation of a single drive .................................................................................56 Figure 4-3 Schematic representation of a tandem drive...............................................................................57 Figure 5-1 Balancing type on the drive-end side ..........................................................................................66 Figure 5-2 Condensation water drain for vertical mounting ..........................................................................70 Figure 5-3 Condensation water drain for horizontal mounting......................................................................71 Figure 5-4 Schematic diagram: Aligning the machine to the driven machine...............................................73 Figure 5-5 Standard coolant connections and coolant drain hole ................................................................76 Figure 6-1 Water drip loop ............................................................................................................................80 Figure 6-2 Terminal box 1XB1621................................................................................................................81 Figure 6-3 Terminal box 1XB1631................................................................................................................81 Figure 6-4 Terminal box 1XB7730................................................................................................................82 Figure 6-5 Terminal box 1XB7731................................................................................................................83 Figure 6-6 Terminal box 1XB7740................................................................................................................83 Figure 6-7 Terminal box 1XB7750................................................................................................................84 Figure 6-8 Strain relief device and sealing insert..........................................................................................93 Figure 6-9 Connection with cable lug and fixing screw (schematic diagram) ...............................................95 Figure 6-10 Connection using terminal clamps (schematic diagram).............................................................97 Figure 7-1 Selecting a motor type...............................................................................................................113 Figure 7-2 Entering the motor data.............................................................................................................114 Figure 9-1 Remove the V ring.....................................................................................................................147 SIMOTICS FD 1MH1 Operating Instructions 02/2019 11 Table of contents Figure 9-2 Disassembling the labyrinth sealing ring (schematic diagram) .................................................148 Figure 9-3 Install the V ring.........................................................................................................................150 Figure 9-4 Roller-contact bearing with grease chamber (schematic diagram) ...........................................151 Figure 9-5 Position the set screws for the labyrinth sealing ring on the outer bearing cover .....................152 Figure 10-1 Housing, stators and rotors .......................................................................................................158 Figure 10-2 Bearing cartridge at the drive end and non-drive end ...............................................................160 Figure 10-3 Bearing cartridge at the drive end and non-drive end ...............................................................161 Figure 10-4 Terminal box 1XB1621 with standard cable entry.....................................................................162 Figure 10-5 Two-part cable entry..................................................................................................................162 Figure 10-6 Terminal box 1XB1631..............................................................................................................164 Figure 10-7 Main terminal box 1XB7730 ......................................................................................................165 Figure 10-8 Main terminal box 1XB7731 ......................................................................................................166 Figure 10-9 Main terminal box 1XB7740 ......................................................................................................167 Figure 10-10 Terminal box 1XB7750 with standard cable entry.....................................................................168 Figure 10-11 Auxiliary terminal box 1XB9014 .............................................................................................169 Figure 10-12 Auxiliary terminal box 1XB9015 .............................................................................................170 Figure 10-13 1XB9016 auxiliary terminal box ...............................................................................................171 Figure 10-14 Auxiliary terminal box 1XB302. .................................................................................................172 12 SIMOTICS FD 1MH1 Operating Instructions 02/2019 1 Introduction In the following text, the motor is referred to as "electrical machine" - or abbreviated, just "machine". 1.1 About these instructions These instructions describe the machine and explain how to handle it, from initial delivery to final disposal of the equipment. Keep these instructions for later use. Read these operating instructions before you handle the machine and follow the instructions to become familiar with its design and operating principles and thus ensure safe, problem-free machine operation and long service life. Safety instructions and handling-related warning notes are provided in these instructions. When carrying out any activity at or with the machine, carefully comply with all of these notes for your own safety, to protect other people and to avoid material damage. Please contact the Service Center (Page 177) if you have any suggestions on how to improve this document. Text format features You can find the following text format features in these instructions: 1. Handling instructions are always formatted as a numbered list. Always perform the steps in the order given. Lists are formatted as bulleted lists. - Lists on the second level are hyphenated. Note The note provides you with additional information about the product itself, handling the product - and the relevant documentation. 1.2 Compiling personal documents On the Internet pages in Industry Online Support you have the possibility of compiling personal documents using the function Documentation (https:// support.industry.siemens.com/My/ww/en/documentation) Using the "Documentation" function, from Product Support manuals, you can compile your own "Documentation". However, you can also include other Product Support content such as FAQs or characteristics in the documentation that you compile. SIMOTICS FD 1MH1 Operating Instructions 02/2019 13 Introduction 1.2 Compiling personal documents In the "Documentation" function, you have the option of creating your own compiled documents in your own structure and managing them. You can delete or shift individual chapters or topics. Further, using the note function you can import your own content. The compiled "documentation" can be exported as PDF, for example. Using the "Documentation" function, you can efficiently compile your own plant or system documentation. The "Documentation" compiled in a specific language can also be automatically exported in one of the other available languages. The full functionality is only available for registered users. 14 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Safety information 2 This machine has been designed, built and tested in accordance with Directive 2014/34/EU ("Explosion Protection Directive") and is intended for use in industrial plants with a potentially explosive atmosphere. Commissioning the machine in hazardous zones is absolutely prohibited until conformance with these guidelines has been proven based on the appropriate certificate. Only commission the machine if it has been absolutely confirmed that the plant or system is in full conformance with the valid directive. Please observe the country-specific regulations when using the machine outside the European Community. 2.1 The 5 safety rules For your own personal safety and to prevent material damage when carrying out any work, always observe the safety-relevant instructions and the following five safety rules according to EN 501101 "Working in a voltage-free state". Apply the five safety rules in the sequence stated before starting work. 5 safety rules 1. Disconnect the system. Also disconnect the auxiliary circuits, for example, anti-condensation heating. 2. Secure against reconnection. 3. Verify absence of operating voltage. 4. Ground and short-circuit. 5. Provide protection against adjacent live parts. To energize the system, apply the measures in reverse order. 2.2 Qualified personnel All work at the machine must be carried out by qualified personnel only. For the purpose of this documentation, qualified personnel is taken to mean people who fulfill the following requirements: Through appropriate training and experience, they are able to recognize and avoid risks and potential dangers in their particular field of activity. They have been instructed to carry out work on the machine by the appropriate person responsible. SIMOTICS FD 1MH1 Operating Instructions 02/2019 15 Safety information 2.3 Safe handling 2.3 Safe handling Workplace safety depends on the attentiveness, care, and common sense of the personnel who install, operate, and maintain the machine. In addition to the safety measures cited, as a matter of principle, the use of caution is necessary when you are near the machine. Always pay attention to your safety. Also observe the following to prevent accidents: General safety regulations applicable in the country where the machine is deployed. Manufacturer-specific and application-specific regulations Special agreements made with the operator Separate safety instructions supplied with the machine Safety symbols and instructions on the machine and its packaging Danger as a result of stationary parts under voltage (live parts) Live parts represent a hazard. Touch protection against active (live) parts is no longer guaranteed if covers are removed. The minimum clearance and creepage distances may be violated when coming close to live parts. Touching or coming close to them can result in death, serious injury or material damage. Ensure that all live parts are suitably covered. Switch off and disconnect the machine first if you want to remove covers. Observe the "5 safety rules". Risk of injury due to rotating parts Rotating parts are dangerous. Touch protection against rotating parts is no longer guaranteed if covers are removed. Touching rotating parts can result in death, serious injury or material damage. Ensure that all rotating parts are reliably covered. Switch off and disconnect the machine first if you want to remove covers. Observe the "5 safety rules". Only remove covers when the rotating parts have come to a complete standstill. Risk of burns due to hot surfaces Individual machine parts can become hot in operation. Burns can result when coming into contact with these parts. Never touch machine parts during operation. Allow the machine to cool before starting work on the machine. Check the temperature of parts before touching them. If required, wear suitable protective equipment. 16 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Safety information 2.4 For use in hazardous Zone 2 or Zone 22 Health hazard due to chemical substances Chemical substances required for the setup, operation and maintenance of machines can present a health risk. Observe the product information provided by the manufacturer. Flammable substances hazard Chemical substances required for the setup, operation and maintenance of machines may be flammable. These substances can ignite if handled incorrectly. They can cause burns and property damage. Observe the product information provided by the manufacturer. See also The 5 safety rules (Page 15) Noise emissions During operation, the machine's noise emission levels can exceed those permitted at the workplace, which can cause hearing damage. Ensure that nobody is in the area of increased noise emissions during machine operation. Take steps to reduce noise so that the machine can be operated safely within your system. The following measures may help to reduce noise. - Covers - Noise insulation - Hearing protection measures 2.4 For use in hazardous Zone 2 or Zone 22 Electrical systems in hazardous areas must be assembled, installed, and operated by the applicable responsible persons in accordance with the applicable rules and regulations. Note The basic requirements relating to electrical systems and their operation in hazardous areas are described, for instance, in EU Directive 1999/92/EC as well as in IEC / EN 60079-14. SIMOTICS FD 1MH1 Operating Instructions 02/2019 17 Safety information 2.5 Electrostatic sensitive devices Ignition hazards The operating company - together with the responsible authorities - must fully evaluate the operational risks, the local operating conditions and the monitoring methods that are required. It is essential that the operating company complies with the necessary measures. Regarding this topic, the machine manufacturer cannot provide any generally applicable recommendations. Please observe the information in these operating instructions. Note You can find basic information on assessing ignition hazards caused by electrical equipment and their operation in hazardous zones in the 2014/34/EU and 1999/92/EC directives - as well as in the series of IEC / EN 60079 standards, for example. If a third-party certification is available for the machine, then carefully comply with the technical data defined in it and any special conditions. The certificate must be available before commissioning. 2.5 Electrostatic sensitive devices Material damage due to electrostatic discharge Electronic modules contain components that can be destroyed by electrostatic discharge. These components can be damaged or destroyed if they are not handled correctly. To protect equipment against damage, follow the instructions given below. Only touch electronic modules if you absolutely have to work on them. The body of the person concerned must have been electrostatically discharged and grounded immediately before any electronic modules are touched. Electronic modules should not be brought into contact with electrically insulating materials, such as: - Plastic film - Plastic parts - Insulating table supports - Clothing made of synthetic fibers Always place electrostatic sensitive devices on conductive bases. Always pack, store and transport electronic modules or components in conductive packaging, such as: - Metallized plastic or metal containers - Conductive foam material - Domestic aluminum foil 18 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Safety information 2.6 Processes that generate high levels of electrostatic charge The necessary ESD protective measures for electrostatic sensitive devices are illustrated once again in the following drawings: 6WDQGLQJSRVLWLRQ 6HDWLQJSRVLWLRQ G E 6WDQGLQJVHDWLQJSRVLWLRQ G I F I D I F G E H I I F D a = conductive floor surfaceb = ESD table d = ESD overall e = ESD wristband H D c = ESD shoes f = cabinet ground connection Risk of explosion due to electrostatic discharge Electrostatic discharge poses a potential ignition source. Dangerous electrostatic charges can occur, for example as a result of mechanical friction, flowing air that contains particles - or persons that are not appropriately grounded, e.g. when carrying out maintenance or cleaning work. In an explosive atmosphere, there is a risk of an explosion. This can result in death, serious injury or material damage. Avoid carrying out work specified above on non-metallic parts, e.g. foam rubber for noise dampeners/attenuators. Please comply with ESD protective measures. 2.6 Processes that generate high levels of electrostatic charge Processes that generate high levels of electrostatic charge Processes that generate high levels of electrostatic charge, which are far higher than those generated through manual rubbing, include the following: Operation of high-voltage electrodes and ionizers Presence of high-speed particles on surfaces, e.g. sprayed charges (electron and ion flows) in electrostatic coating processes Pneumatically conveyed dusts and bulk goods Flowing or hydraulically conveyed liquids and drops Belts, brushes and foils etc. moved by machines Risk of explosion as a result of processes with high levels of electrostatic charging Processes with high levels of electrostatic charging can result in propagating brush discharge/ brushing discharge and explosion SIMOTICS FD 1MH1 Operating Instructions 02/2019 19 Safety information 2.7 Interference immunity This can result in death, serious injury or material damage. Avoid all of these processes in areas where there is risk of gas and dust explosions at nonmetallic exposed components, e.g. paint finishes. These discharge types are not addressed in current standards. The non-metallic exposed components, e.g. paint finishes are subject to an electrostatic suitability test in the factory. When supplied, the motor has its original paint finish. Use the tested, original paint when repainting or touching up. It is possible to use a paint that has not been tested by Siemens, which is however suitable from an electrostatic perspective. The operating company is responsible for carrying out an electrostatic test of the complete system. 2.7 Interference immunity By selecting suitable signal cables and evaluation units, ensure that the interference immunity of the machine is not diminished. 2.8 Influence on the line power supply through a strongly irregular torque A strongly irregular torque, for example with the drive of a reciprocating motor, forces a nonsinusoidal motor current. The emerging harmonics can have an impermissible influence on the line power supply via the connection lines. 2.9 Interference voltages when operating the converter Interference voltages when operating the converter When a converter is in operation, the emitted interference varies in strength depending on the converter (manufacturer, type, interference suppression measures undertaken). On machines with integrated sensors (e.g. PTC thermistors), interference voltages caused by the converter may occur on the sensor lead. This can cause faults which can result in eventual or immediate death, serious injury or material damage. Comply with the EMC information provided by the manufacturer of the converter. This is how you prevent the limit values stipulated by IEC/EN 61000-6-3 for the drive system (consisting of the machine and converter) from being exceeded. You must put appropriate EMC measures in place. 20 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Safety information 2.10 Electromagnetic fields when operating electrical power engineering installations 2.10 Electromagnetic fields when operating electrical power engineering installations Electrical power equipment generate electromagnetic fields during operation. Potentially lethal malfunctions can occur in medical implants, e.g. pacemakers, in the vicinity of electrical power equipment. Data may be lost on magnetic or electronic data carriers. Protect the personnel working in the plant by taking appropriate measures, such as erecting identifying markings, safety barriers and warning signs and giving safety talks. Observe the nationally applicable health and safety regulations. It is forbidden for people with pacemakers to be close to the machine. Do not carry any magnetic or electronic data media. SIMOTICS FD 1MH1 Operating Instructions 02/2019 21 Safety information 2.10 Electromagnetic fields when operating electrical power engineering installations 22 SIMOTICS FD 1MH1 Operating Instructions 02/2019 3 Description Applications This electrical machine has been designed for a wide range of drive and energy conversion applications. The machines are characterized by extreme ruggedness, long service life, and overall reliability. They are also highly versatile, allowing them to be tailored to specific functions. Details of the supplied machine and permissible operating conditions can be found in this documentation. The machine was designed in accordance with the ordering party's specification and may only be used for the contractually agreed purpose. The permissible operating conditions are specified on the rating plate. The technical data are described in the catalog. Type of protection Ex ec This machine has type of protection Ex ec according to IEC / EN 60079-7. It can therefore be operated in hazardous areas of Zone 2 according to IEC / EN 6007910-1. WARNING Explosion hazard This machine is not designed for use in areas at risk of dust explosion or in areas where an explosion hazard exists due to hybrid mixtures. An explosion can occur if the machine is operated in these areas. This can result in death, serious injury or material damage. Never operate this machine in the presence of explosive dust or in areas where an explosion hazard exists due to hybrid mixtures. Machine design The regulations and standards used as the basis to design and test this machine are stamped on the rating plate. The machine design basically complies with the subsequent standards. Please refer to the EU Declaration of Conformity for the versions of the harmonized standards referenced. Table 3-1 Machine design Feature Standard Rating and performance IEC/EN 600341 Degree of protection IEC/EN 600345 Cooling IEC/EN 600346 Type of construction IEC/EN 600347 SIMOTICS FD 1MH1 Operating Instructions 02/2019 23 Description Feature Standard Terminal markings and direction of rotation IEC/EN 600348 Noise emission IEC/EN 600349 Starting characteristics of rotating electrical machines * IEC/EN 6003412 Vibration severity grades IEC/EN 6003414 Efficiency classification of three-phase squirrel-cage induction motors ** IEC/EN 60034-30-1 Vibration limits DIN ISO 10816-3 * For machines in line operation only ** Exception: Pole-changing motors See also Quality documents (Page 181) The following standards additionally apply for explosion-proof machines: Table 3-2 Machine design with type of protection Ex ec Feature Standard Type of protection Ex ec IEC/EN 600790 IEC / EN 60079-7 Optional (depending on order) Comparison of IEC and GOST standards The IEC/EN standards correspond to the following GOST standards. IEC/EN GOST IEC/EN 60034-1 GOST R IEC 60034-1 IEC/EN 60034-5 GOST R IEC 60034-5 IEC/EN 60034-6 GOST R IEC 60034-6 IEC/EN 60034-7 GOST R IEC 60034-7 IEC/EN 60034-8 GOST R IEC 60034-8 IEC/EN 60034-9 GOST R IEC 60034-9 IEC/EN 60034-12 GOST R IEC 60034-12 IEC/EN 60034-14 GOST R IEC 60034-14 This machine has been designed and built in accordance with Directive 2014/34/EU and Customs Union Technical Regulation "On safety of equipment intended for use in explosive atmospheres" (TR CU 012/2011) and is intended for use in industrial plants with potentially explosive atmospheres. The IEC/EN standards correspond to the following GOST standards. 24 IEC/EN GOST IEC/EN 60079-0 GOST R IEC 60079-0 IEC/EN 60079-2 GOST IEC 60079-2 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Description IEC/EN 60079-7 GOST R IEC 60079-7 IEC/EN 60079-10 GOST IEC 60079-10 IEC/EN 60079-14 GOST IEC 60079-14 Ex marking for type of protection Ex ec IIC T3 Gc II 3 G Ex ec IIC T3 Gc 2 Ex nA IIC T3 Gc X AA87 CE- or EAC marking Code for prevention of explosions Equipment group: II not for mining, but other hazardous zones Device category: 3 for infrequent, short-term danger Atmosphere: G for gas Explosion protection: International Type of protection: "ec" Explosion group: IIC for acetylene Temperature Class: T3 for maximum surface temperature 200 C Device protection level: Gc for an extended level of protection in hazardous zones with explosive gas mixtures Identification number or name of nominated testing agency Zone 2 "X" special conditions Ex marking for type of protection Ex ec IIB T3 Gc II 3 G Ex ec IIB T3 Gc 2 Ex nA IIB T3 Gc X AA87 SIMOTICS FD 1MH1 Operating Instructions 02/2019 25 Description CE- or EAC marking Code for prevention of explosions Equipment group: II not for mining, but other hazardous zones Device category: 3 for infrequent, short-term danger Atmosphere: G for gas Explosion protection: International Type of protection: "ec" Explosion group: IIB for ethylene Temperature Class: T3 for maximum surface temperature 200 C Device protection level: Gc for an extended level of protection in hazardous zones with explosive gas mixtures Identification number or name of nominated testing agency Zone 2 "X" special conditions Rating plate The rating plate shows the identification data and the most important technical data. The data on the rating plate and the contractual agreements define the limits of proper usage. SIEMENS R R R Figure 3-1 26 R '(: Schematic of the rating plate SIMOTICS FD 1MH1 Operating Instructions 02/2019 Description Table 3-3 Data on the rating plate Item Description Item Description (1) Type of motor (15) Rated power [kW or HP] (2) Order number (16) Rated efficiency factor (3) Identifier of the motor series (17) Rated speed [rpm] (4) Serial number (18) Rated frequency [Hz] (5) Weight (19) Efficiency class (IE code) or efficiency ac cording to IEEE112B or empty (6) Degree of protection (20) Efficiency according to IEC/EN 60034-2-1 or current at service factor power (7) Type of construction (21) Motor design (converter or mains motor) (8) Permissible ambient temperature range (22) Line voltage/frequency (9) Thermal class of the insulation system (23) Optional additional data (e.g. service fac tor, design and code letter, amount of cool ing water and intake temperature, etc.) (10) Thermal class of the utilization (24) Country of manufacture and location (11) Maximum speed [rpm] (25) Certification mark for UL/CSA + file number (optional) (12) Standards (26) Certificate number(s) for Ex motors for Zone 2 (optional) (13) Rated voltage [V] and connections (27) Direction of rotation (14) Rated current [A] (28) Data matrix code (order number and serial number) Relevant directives The following directives are relevant for the SIMOTICS motor series. European low-voltage directive The SIMOTICS motor series complies with the requirements of the low-voltage directive 2014/35/EU. Eurasian Conformity The SIMOTICS motor series complies with the requirements of the Russia/Belarus/ Kazakhstan customs union (EAC). Underwriters Laboratories The SIMOTICS motor series generally complies with UL and cUL requirements as component of motor applications - and is correspondingly listed. Specifically developed motors and functions are the exceptions in this case. Carefully observe the content of the quotation, and that there is a cUL-marking on the rating plate. Quality management system Siemens AG employs a quality management system that meets the requirements of ISO 9001 and ISO 14001. SIMOTICS FD 1MH1 Operating Instructions 02/2019 27 Description Certificates that can be downloaded You can download certificates for the SIMOTICS motor series at the following link: Certificates (https://support.industry.siemens.com/cs/ww/en/ps/13358/cert) The following directives are not relevant European EMC directive: The products are not considered as devices in the sense of the directive. European Machinery Directive: However, the use of the products in a typical machine application has been fully assessed for compliance with the main regulations in this directive concerning health and safety. China Compulsory Certification (CCC): The SIMOTICS motor series does not fall under the area of application. Rotors The rotor assembly is pressed onto the shaft together with the cage winding. The drive end of the shaft usually has a cylindrical shaft end. Dependent on the design, a second shaft end may be located at the non-drive end. Drive The motor speed is controlled using a converter. It has been optimized for operation with SINAMICS low-voltage converters. Other converters must comply with certain requirements: You can find more information in the catalog or in the engineering documentation. Line operation The motor is supplied from the line system. NOTICE Destruction of the machine when operated directly from the line supply The machine will be destroyed if it is directly connected to the line supply. Only operate the machine using a converter. NOTICE Machine damage for operation on the converter If you connect the machine to a converter, the machine can be damaged. Operate the machine only on the electrical supply system. 28 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Description Cooling The cooling system is designed as a closed, internal cooling circuit. The heat lost from the machine is dissipated partially via heat conduction and partially via the cooling air at the cooling water flowing through the cooling pipes. A shaft-mounted fan ensures circulation of the cooling air. Degree of protection The machine is available with degree of protection IP55. Rolling-contact bearings The machines are equipped with different types of rolling-contact bearings depending on the version and the operating conditions described in the order. The different types are listed on the lubricant plate of the machine. In converter operation an insulated bearing is usually installed on the non-drive end. The following rolling-contact bearing variants are available: Table 3-4 Rolling-contact bearing variants Version Rolling-contact bearing Horizontal type of construction, coupling output Drive end: Deep-groove ball bearing as a fixed bearing Horizontal type of construction, for increased transverse forces e.g. in the case of belt coupling Drive end: Cylindrical-roller bearing as a floating bearing Non-drive end: Deep-groove ball bearing as a floating bearing with axial compression springs Non-drive end: Deep-groove ball bearing as a fixed bearing Vertical type of construction, Drive end: Deep-groove ball bearing as a fixed bearing shaft height 315, coupling output Non-drive end: Deep-groove ball bearing as a floating bearing with axial compression springs Vertical type of construction, shaft height 355 ... 450 Drive end: Pairing of angular-contact ball bearing / deep-groove ball bearing as a fixed bearing Non-drive end: Deep-groove ball bearing as a floating bearing with axial compression springs The standard version of the machine is not suitable for belt couplings. This can result in damage to the machine. Automatic regreasing system (option) The roller bearings are optionally equipped with an automatic regreasing system. The roller bearings are supplied with new grease portions by the regreasing system in parameterized time intervals. SIMOTICS FD 1MH1 Operating Instructions 02/2019 29 Description Rolling-contact bearing design for "Increased degree of protection" (option) Improved sealing of the bearing units to prevent dust and water from getting in can be achieved by positioning a grease chamber ahead of the actual bearing unit. Although the same grease is used in both cases for reasons of convenience, a distinction is made here between "lubricating grease" and "sealing grease" because of their different functions. Layout The spent lubricating grease collects in the space between the bearing housing and the outer bearing cap. The latter also forms the sealing grease chamber with the labyrinth sealing ring (optional). The second lubricating nipple containing the grease duct for pressing in the sealing grease is also located in the outer bearing cap. The chamber is sealed off from the space where the lubricating grease collects by a V-ring or a V-ring and felt ring combination which prevents the sealing grease in the chamber from penetrating into the lubricating grease collecting space. During operation, the sealing grease in the chamber slowly runs out via the labyrinth and seals it, additionally removing dust from inside and around the outside of the labyrinth ring. Terminal box Depending on the machine design, the following terminal boxes are generally used for connecting the cables: Terminal box Comment Application GT640 Only for machines on the power supply Not for explosion-proof versions 1XB1621 1XB1631 2 x 1XB1631 1XB7730 Not for IEC explosion-proof versions 1XB7731 Not for IEC explosion-proof versions 1XB7740 2 x 1XB7740 Not for IEC explosion-proof versions 1XB7750 Depending on the terminal box and version, it is possible to rotate the terminal box through 90 in accordance with the connection direction. The implementation on the other motor side is possible only with the support of the Service Center. If you wish to retrofit using a different terminal box at a later date, please contact the Service Center (Page 177). See also Rotating the terminal box (Page 84) Terminal box (Page 80) Note You can find more information in Chapter 2 of catalog D81.8. 30 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Description Supplementary devices Depending on the order, various supplementary devices can be installed or mounted. These include sensors for bearing temperature monitoring or winding monitoring, for example. Anti-condensation heating (option) The machine is fitted with anti-condensation heating. The connection data is listed on an additional plate on the machine. SIMOTICS FD 1MH1 Operating Instructions 02/2019 31 Description 32 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4 Good planning and preparation of machine applications are essential in terms of keeping installation simple and avoiding errors, ensuring safe operation, and allowing access to the machine for servicing and corrective maintenance. This chapter outlines what you need to consider when configuring your plant in relation to this machine and the preparations you need to make before the machine is delivered. 4.1 Safety-related aspects to consider when configuring the plant A number of residual risks are associated with the machine. These are described in the chapter titled "Safety information" (Page 15) and in related sections. Take appropriate safety precautions (covers, barriers, markings, etc.) to ensure the machine is operated safely within your plant. 4.2 Observing the operating mode Observe the machine's operating mode. Use a suitable control system to prevent overspeeds, thus protecting the machine from damage. 4.3 Ensuring cooling Ensure that the machine and/or any mounted external fan unit is sufficiently cooled by the cooling air flow at the installation site: The cooling air can flow in and out freely. The full air flow provided by the fan is only achieved if air can freely enter the impeller. Ensure that the required distance in accordance with the dimensioned drawing is maintained. Hot discharged air must not be drawn in again. On the vertical design with air intake from above, the air inlets must be protected against the ingress of foreign bodies and water. 4.4 Configuration of the cooling circuit and coolant supply 4.4.1 Material selection for the cooling circuit For optimum durability of the cooling system, use a closed or half open cooling circuit in stainless steel or acrylic butadiene styrene (ABS). SIMOTICS FD 1MH1 Operating Instructions 02/2019 33 Preparations for use 4.4 Configuration of the cooling circuit and coolant supply Use either stainless steel or steel (S235JR) for the cooling circuit pipes and fittings. 4.4.2 Pressures and differential pressures in the cooling circuit The maximum permissible overpressure in the heat sink and thus in the cooling circuit must not exceed 6 bar. If you are using a pump, which reaches more than this maximum pressure, then on the plant or system side ensure that the maximum pressure is not exceeded. The lowest possible differential pressure between the coolant in the supply and return lines should be selected to allow use of pumps with a flat characteristic. The maximum differential pressure for a heat sink varies from shaft height to shaft height. Higher pressure differences significantly increase the risk of cavitation and abrasion. Machine type Flow rate 10 % Pressure drop for fresh water [l/min] [bar] 40 1.0 40 1.2 60 1.1 60 1.2 60 1.2 80 1.2 80 1.2 1LH....-3A...-.... 1MH....-3A...-.... 1LH....-3B...-.... 1MH....-3B...-.... 1LH....-4A...-.... 1MH....-4A...-.... 1LH....-4B.1.-.... 1MH....-4B.1.-.... 1LH....-4B.3.-.... 1MH....-4B.3.-.... 1LH....-4B.5.-.... 1MH....-4B.5.-.... 1LH....-4B.7.-.... 1MH....-4B.7.-.... The pressure drop is dependent on the machine type. The machine type is stamped on the rating plate. If there is a risk of frost, use cooling water with antifreeze suitable for this temperature. The pressure drop increases when antifreeze is added. See also Connecting the cooling water supply (Page 76) 34 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.4 Configuration of the cooling circuit and coolant supply 4.4.3 Components and materials of the cooling circuit The following table lists a wide variety of materials and components which can occur in a cooling circuit or which are prohibited. Table 4-1 Materials and components of a cooling circuit Material Component Remark Zinc Pipes, valves and fit tings Do not use any components manufactured out of zinc. Brass Pipes, valves and fit tings Can be used in closed cooling circuits with inhibitor. Copper Pipes, valves and fit tings Can only be used in closed cooling circuits with inhibitor. Locate an isolating element, e.g. connecting pipe of the devices, between the heat sink and copper component. Steel (e.g. S235JR) Cable Can be used in closed cooling circuits with inhibitors or anti-freeze. Check for the formation of oxide; to do this, use a sight glass, for example. Cast steel, cast iron Pipes, motors Can be used in closed cooling circuits. Use sieves and return flush filter; for stainless steel cooling systems, use a Fe separator. High-alloy steel, Group 1 (V2A) Pipes, valves and fit tings Can be used for drinking or municipal water with a chloride content < 250 ppm. High-alloy steel, Group 2 (V4A) Pipes, valves and fit tings Can be used for drinking or municipal water with a chloride content < 500 ppm. Installation employing differ Pipes, valves and fit ent materials ("mixed instal tings lation") Do not use a mixed installation. PVC Do not use any components manufactured out of PVC. Pipes, valves and fit tings, hoses Hoses Reduce the use of hoses for connecting devices to a minimum. Do not use any hoses as main connecting line for the complete system. Recommendation: EPDM hoses with an electrical resistance > 109 , e.g. "Semperflex FKD" supplied from Semperit or "DEMIT TEL" from PE/EPD, supplied from the Telle company. Gaskets Pipes, valves and fit tings Use seals manufactured from fluorinated rubber in accordance with DIN ISO 1629, AFM34, EPDM (recommended). Hose connections Transition from pipe to hose Fasten the hose connections with bracket clamps in accordance with EN 14420. 4.4.4 Potential equalization on the cooling circuit components Connect an equipotential bonding conductor to all of the components in the cooling system (motor, converter, piping system, etc.). Implement the equipotential bonding using a copper rail or finely stranded copper cable with the appropriate cable cross-sections. In this way, you suppress electrochemical processes. SIMOTICS FD 1MH1 Operating Instructions 02/2019 35 Preparations for use 4.5 Coolant specification 4.4.5 Power loss When dimensioning the cooling system, take into account the power losses as a function of the flow rate for the rated data. Machine type Flow rate 10 % Power loss [l/min] [kW] 40 28 60 42 80 56 1LH....-3A...-.... 1MH....-3A...-.... 1LH....-3B...-.... 1MH....-3B...-.... 1LH....-4A...-.... 1MH....-4A...-.... 1LH....-4B.1.-.... 1MH....-4B.1.-.... 1LH....-4B.3.-.... 1MH....-4B.3.-.... 1LH....-4B.5.-.... 1MH....-4B.5.-.... 1LH....-4B.7.-.... 1MH....-4B.7.-.... Power losses as a function of the flow rate for the rated data. 4.5 Coolant specification 4.5.1 General coolant requirements The coolant must fulfill the following requirements over the long term. The coolant is based on filtered drinking/municipal water of the quality specified below. De-ionized water Specific conductivity < 30 S/cm Evaporation residue < 20 mg/l NOTICE High percentage of chloride in drinking water According to Directive 98/83/EC, drinking water may contain up to 250 mg/l of chloride. This value is too high for the heat sinks, which may be destroyed if inhibitors are not added. Use inhibitors if the drinking water has an excessively high chloride percentage. To better explain the coolant recommendations in this document, some of the problems that can be encountered if the recommendations are ignored are listed in the table below. 36 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.5 Coolant specification Table 4-2 Substances that can destroy the cooling system Coolant property or limit value vi Countermeasure olation Seawater Do not use seawater. Water compliant with limit values Use inhibitors/antifreeze with the appropriate concentration. Locate a pressure relief valve in the cooling circuit. Entry of oxygen Use a closed cooling circuit. Locate a pressure relief valve in the cooling circuit. Use inhibitors/antifreeze with the appropriate concentration. Chloride Use inhibitors/antifreeze with the appropriate concentration. Sulfate Dilute the coolant using de-ionized water until the limit value is reached. Solids (e.g. sand) Flush the cooling circuit, without converter and motor. Use dirt fil tering equipment, e.g. sieves, fine filters. Total hardness Use inhibitors/antifreeze with the appropriate concentration. Conductivity Connect an equipotential bonding conductor to all cooling circuit components. Biological contamination Use biocides. Use dirt filtering equipment, e.g. sieves, fine filters. Oil residue Use inhibitors/antifreeze with the appropriate concentration. Flush the cooling circuit, without converter and motor. Mechanical contamination Flush the cooling circuit, without converter and motor. Use dirt fil tering equipment, e.g. sieves, fine filters. Inadequate equipotential bond ing Connect an equipotential bonding conductor to all cooling circuit components. See also Inhibitors, anti-freeze, biocides (Page 39) Cooling water intake temperature The maximum cooling water intake temperature is 25 C. NOTICE Condensation for an excessively low cooling water intake temperature If the temperature difference between cooling water and ambient temperature is greater than 5 K, this may result in condensation forming in the machine. This results in material damage. Make sure that the condensation can drain away freely. Adopt appropriate measures to achieve the required intake temperature of the cooling water. Alternatively, dry the ambient air. SIMOTICS FD 1MH1 Operating Instructions 02/2019 37 Preparations for use 4.5 Coolant specification NOTICE Corrosion due to insufficient cooling water quality The materials used in the cooler are selected to match the cooling water quality for which the air-water cooler was ordered. The cooler cannot be simply used without taking any other measures if other water conditions apply. If the cooling water quality is unsuitable, the air-towater heat exchanger may suffer corrosion and fail. The chemical composition of the cooling water must comply with the configuration specifications. If the cooling water quality fails to satisfy the quality stated on the order, please contact the Service Center. Please observe the recommended water quality in the operating instructions for the airwater cooler. NOTICE Overheating of the machine as a result of additives in the cooling water Additives for antifreeze or corrosion protection can have a negative impact on the heat transporting properties. The machine can overheat. Only operate the machine with the contractually agreed cooling water quality. See also Service and Support (Page 177) 4.5.2 Coolant specification (M85 "stainless steel version" option) Drinking or municipal water (option M85: Stainless steel version) 38 pH value 6.5 ... 9.5 Chloride ions Cl- < 200 mg/l Sulfate ions SO42- < 240 mg/l Nitrate ions NO3 < 50 mg/l + Dissolved solids < 340 mg/l Total hardness < 1.7 mmol/l Electrical conductivity < 2000 S/cm Maximum size of dissolved substances < 0.1 mm SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.5 Coolant specification 4.5.3 Inhibitors, anti-freeze, biocides You can use the following anti-freeze, inhibitors and biocides in the stainless steel cooling circuit: Table 4-3 Overview and application of coolant additives Anti-freeze used Please note the following in particular Inhibitor without antifreeze effect Not necessary Inhibitor, 0.2 ... 0.25 % by volume! Anti-freeze protection Antifrogen N: 20 % < X 45 % A 45 % concentration provides frost protection down to -15 C. With Antifrogen L, for the same antifreeze protection, a higher concentration is required then for Antifrogen N Antifrogen L: 25 % < X 48 % A 48 % concentration provides frost protection down to -15 C. Varidos FSK: 20 % < X 45 % A 45 % concentration provides frost protection down to -15 C. Biocide* Yes Cooling circuit with open pressurizer Antifrogen N, minimum quantity 20 % Antifrogen L, minimum quantity 30 % Varidos FSK, minimum quantity 30 % Antifreeze + biocide* An Antifrogen N antifreeze concentration of >20 % provides an adequate biocidal effect. With Antifrogen L and Varidos FSK, 30 % is required in order to achieve the same effect. * Effectiveness regarding the growth of microorganisms Inhibitor without anti-freeze effect If you use inhibitors without any antifreeze effect, then it is not permissible that there is any magnesium carbonate in the cooling/water used. Only use the NALCO TRAC100 inhibitor from the Nalco company in the ratio 0.2 % up to 0.25 %. Control Kits can be ordered from Nalco to check the inhibitor concentration. Anti-freeze All antifreeze agents contain corrosion protection inhibitors, which permanently protect the cooling system against corrosion. You can use the additives listed above as anti-freeze agent: NOTICE Corrosive mixture Top up with antifreeze to comply with the minimum concentration, otherwise a mixture is obtained that has a corrosive effect. The cooling system can be damaged. Never mix inhibitors and anti-freeze. SIMOTICS FD 1MH1 Operating Instructions 02/2019 39 Preparations for use 4.5 Coolant specification Biocides Closed cooling circuits with soft water (dH > 4) are susceptible to microbes. The risk of corrosion caused by microbes is virtually non-existent in chlorinated drinking water systems. No strain of bacteria can survive when the appropriate quantity of anti-freeze is added. The following microbes can occur: Bacteria that cause the formation of slime Corrosive bacteria Bacteria that cause deposits of iron The type of bacteria determines the suitability of a biocide. At least one water analysis per annum (to determine the number of bacterial colonies) is recommended. You can purchase suitable biocides, for example from Nalco. Note Determining the appropriate biocide The type of bacteria determines the biocide. Antifreeze already has a biocidal effect for the minimum concentration specified above. The manufacturer's recommendations must be followed in regard to the dosage and compatibility with any inhibitor that might be used. Never mix biocides and anti-freeze. 4.5.4 Cooling capacity derating If you use antifreeze, then observe the cooling capacity derating factor, dependent on the antifreeze concentration, as listed in the table. Anti-freeze Concentration Cooling capacity derating factor 20% 0% 25% 0% Antifrogen N 30% 0% Varidos FSK 35% 2% Antifrogen L 40% 4% 45% 5% Antifrogen N / Varidos FSK ethylene glycol Antifrogen L propylene glycol Note Order-specific agreements Order-specific agreements regarding the cooling water specification can deviate from the cooling water specification mentioned. 40 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.6 Thermal motor protection 4.6 Thermal motor protection The machine is equipped with measuring equipment for direct monitoring of the motor temperature to protect the machine against overload during operation. Plan a corresponding circuit for monitoring. 4.7 Thermal motor protection using PTC thermistors (option) The machine is equipped with PTC thermistors for direct monitoring of the motor temperature to protect the machine against overheating during operation. Plan a corresponding circuit for monitoring. 4.8 Interlock circuit for the automatic regreasing system (option) Relubrication is permitted only for a rotating shaft. Consequently, deploy an interlock circuit for machines with automatic regreasing system to prevent them from operating at machine standstill. 4.9 Interlock circuit for anti-condensation heating If the anti-condensation heating is operated while the machine is running, this can increase the temperatures inside the machine. Install an interlock circuit that switches off the anti-condensation heating once the main machine is switched on. Only switch on the anti-condensation heating after the machine has been switched off. See also Safety instructions for operation (Page 119) WARNING Explosion hazard If the anti-condensation heating is switched on directly after the machine is switched off, the temperature class or the maximum surface temperature of the machine can be exceeded. In an explosive atmosphere, there is a risk of an explosion. This can result in death, serious injury or material damage. Only switch on the anti-condensation heating after the motor has been switched off. Carefully comply with the data on the anti-condensation heating plate. SIMOTICS FD 1MH1 Operating Instructions 02/2019 41 Preparations for use 4.10 IM B5 type of construction with support foot 4.10 IM B5 type of construction with support foot For machines, type of construction IM B5, provide an additional support foot at the NDE. The support foot is not included in the scope of supply. Use an appropriately sized support foot with the appropriate rigidity. The support foot must be able to support the total weight of the machine. The weight of the machine is stated on the rating plate, data on geometry is shown in the dimension drawing. There is a threaded hole M36 at the bottom of the machine where you can attach the support foot. WARNING Danger if there is no support at the NDE If the machine has no support at the NDE, the flange cannot hold the weight of the machine. The machine or machine parts may loosen. This can result in death, serious injury or material damage. Use an appropriately sized support base. 4.11 Noise emissions Noise emissions During operation, the machine's noise emission levels can exceed those permitted at the workplace, which can cause hearing damage. Ensure that nobody is in the area of increased noise emissions during machine operation. Take steps to reduce noise so that the machine can be operated safely within your system. The following measures may help to reduce noise. - Covers - Noise insulation - Hearing protection measures 4.12 Rotational speed limit values Excessive rotational speed can lead to serious damage to the machine. This can result in death, serious injury, or material damage. Avoid operation above the permissible speed by using the appropriate control function. Observe the speeds stamped on the rating plate. 42 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.13 Complying with speed-torque curve 4.13 Complying with speed-torque curve Risk of explosion if the speed-torque characteristic is exceeded If the load torque exceeds the speed-torque characteristic, then the temperature class can be exceeded. An explosion can occur. This can result in death, serious injury or material damage. It is not permissible that the values defined by the speed-torque characteristic are exceeded. Observe the data on the extra rating plate on the motor. 4.14 Voltage and frequency fluctuations during line operation Unless otherwise stated on the rating plate, the permissible voltage/frequency fluctuation is corresponds to Zone B in IEC / EN 600341. Permissible fluctuations that go beyond this are indicated on the rating plate. Operate the machine in continuous operation in Zone A. Prolonged operation in Zone B is not recommended: Exceeding the permissible tolerances for voltage and frequency can lead to an impermissibly high temperature rise of the winding. This can result in long-term damage to the winding. Limit exceptions of this sort with regard to the values that arise, how often, and for how long they occur. Where possible and within a reasonable time take corrective actions such as reducing the power. In this way you can avoid that the service life of the machine is reduced as a result of thermal aging. 4.15 Phase synchronization during supply system switching Damage to the machine may be caused when switching to another supply system with different phasing. The phasing must be synchronized during switching. Use appropriate means to synchronize the phasing. 4.16 System-inherent frequencies Excessively high vibration levels and system resonances can damage the machine set. Configure and match the system consisting of the foundation and machine set in such a way that no system resonances can arise and result in the permissible vibration levels being exceeded. The vibration values according to DIN ISO 10816-3 must not be exceeded. SIMOTICS FD 1MH1 Operating Instructions 02/2019 43 Preparations for use 4.17 Torsional load of the drive train 4.17 Torsional load of the drive train In the event of faults in the electrical connection during operation, excessive air gap torques can lead to additional mechanical torsional load on the line shaft. Note The system planner is responsible for the entire drive train. WARNING Torsional loadings of the shaft assembly If the configuration does not correctly recognize the mechanical torsional loadings of the shaft assembly, this can lead to serious damage to the machine. This can result in death, serious injury or material damage. When planning the system, consider the configuration data. Note You can find more information in Chapter 2 of catalog D81.8. 4.18 Transport 4.18.1 Safety instructions for transport Observe the following when carrying out any work on the machine: Comply with the general safety instructions Comply with the applicable national and sector-specific regulations. When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. The information required to correctly attach, lift and transport the machine - such as weight, center of gravity and attachment points - is provided here: Machine dimension drawing and the associated explanations Transport data Rating plate and lifting plate, if available Shipping parts list Packaging 44 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.18 Transport Danger when incorrectly lifting and transporting Danger of death, serious injury, or substantial material damage caused by tipping or falling transported goods. Comply with the following safety instructions: All work must be performed with due caution and care. Comply with any notes in the shipping papers. Carefully comply with all of the handling information and markings on the packages whenever transporting and putting the equipment into storage according to ISO 780. Only use suitable and adequately dimensioned lifting equipment, transport equipment and industrial trucks. Danger due to incorrect attachment and lifting Ensure that suitable lifting equipment is available. Only hoist the goods using the designated hoisting points and/or at marked positions. The attachment points are not dimensioned for additional loads. Use suitable strap guiding or spreading devices. If not specified otherwise in the transport data, always transport the machine in the position associated with its specific type of construction. Danger due to damaged attachment points Carefully check the attachment points provided on the machine, e.g. attachment eyes, lifting lugs or ring bolts for possible damage. Replace any damaged attachment points. Before using, carefully ensure that the attachment points are correctly attached. Bearing damage caused by vibration Depending on the version, the machine is fitted with a rotor shipping brace. Not using the rotor shipping brace can cause damage to the bearings if it is jolted or subject to vibration during transport or storage. Always transport the machine with the rotor shipping brace mounted. Remove the rotor shipping brace at the latest possible time, e.g. just before attaching the output elements or just before installing in the plant or system. If the customer already has mounted parts, such as a coupling or belt pulley, the bearings can be damaged during transport. In this case, make sure that the customer uses a rotor shipping brace. Protect the motor against strong radial shocks and vibration when storing, as the rotor shipping brace cannot completely absorb these forces. Do not remove the rotor shipping brace until the machine is in a vertical position. If a machine has to be transported in a horizontal position, the rotor must be fixed in position before the machine is turned onto its side. Vertical machines can be supplied in the horizontal position from the manufacturing plant. SIMOTICS FD 1MH1 Operating Instructions 02/2019 45 Preparations for use 4.18 Transport Danger if the machine falls The attachment points on the machine are designed for the weight of the machine only. If a machine set is lifted and transported at a single machine, this can fracture the attachment point. The machine or machine set may fall. This can result in death, serious injury or material damage. Do not lift machine sets by attaching lifting tackle to the individual machines. Use only the equipment provided, e.g. the openings or lugs on the base plates, for transporting machine sets. Note the maximum capacity of the lifting lug. Danger when attachment points fracture At low temperatures, the material of the attachment points can become brittle. When lifting and transporting, the attachment points can shear off and the motor can fall. This can result in death, serious injury, or material damage. Only lift the machine using the attachment points at temperatures that are not below -20 C. Heat up the attachment points properly beforehand. 4.18.2 Checking the delivery The components are assembled on an individual basis. When you take receipt of the delivery, please check immediately whether the scope of the delivery matches up with the accompanying documents. No claims relating to defects/items missing from the delivery will be accepted if they are submitted at a later date. Report any apparent transport damage to the delivery agent immediately. Immediately report any apparent defects/missing components to your contact partner. These Operating Instructions are part of the scope of delivery; keep them in a location where they can be easily accessed. 46 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.18 Transport 4.18.3 Securing the rotor Depending on the version, the machine is fitted with a rotor shipping brace. This protects the bearings against damage due to shock and vibration during transport or storage. NOTICE Vibration and shock during transport Not using the rotor shipping brace can cause damage to the machine if it is jolted during transport. Material damage can result. If the machine is fitted with a rotor shipping brace, this should always be used when transporting the machine. The rotor shipping brace must be attached during the transport. Only remove it before pulling on the output element. For machines with a vertical type of construction: - Do not remove the rotor shipping brace until the machine is in a vertical position. - If a machine has to be transported in a horizontal position, the rotor must be fixed in position before the machine is turned onto its side. Vertical machines can be supplied in the horizontal position from the manufacturing plant. SIMOTICS FD 1MH1 Operating Instructions 02/2019 47 Preparations for use 4.18 Transport Alternative rotor bracing If you transport the machine after the output element has been pulled on, then you must axially fix the rotor in another way. Sleeve Figure 4-1 Axial fastening of the rotor Thread in the shaft extension Shaft screw and washer Tightening torque M20 80 Nm M24 150 Nm M30 230 Nm Tightening torques for other rotor shipping brace types The thread in the shaft extension indicates the rotor weight. This indirectly specifies the required preload force when axially fastening the rotor. Thread in the shaft extension Preload M20 20 kN M24 30 kN M30 40 kN Axial preload force for other rotor shipping brace types Note Store the rotor locking device Be sure to store the rotor locking device. It must be remounted for possible disassembly and transport. 48 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.19 Storage 4.18.4 Lifting and transporting the machine If adapter flange and adapter plates are also supplied, then lift them and transport these parts separately. The load suspension equipment for the motor is not rated for lifting the motor with mounted adapter flange is or adapter plates When lifting the machine, refer to the information on the lifting plate or in the technical data: - Comply with the specified spreading angles. - Do not exceed the maximum lifting acceleration and lifting speed specified on the lifting plate. Lift the machine without jerking it. Acceleration a 0.4 g ( 4 m/s2) Velocity v 20 m/min Use only the attachment points (eyebolts) that are attached to the stator frame or the bearing shield. Note Place the machine in a secure and raised position In order to obtain easy and safe access to the underside of the machine, place it in a secure and raised position. DANGER Standing under suspended loads If the lifting gear or load handling attachments were to fail, the machine could fall. This can result in death, serious injury or material damage. Never remain under or in the immediate vicinity of the machine when it is raised. 4.19 Storage 4.19.1 Storing the machine You must correctly store the machine if you do not install and use it after it has been delivered. NOTICE Bearing seizure damage if incorrectly stored If storage conditions are inappropriate there is a risk of bearing seizure damage. Resulting damage can include scoring (brinelling) and corrosion. Follow the storage guidelines. SIMOTICS FD 1MH1 Operating Instructions 02/2019 49 Preparations for use 4.19 Storage Preconditions and preparations Only store goods in undamaged packaging. Unpack the goods if the packaging is damaged. Correctly store the goods corresponding to the type. Repair any damage to the packaging before putting the equipment into storage insofar as this is necessary to ensure proper storage conditions. General instructions for storage Wherever possible, store the machine in a storage room. The place of storage must satisfy the following general conditions: Select a sufficiently sized dry and horizontal place of storage that is above flood level and free of vibration (veff 0.2 mm/s). - The place of storage must be well ventilated as well as free of dust and frost. Provide protection against extreme weather conditions. Ensure that the temperature remains stable in the range from 10 C to 50 C - or 50 F to 120 F. If there is a risk of condensation, the room temperature should be approx. 10 K above the outside temperature. The temperature should not fall below 20 C. - The relative humidity of the air should be less than 60%. - The floor of the place of storage must be sufficiently strong. The maximum permissible floor loading or storage compartment loading may not be exceeded. - The ambient air must not contain any harmful gases. Protect the machine from shocks and humidity. Position machines, devices and crates on pallets, wooden beams or foundations that protect them against rising damp and water. Ensure that the air circulation under the equipment is not impeded. - Place wooden spacer blocks between the covers and the machine. - Covers or tarpaulins must not trail on the floor around the machine. Storing outdoors When storing the machines outside, the storage location must comply with the following conditions: The ground must be sufficiently strong. Prevent the machine from sinking into the ground. Covers or tarpaulins used to protect the equipment against the weather must not make contact with the surfaces of the equipment. Otherwise air circulation under the stored items will be prevented. 50 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.19 Storage Protection against humidity If a dry storage space is not available, protect the machine as follows against humidity: Wrap the machine in humidity-absorbent material. Wrap the machine in plastic film: - Place a humidity meter inside the plastic film. - Place desiccant within the plastic film. - Pack the machine air-tight. Inspect the machine regularly. NOTICE Improper storage or transport Damage to bearings can result from improper storage or transport. On machines that have been supplied with a rotor shipping brace, secure the rotor as per the notes on transportation (Page 47). Protect the motor against strong radial shocks and vibration when storing, as the rotor shipping brace cannot completely absorb these forces. If the customer has already mounted parts, such as a coupling or belt pulley, the bearings can be damaged during transport. In this case, make sure that the customer uses a rotor locking device. WARNING Risk of explosion due to damaged sealing materials Storing the machine at temperatures that do not fall within the specified limits can damage the material of the seals and cause them to fail. As a result, a potentially explosive gaseous atmosphere can enter the machine and be ignited during commissioning. Explosions can occur. This can result in death, serious injury or material damage. The materials used are specially designed for the temperature range required by the customer. Do not store the machine in conditions that lie outside the specified temperature limits. The relevant temperature limits are specified on the rating plate. Long-term storage If you are storing a machine for more than six months, you must check its condition every six months. Store the machine in accordance with the specifications in Section "Storage (Page 49)", and if possible, packed. Check the motor for damage. Carry out any necessary maintenance work. SIMOTICS FD 1MH1 Operating Instructions 02/2019 51 Preparations for use 4.19 Storage Make sure that the storage conditions are such that condensation cannot form in the motor. If the machine is not sealed in plastic film, continually and slightly heat the machine, e.g. with anti-condensation heating (if available), and ensure that the air circulates in the storage room. Storage for longer than three months Lubricate the machine after every two years of storage. 1. Unpack the machine. 2. Remove the rotor shipping brace, if one is being used. 3. When stored for longer than two years, lubricate with twice the grease quantity in accordance with the lubricant plate. This ensures that the grease is evenly distributed and covers all surfaces. Corrosion damage is avoided. NOTICE Damage to roller bearings Roller bearings can be damaged when kept in the same or almost the same position. Every three months, manually rotate the rotor through five revolutions. Make sure that the resting position of the roller bearings after the rotor has been turned is different from what it previously had been. Use the feather key as a reference point, if present. 4. Replace the corrosion protection. 5. Reattach the rotor shipping brace, if present. 6. Pack the machine again. 4.19.2 Protecting the cooling water circuit during storage When supplied, the machine is not filled with cooling water. Protecting the cooling circuit against corrosion You protect the cooling circuit against corrosion when the machine has already been in operation and is then placed in storage or put out of operation. 1. Completely drain the cooling ducts. Blow out the cooling water ducts with compressed air. 1. Close and seal the intake and discharge. 52 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.20 Converter operation 4.19.3 Protection against corrosion If the machine is stored in dry conditions, then apply the subsequently listed anti-corrosion measures: Storage up to six months: Apply a coat of corrosion protective compound to all accessible bare metal parts such as the exposed shaft extension, flange or machine feet. Storage for longer than six months: Apply a coat of long-term anti-corrosion agent to all accessible bare parts. Inspect the machine regularly and if necessary, apply an additional coating of corrosion protection. Document all preservation measures taken so that they can be reversed before the machines are put back into service. 4.20 Converter operation The following chapter is relevant only if the machine has been ordered for converter operation. Note The order number shows whether the machine was ordered for converter operation. In this case, digits 1, 2, 3 or 4 is located at the 6th position of the order number. 4.20.1 Converter operation of explosion-proof machines The operation of the explosion-proof machine on the frequency converter is permitted, when the specifications for the speed control range and torque characteristic are observed, and if winding temperature monitoring is ensured via the integrated temperature sensors in conjunction with a tripping unit. WARNING Operation with a converter that is not permissible for the application If a certain converter type has been defined in the test verification document, on the extra rating plate, or in the certificate, the machine is only allowed to be operated with this converter. Death, serious injury, or material damage can result if it is operated with an unauthorized converter. Only operate the motor with the specified converter. SIMOTICS FD 1MH1 Operating Instructions 02/2019 53 Preparations for use 4.20 Converter operation 4.20.2 Supply line configuration NOTICE Asymmetric voltage load during operation on a TN system in delta connection An asymmetric voltage load of the machine winding can occur during operation on a TN system in delta connection with a grounded line conductor. Winding damage can result. Do not operate the machine on a TN system with a grounded line conductor. NOTICE Ground fault during operation on an IT system If a ground fault occurs when connected to an IT supply system, the insulation is excessively stressed. Winding damage can result. If possible, complete the process within two hours. Rectify the fault cause. Deploy a ground fault monitoring. 4.20.3 Converter input voltage The insulation system of SIMOTICS machines always complies with the requirements of stress category C (IVIC C = high stress). If voltage peaks higher than those specified according to IVIC C can occur, then please contact your Siemens partner: For a line supply voltage (converter input voltage) up to max. 480 V, and when controlled from a SINAMICS G/SINAMICS S converter with uncontrolled/controlled infeed: Comply with the guidelines for configuring motor and converter. For line voltages (converter input voltages) higher than 480 V, motors, which are ordered for converter operation, have an appropriate insulation system. Operation with a converter from another manufacturer: Comply with the permissible voltage peaks according to IEC 60034-18-41 in accordance with stress category C, dependent on the particular line voltage (converter input voltage) and the motor insulation system. NOTICE Material damage caused by an excessively high supply voltage The insulation system will be damaged if the supply voltage is too high for the insulation system. This can completely destroy the machine. Comply with the peak voltages as laid down in the guidelines above. 54 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.20 Converter operation 4.20.4 Reducing bearing currents Taking the following actions will reduce the bearing currents: Ensure that the contacts are established over a large area. Solid copper cables are not suitable for high frequency grounding because of the skin effect. Equipotential bonding conductors: Use equipotential bonding conductors: Between motor and driven machine Between motor and converter Between the terminal box and the RF grounding point at the motor enclosure. Selecting and connecting the cable: As far as possible, use symmetrically arranged, shielded connection cables. The cable shielding, made up of as many strands as possible, must have good electrical conductivity. Braided shields made of copper or aluminum are very suitable. The shield is connected at both ends, at the motor and converter. To ensure good discharging of high-frequency currents, provide contacting over a large surface area: - as contact established through 360 at the converter - at the motor, for instance with EMC glands at the cable entries If the cable shield is connected as described, then it ensures the specified equipotential bonding between the motor enclosure and converter. A separate RF equipotential bonding conductor is then not necessary. / / 3( / / / 3( / / 3( Concentric copper or aluminum shield / / 3( Steel armor If the cable shield is not connected due to special secondary conditions, or not adequately connected, then the specified equipotential bonding is not provided. In this particular case, use a separate RF equipotential bonding conductor: - Between the motor enclosure and protective ground rail of the converter. - Between motor enclosure and driven machine - Use braided flat copper straps or high-frequency cables with finely-stranded conductors for the separate RF equipotential bonding cable. - Ensure that the contacts are established over a large area. SIMOTICS FD 1MH1 Operating Instructions 02/2019 55 Preparations for use 4.20 Converter operation Overall system design To specifically reduce bearing currents, you must consider the system as a whole, which comprises the motor, converter, and driven machine. The following measures support you when reducing bearing currents and help to avoid damage: In the overall system, set up a properly meshed grounding system with low impedance. Use the common-mode filter (damping cores) at the converter output. The Siemens sales representative is responsible for selection and dimensioning. Limit the rise in voltage by using output filters. Output filters dampen the harmonic content in the output voltage. Note Converter documentation The operating instructions for the converter are not part of this documentation. Refer also to the configuration information for the converter. 4.20.5 Insulated bearings when operating the converter If the machine is operated from a low-voltage converter, insulated bearings are fitted at the NDE and an insulated encoder with insulated bearings (option). Comply with the plates on the machine relating to bearing insulation and possible bridges. Driving machine Motor Insulated bearings Insulated tachometer fitting Coupling Figure 4-2 Schematic representation of a single drive NOTICE Bearing damage The bearing insulation must not be bridged. Bearing currents can damage bearings. Do not bridge the bearing insulation for subsequent installation work, such as the installation of an automatic lubrication system or a non-insulated vibration sensor. Please contact the service center if necessary. 56 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Preparations for use 4.20 Converter operation Tandem operation If you connect two motors in series in "tandem operation", install an insulated coupling between the motors. Driving machine Motor Insulated bearings Insulated tachometer fitting Coupling Insulated coupling Figure 4-3 Schematic representation of a tandem drive NOTICE Bearing damage Bearing currents can flow if the coupling between the motors of the tandem drive is not insulated. This can damage the DE bearings of both motors. Use an insulated coupling to link the motors. See also Service and Support (Page 177) If you connect two motors in series in "tandem operation", locate a coupling between the motors; this coupling should satisfy the Directive 2014/34/EU or the regulations that apply in the country where the equipment is installed. 4.20.6 Converter operation on a grounded network NOTICE Damage resulting from protective conductor currents When the machine is operated with a converter with current limiting, but without ground-fault monitoring, protective conductor currents of up to 1.7 times the phase conductor current can flow if there is a ground fault on the output side. Neither the PE conductors of normally rated multi-conductor connecting cables nor the PE connecting points of standard terminal boxes is suitable for this purpose. Material damage can result. Use an appropriately sized PE conductor. Connect the PE conductor to the grounding terminal on the motor enclosure. SIMOTICS FD 1MH1 Operating Instructions 02/2019 57 Preparations for use 4.20 Converter operation 58 SIMOTICS FD 1MH1 Operating Instructions 02/2019 5 Assembly 5.1 Safety instructions for mounting Observe the following when carrying out any work on the machine: Comply with the general safety instructions Comply with the applicable national and sector-specific regulations. When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. See also Safety information (Page 15) Injury and material damage caused by inappropriate fastening material If screws of an incorrect property class have been selected or if they have been fastened to an incorrect tightening torque, they may break or become loose. This will cause the machine to move, which could damage the bearings. The rotor could smash into the machine enclosure and machine parts could be flung out of place. This can result in death, serious injury or material damage. Comply with the required property classes for screwed connections. Tighten the screwed connections to the specified tightening torques. Injury and material damage caused by incorrect machine alignment If the machine has not been properly aligned, this will mean the fastening parts are subjected to stress/distortion. Screws may become loose or break, the machine will move, machine parts could be flung out of place. This can result in death, serious injury or material damage. Carefully align the machine to the driven machine. Material damage caused by improper handling Mounting parts such as temperature sensors or speed sensors are attached to the machine and could be ripped off or destroyed as a result of improper handling. This could lead to machine malfunctions, extending even to total loss of the machine. Where necessary, use suitable steps when performing installation work on the machine. Do not stand on cables or attachments during installation. Do not use attachments as steps. SIMOTICS FD 1MH1 Operating Instructions 02/2019 59 Assembly 5.2 Preparations for installation Damage to mounted parts and components as a result of high temperatures The motor components get very hot during operation. High temperatures can damage parts mounted by customers, such as cables manufactured out of materials that are not heat resistant. Temperature-sensitive parts must not come into contact with or be attached to components mounted on the machine. Only use heat-resistant mounting parts. The connecting cables and cable entries must be suitable for the particular application. Loss of conformity with European directives In the delivery state, the machine corresponds to the requirements of the European directives. Unauthorized changes or modifications to the machine lead to the loss of conformity with European Directives and the loss of the associated warranty. Explosion hazard when making modifications to the machine Substantial modifications to the machine are not permitted - or may only be performed by the manufacturer. Otherwise an explosion can occur in an explosive atmosphere. This can result in death, serious injury or material damage. If necessary, please contact the service center. See also Service and Support (Page 177) 5.2 Preparations for installation 5.2.1 Requirements for installation The following requirements must be satisfied prior to starting installation work: Staff have access to the operating and installation instructions. The machine is unpacked and ready for mounting at the installation location. Measure the insulation resistance of the winding before starting any installation work. If the insulation resistance lies below the specified value, take appropriate remedial measures. These remedial measures may necessitate the machine being removed again and transported. 60 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.2 Preparations for installation 5.2.2 Insulation resistance and polarization index Measuring the insulation resistance and polarization index (PI) provides information on the condition of the machine. It is therefore important to check the insulation resistance and the polarization index at the following times: Before starting up a machine for the first time After an extended period in storage or downtime Within the scope of maintenance work The following information is provided regarding the state of the winding insulation: Is the winding head insulation conductively contaminated? Has the winding insulation absorbed moisture? As such, you can determine whether the machine needs commissioning or any necessary measures such as cleaning and/or drying the winding: Can the machine be put into operation? Must the windings be cleaned or dried? Detailed information on testing and the limit values can be found here: "Testing the insulation resistance and polarization index" (Page 61) 5.2.3 Testing the insulation resistance and polarization index WARNING Hazardous voltage at the terminals During and immediately after measuring the insulation resistance or the polarization index (PI) of the stator winding, hazardous voltages may be present at some of the terminals. Contact with these can result in death, serious injury or material damage. If any power cables are connected, check to make sure line supply voltage cannot be delivered. Discharge the winding after measurement until the risk is eliminated, e.g. using the following measures: - Connect the terminals with the ground potential until the recharge voltage drops to a non-hazardous level - Attach the connection cable. Measure the insulation resistance 1. Before you begin measuring the insulation resistance, please read the operating manual for the insulation resistance meter you are going to use. 2. Short-circuit the ends of the temperature sensor cables before applying the test voltage. If the test voltage is connected to only one temperature sensor terminal, the temperature sensor will be destroyed. SIMOTICS FD 1MH1 Operating Instructions 02/2019 61 Assembly 5.2 Preparations for installation 3. Make sure that no power cables are connected. 4. Measure the winding temperature and the insulation resistance of the winding in relation to the machine enclosure. The winding temperature should not exceed 40 C during the measurement. Convert the measured insulation resistances in accordance with the formula to the reference temperature of 40 C. This thereby ensures that the minimum values specified can be compared. 5. Read out the insulation resistance one minute after applying the measuring voltage. Limit values for the stator winding insulation resistance The following table specifies the measuring voltage and limit values for the insulation resistance. These values correspond to IEEE 432000 recommendations. Table 5-1 Stator winding insulation resistance at 40 C UN V Umeas V M U 1000 500 5 1000 U 2500 500 (max. 1000) 100 2500 < U 5000 1000 (max. 2500) 5000 < U 12000 2500 (max. 5000) U > 12000 5000 (max. 10000) RC Urated = rated voltage, see the rating plate Umeas = DC measuring voltage RC = minimum insulation resistance at a reference temperature of 40 C Conversion to the reference temperature When measuring with winding temperatures other than 40 C, convert the measuring value to the reference temperature of 40 C according to the following equations from IEEE 43-2000. (1) RC = KT * RT (2) KT = (0.5) (40-T)/10 RC Insulation resistance converted to 40 C reference temperature KT Temperature coefficient according to equation (2) RT Measured insulation resistance for measuring/winding temperature T in C 40 Reference temperature in C 10 Halving/doubling of the insulation resistance with 10 K T Measuring/winding temperature in C In this case, doubling or halving the insulation resistance at a temperature change of 10 K is used as the basis. The insulation resistance halves every time the temperature rises by 10 K. The resistance doubles every time the temperature falls by 10 K. 62 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.2 Preparations for installation For a winding temperature of approx. 25 C, the minimum insulation resistances are 20 M (U 1000 V) or 300 M (U > 1000 V). The values apply for the complete winding to ground. Twice the minimum values apply to the measurement of individual assemblies. Dry, new windings have an insulation resistance of between 100 and 2000 M, or possibly even higher values. An insulation resistance value close to the minimum value could be due to moisture and/or dirt accumulation. The size of the winding, the rated voltage and other characteristics affect the insulation resistance and may need to be taken into account when determining measures. Over its operating lifetime, the motor winding insulation resistance can drop due to ambient and operational influences. Calculate the critical insulation resistance value depending on the rated voltage by multiplying the rated voltage (kV) by the specific critical resistance value. Convert the value for the current winding temperature at the time of measurement, see above table. Measuring the polarization index 1. To determine the polarization index, measure the insulation resistances after one minute and ten minutes. 2. Express the measured values as a ratio: PI = Rinsul 10 min / Rinsul 1 min Many measuring devices display these values automatically following the measurement. For insulation resistances > 5000 M, the measurement of the PI is no longer meaningful and consequently not included in the assessment. R(10 min) / R(1 min) Assessment 2 Insulation in good condition <2 Dependent on the complete diagnosis of the insulation NOTICE Damage to insulation If the critical insulation resistance is reached or undershot, this can damage the insulation and cause voltage flashovers. Contact the service center (Page 177). If the measured value is close to the critical value, you must subsequently check the insulation resistance at shorter intervals. Limit values of the anti-condensation heating insulation resistance The insulation resistance of the anti-condensation heating with respect to the machine housing should not be lower than 1 M when measured at 500 V DC. SIMOTICS FD 1MH1 Operating Instructions 02/2019 63 Assembly 5.3 Lift the machine to where it will be installed, and position it 5.2.4 Prepare the mating faces (IM B3) Ensure that the foundation faces are flat and free of contaminations. Note Shims To establish a defined mounting surface, you can order shims (option L31) from our Service Center. Check the dimensions of the mounting-foot holes. See also Service and Support (Page 177) 5.2.5 Prepare the mating face for a flange connection Clean the flange before installation, and make sure that the flange face is flat and free of contaminations. Check the geometry of the flange. 5.2.6 Prepare the mating face for wall mounting Ensure that the wall surface is flat and free of contaminations. Check the dimensions of the mounting-foot holes. Support the machine from below, e.g. using a wall bracket or by bolting it. 5.3 Lift the machine to where it will be installed, and position it 5.3.1 Preconditions for correct alignment and secure attachment Detailed specialist knowledge of the following measures is required in order to correctly align and securely fit the equipment. Preparing the foundation Selecting and mounting the coupling Measuring the concentricity and axial eccentricity tolerances Positioning the machine If you are not familiar with the prescribed measures and procedures, then you can make use of the services offered by the local Service Center (Page 177). 64 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.3 Lift the machine to where it will be installed, and position it 5.3.2 Checking the load handling attachments Inspect the load handling attachments such as the load trestles, lifting eyes and ring bolts and also the lifting gear, before lifting the machine: Inspect the load handling attachments on the machine for possible damage. Replace any load suspension equipment that is found to be damaged. Before use, check that the load suspension equipment is correctly attached. When lifting the machine, use only approved and undamaged lifting gear of sufficient rated capacity. Check the lifting gear prior to its use. WARNING The machine can be dropped If the load handling attachments and lifting gear are damaged or not correctly secured, the machine may be dropped during lifting. This can result in death, serious injury or material damage. Inspect the load handling attachments and lifting gear before use. 5.3.3 Removing the rotor shipping brace If a rotor shipping brace is attached to the machine, remove it at the last possible moment, for example, when you are ready to push on the output or drive element. 5.3.4 Removing the rotor shipping brace from machines in vertical type NOTICE Removing the rotor shipping brace in the horizontal position. Dismantling the rotor shipping brace when the machine is in a horizontal position could damage the bearings. Only remove the rotor shipping brace when the machine is in a vertical position. NOTICE Turning the motor over without rotor shipping brace Failure to fit the rotor shipping brace can result in damage to the bearings while the machine is being turned onto its side. Fix the rotor in place before you turn the machine into a horizontal position. SIMOTICS FD 1MH1 Operating Instructions 02/2019 65 Assembly 5.3 Lift the machine to where it will be installed, and position it Note Store the rotor locking device Be sure to store the rotor locking device. It must be remounted for possible disassembly and transport. 5.3.5 Removing anti-corrosion protection Machined, bare metallic surfaces of the motor, such as the shaft end, fitted key, foot and flange surfaces, are treated with an anti-corrosion agent. 1. Remove this layer of anti-corrosion agent from the mounting surfaces of the motor by wiping it away with an absorbent cloth or paper sheet. NOTICE Damage to the machine surface Using metal objects such as scrapers, spatulas, or plates to remove the anti-corrosion protection could result in damage to the surfaces of the machine parts. 2. Then lightly oil the bare surfaces again. 5.3.6 Mounting the output elements Type of balancing The rotor is dynamically balanced. For shaft extensions with featherkeys, the balancing type is specified using the following coding on the face of the drive end of the shaft: "H" means balancing with a half feather key "F" means balancing with a whole feather key Figure 5-1 66 Balancing type on the drive-end side SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.3 Lift the machine to where it will be installed, and position it Pushing on the power output elements Requirements: - The coupling and/or the output element must be appropriately dimensioned for the operating case at hand. Carefully comply with the coupling manufacturer's instructions. - Make sure that the balancing type of the transmission element correctly matches the type of balance of the rotor. - Use only ready drilled and balanced transmission elements. Check the hole diameters and the balancing status before pulling them on. Thoroughly clean the shaft extension. Pulling on: - Warm up the transmission elements to expand them before pulling them on. Select the temperature difference for the heating process to suit the coupling diameter, fit and material. Carefully comply with the coupling manufacturer's instructions. - Power output elements may only be pushed on or pulled off with the correct equipment. The transmission element must be pulled on in one continuous operation via the front thread holes in the shaft or pushed on by hand. - Do not strike it with a hammer, as this would damage the bearings. Shaft extensions with feather key To maintain the balancing quality, you have the following options: If the transmission element is shorter than the feather key with balancing type "H", then you must machine off the section of feather key protruding from the shaft contour and transmission element in order to maintain the balance quality. If the transmission element is drawn up on to the shoulder of the shaft, you must ensure that the part of the coupling groove where the feather key is not inserted is taken into consideration when balancing the coupling. The following applies to all four-pole machines with a frequency 60 Hz: The feather key must be shortened if the coupling hub us shorter than the feather key. The center of gravity of the coupling half should be within the length of the shaft end. The coupling used must be prepared for system balancing. The number of poles of the machine is specified on the rating plate, at the 10th position of the motor type. There, four-pole machines are marked with a "B". Danger when feather keys are flung out The feather key is only secured to prevent it falling out during transport. The feather key may be flung out if the motor is operated without fitted transmission elements, such as coupling, etc. This can result in death, serious injury or material damage. Only operate the motor with the transmission element pulled on. For test operation or when commissioning without transmission element, carefully secure the feather key using a suitable locking element. When doing this, take into account the type of machine balancing. SIMOTICS FD 1MH1 Operating Instructions 02/2019 67 Assembly 5.3 Lift the machine to where it will be installed, and position it 5.3.7 Lifting and transportation To safely lift and transport the machine, the following requirements must be met: Personnel operating cranes and fork-lift trucks must be appropriately qualified. If the machine is packed, depending on the weight, size and on-site conditions, lift crates and transport frames using a fork-lift truck or a crane with slings. Use a crane or fork-lift truck suitable for the load. When lifting the machine, use only approved and undamaged sling guides and spreaders of sufficient rated capacity. Check the lifting equipment prior to its use. The weight of the machine is shown on the rating plate. When lifting the machine, refer to the information on the lifting plate. - Comply with the specified spreading angles. - Do not exceed the maximum lifting acceleration and lifting speed specified on the lifting plate. Lift the machine without jerking it. Acceleration a 0.4 g ( 4 m/s2 ) Velocity v 20 m/min WARNING Transport for a different type of construction If you do not transport or lift the machine in a position appropriate for its construction, the machine can tip, slip into the lifting equipment or fall down. This can result in death, serious injury or material damage. Use only the load carrying device on the stator frame for lifting. Use the load carrying device appropriate for the machine position. Only use suitable rope guiding or spreading devices. WARNING Center of gravity not centered If the center of gravity of a load is not located centrally between the attachment points, the machine can tip over or slip out of the lifting equipment and fall when it is being transported or lifted. This can result in death, serious injury or material damage. Comply with the handling instructions on the machine when transporting it. Be aware of the possibility of different loads on the sling ropes or lifting straps and the carrying capacity of the lifting equipment. Always take account of the center of gravity when transporting or lifting the machine. If the center of gravity is not located centrally between the attachment points, then position the hoisting hook above the center of gravity. 68 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.3 Lift the machine to where it will be installed, and position it Note Place the machine in a secure and raised position In order to obtain easy and safe access to the underside of the machine, place it in a secure and raised position. DANGER Standing under suspended loads If the lifting gear or load handling attachments were to fail, the machine could fall. This can result in death, serious injury or material damage. Never remain under or in the immediate vicinity of the machine when it is raised. 5.3.8 Putting the machine down Requirements The following preconditions must be satisfied before setting down the machine at the installation location: The mating faces must be clean. The anti-corrosion protection paint has been removed from the mating faces, such as the machine mounting feet, flange, ... There is no condensation present within the machine. Setting down the machine Set down the machine slowly and carefully at the installation location to avoid any impact. See also Draining condensation (Page 70) SIMOTICS FD 1MH1 Operating Instructions 02/2019 69 Assembly 5.3 Lift the machine to where it will be installed, and position it 5.3.9 Draining condensation Under the following conditions it is possible that condensate may accumulate within the machine: Wide fluctuations in the ambient temperature, such as direct sunshine combined with high atmospheric humidity Intermittent operation or load fluctuations during operation NOTICE Damage due to condensate If the stator winding is damp, its insulation resistance will be reduced. This can result in voltage flashovers, which can destroy the winding. Condensate can also cause rust to form within the machine. Ensure that condensate can drain away. Depending on the type of installation, the water drainage holes are located at the bottom: Allow the condensation water to discharge for vertical placement In the DE bearing shield, water drain holes are located in the area of the mounting feet or opposite the regreasing system. They are sealed with screw plugs. Figure 5-2 70 Condensation water drain for vertical mounting SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.3 Lift the machine to where it will be installed, and position it Allow the condensation water to discharge for horizontal placement The water drain holes are located in the lower side of the stator enclosure, and sealed with screw plugs. Figure 5-3 Condensation water drain for horizontal mounting To drain the condensation water, proceed as follows: 1. Remove the screw plugs to allow the condensation water to drain. 2. Then reinsert the screw plugs. NOTICE The degree of protection is reduced Nominally the degree of protection of the machine is reduced to IP44 when the screw plug is removed. 5.3.10 Roughly aligning the machine Requirement The transmission element such as a coupling half has already been pulled on. Roughly aligning the machine For horizontal positioning, push the motor sideways across the foundation. When doing so, ensure that the axial position is maintained. SIMOTICS FD 1MH1 Operating Instructions 02/2019 71 Assembly 5.4 Installing the machine 5.4 Installing the machine 5.4.1 Preconditions for smooth, vibration-free operation Preconditions for smooth, vibration-free operation: Stable foundation design Precise alignment of the machine Correct balancing of parts to be fitted to the shaft end. Maintaining the vibration velocity according to ISO 108163 5.4.2 Aligning the machine to the driven machine and mounting (IM B3 / IM B35) 1. Refer to any instructions for aligning the driven machine and those of the coupling manufacturer. 2. Align the machines with coupling output to the driven machine in such a manner that the center lines of the shafts at the operating temperature do not have any parallel or angular offset. This ensures that no additional forces affect their bearings during operation. If the thermal change of the motor and the driven machine is different, couple in the cold state with an appropriate alignment offset. The alignment offset to be set in the cold state must be determined and specified by the system specialist. 3. For the vertical positioning (x0), place thin shims over a large surface area under the machine feet. The number of shims should be kept as low as possible, i.e. stack as few as possible. This also prevents the machine being subjected to any stress/distortion. Use the existing tapped holes for the forcing-off bolts to raise the machine. The balance state of the shaft (full-key or half-key balancing) and alignment errors primarily influence the service life of the bearing, especially for high motor speeds or when using rigid couplings. 72 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.4 Installing the machine 4. When positioning the machine, ensure that a uniform axial gap (y0) is maintained around the coupling. 5. Fix the machine to the foundation. The choice of fixing elements depends on the foundation and is the plant operator's responsibility. [ ' \ Plates placed under the motor for alignment Laser alignment Figure 5-4 Table 5-2 Schematic diagram: Aligning the machine to the driven machine Permissible deviations for aligning the machine with flexible coupling Max. speed nmax Max. parallel offset x Max. angular offset y nmax 1500 rpm xmax = 0.08 mm ymax = 0.08 mm / 100 mm D 1500 rpm < nmax 3600 rpm xmax = 0.05 mm ymax = 0.05 mm / 100 mm D Note Machine expansion When performing alignment, make allowance for the thermal expansion of the machine due to rising temperature. See also Tightening torques for screw and bolt connections (Page 179) SIMOTICS FD 1MH1 Operating Instructions 02/2019 73 Assembly 5.4 Installing the machine 5.4.3 Aligning the machine to the driven machine and attaching it to it (IM B5) The standard flange is provided with a centering. The choice of fit for the mating flange on the driven machine is the system manufacturer's or the plant operator's responsibility. Note If the machine is not fitted with a standard flange, align the machine to suit the driven machine. Procedure The machine axis must be horizontal when it is lifted and the flange must be parallel to the mating flange, so as to avoid seizing and stressing. Otherwise damage to the centering will result. 1. Grease the centering flange with assembly paste to make the process easier. 2. Screw three studs into tapped holes spaced about 120 apart around the driven machine flange. The studs act as positioning aids. 3. Position the machine so that its axis is aligned with that of the driven machine, but not yet quite touching. Advance the machine slowly towards the driven machine; advancing too quickly risks damaging the centering. 4. If necessary, rotate the machine into the right position so that the clearance holes in the flange are central to the tapped holes. 5. Move the machine fully up against the mating flange so that it is fully in contact. 6. Fix the machine using the flange fixing bolts, finishing by replacing the studs. See also Tightening torques for screw and bolt connections (Page 179) There is a threaded hole M36 at the bottom of the machine where you can fasten the support base. Mount the support base so that no additional mechanical tensions can occur in the housing. WARNING Mechanical tensions The machine may be damaged by additional mechanical tensions in the housing caused by incorrect mounting of the support base. The machine or machine parts may loosen during operation. This can result in death, serious injury or material damage. Mount the support base so that no additional mechanical tensions can occur in the housing. 74 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.4 Installing the machine 5.4.4 Aligning the machine to the driven machine and attaching it to it (IM V1, IM V10) The standard flange is provided with a centering. The choice of fit for the mating flange on the driven machine is the system manufacturer's or the plant operator's responsibility. Note If the machine is not fitted with a standard flange, align the machine to suit the driven machine. Procedure The machine axis must be vertical when it is lifted and the flange must be parallel to the mating flange, so as to avoid seizing and stressing. Otherwise damage to the centering will result. 1. Grease the centering flange with assembly paste to make the process easier. 2. Screw in two studs into tapped holes on opposite sides of the driven machine flange. The studs act as positioning aids. 3. Lower the machine slowly toward the driven machine and into the centering, so that the flanges do not quite touch. Lowering too quickly risks damaging the centering. 4. If necessary, rotate the machine into the right position so that the clearance holes in the flange are central to the tapped holes. 5. Lower the machine completely onto the mating flange so that it is fully in contact; then remove the studs. 6. Fix the machine using the flange fixing bolts. See also Tightening torques for screw and bolt connections (Page 179) Alignment accuracy The coaxial characteristic of the shafts of electrical machines and driven machine may not exceed 0.05 mm in diameter. 5.4.5 Axial and radial forces You can obtain the permissible values for axial and radial forces by contacting the Siemens Service Center (Page 177) or referring to the machine catalog. SIMOTICS FD 1MH1 Operating Instructions 02/2019 75 Assembly 5.5 Connecting the cooling water supply WARNING Damage to bearings or the shaft Large output masses and their centers of gravity outside the shaft extensions can lead to resonance in operation. This can result in damage to the bearings and shaft. In an explosive atmosphere, there is a risk of explosion. Death, serious injury, or material damage can result. Ensure that the permissible loads for the forces on the shaft extension are adhered to in accordance with the catalog data or configuration data. Note You can find more information in Chapter 2 of catalog D81.8. 5.5 Connecting the cooling water supply There are three couplings and on the bearing shield for the coolant connection. The lower coupling is used to drain the coolant for type of construction IM B3. Figure 5-5 76 Standard coolant connections and coolant drain hole SIMOTICS FD 1MH1 Operating Instructions 02/2019 Assembly 5.5 Connecting the cooling water supply 1. With the "Piping" option, piping is attached on the right, left or top at the NDE. You can then connect the coolant supply radially to the appropriate side. Different threads are available depending on the machine type. Machine type 1LH....-3A...-.... / 1MH....-3A...-.... Thread G1/2" 1LH....-3B...-.... / 1MH....-3B...-.... 1LH....-4A...-.... / 1MH....-4A...-.... G3/4" 1LH....-4B...-.... / 1MH....-4B...-.... 2. Use flexible water lines and hoses. This avoids mechanical stress at the connections as a result of the heat-dependent height increase of the machine (thermal expansion). 3. Only use valves, fittings and cooling water pipes made of rust-proof, stainless steel in the cooling system. 4. Make sure that the cooling water complies with the required cooling water specification. 5. Make sure that the appropriate volume of cooling water is available. 6. Hold the hexagon coupler with an open-ended wrench while you screw in the water pipes. NOTICE Damage to the pipe system The hexagonal couplers are connected directly to the water pipes inside the machine. Applying excessive torque when screwing in can damage the pipe system. Hold the couplers with an open-ended wrench while you screw in the water pipes. Avoid axial forces at the coolant connections. 7. Screw the cooling water pipes into the female thread. You can connect the inlet and outlet as required. See also Coolant specification (Page 36) Coolant specification (M85 "stainless steel version" option) (Page 38) NOTICE Bleed air from the cooling ducts Adequate machine cooling cannot be guaranteed if the cooling ducts are not completely filled with water. The machine can overheat. Vent the cooling ducts when filling. Completely fill the cooling ducts with water. SIMOTICS FD 1MH1 Operating Instructions 02/2019 77 Assembly 5.5 Connecting the cooling water supply 78 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.1 6 Safety instructions for the electrical connection Observe the following when carrying out any work on the machine: Comply with the general safety instructions (Page 15) Comply with the applicable national and sector-specific regulations. When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. Risk of explosion by fixing elements becoming loose If you use fixing elements made from the wrong material or apply the wrong tightening torque, this could impair current transfer or cause connecting parts to become loose. Fastening elements can work loosely, so that the minimum air clearances are no longer maintained. Sparking formation may occur, in an explosive atmosphere it can lead to an explosion. This could result in death, serious injury or material damage to the machine or even in failure, which could in turn lead indirectly to material failure of the system. Tighten the screwed connections to the specified tightening torques. Observe any specifications regarding the materials from which fixing elements must be made. When performing servicing, check the fastenings. See also Tightening torques for screw and bolt connections (Page 179) Note Service Center If you require support when electrically connecting up the machine, please contact the Service Center (Page 177). 6.2 Basic rules The following generally applies to electrical connections: Ensure that there is a safe and reliable PE ground connection before starting any work. The connecting cables can be sealed and secured at every cable entry point into the terminal box. SIMOTICS FD 1MH1 Operating Instructions 02/2019 79 Electrical connection 6.3 Terminal box Lay the connecting cables and in particular the PE conductor in the terminal box in an open arrangement so that chafing of the cable insulation is prevented. Connect the machine in such a way that a permanent, safe electrical connection is maintained. Avoid protruding wire ends. Lay and secure external auxiliary cables separately from the main cable. Elements with cable ties may be present for this purpose. In case of high humidity or when installed outside, water drops can move along the cable jacket and enter the motor through the cable entry and cable gland. If you route the cable with an appropriate loop then water doesn't enter the terminal box, but simply drips off. ; ; Figure 6-1 6.3 Water drip loop Terminal box Depending on the version, different terminal boxes may be installed on the machine. Depending on the terminal box, different cable entries and options for the cable connection are possible. You can identify the terminal box installed on the machine via the illustrations in the following chapters. 80 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.3 Terminal box 6.3.1 Terminal box 1XB1621 Figure 6-2 Terminal box 1XB1621 The connecting cables are introduced into the 1XB1621 terminal box through the cable glands with threaded holes 2 x M80 x 2 and 2 x M25 x 1.5. The cable glands are not included in the standard scope of supply. The version with sealing insert with break-off ring is optional. You can find additional information here: Bringing cables into the terminal box 1XB... with cable gland (Page 94) Connecting cables without cable lugs (Page 96) Connecting cables with cable lugs (Page 95) See also Bringing cables into the terminal box 1XB... with sealing insert with break-off ring (Page 92) 6.3.2 Terminal box 1XB1631 Figure 6-3 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Terminal box 1XB1631 81 Electrical connection 6.3 Terminal box The connecting cables are introduced into the 1XB1631 terminal box through cable glands with threaded holes 4 x M80 x 2 and 2 x M25 x 1.5. The cable glands are not included in the standard scope of supply. The version with onion sealing ring is optional. You can find additional information here: Bringing cables into the terminal box 1XB... with cable gland (Page 94) Connecting cables without cable lugs (Page 96) Connecting cables with cable lugs (Page 95) See also Bringing cables into the terminal box 1XB... with sealing insert with break-off ring (Page 92) 6.3.3 Terminal box 1XB7730 Only a three-core power cable can be connected in terminal box 1XB7730. Figure 6-4 Terminal box 1XB7730 The connecting cables are introduced into the 1XB7730 terminal box through the cable glands with threaded holes 1 x M72 x 2 and 3 x M25 x 1.5. The cable glands are not included in the standard scope of supply. You can find additional information here: Bringing cables into the terminal box 1XB... with cable gland (Page 94) Connecting cables with cable lugs (Page 95) Connecting cables without cable lugs (Page 96) 82 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.3 Terminal box 6.3.4 Terminal box 1XB7731 Figure 6-5 Terminal box 1XB7731 The connecting cables are introduced into the 1XB7731 terminal box through the cable glands with threaded holes 2 x M72 x 2 and 3 x M25 x 1.5. The cable glands are not included in the standard scope of supply. You can find additional information here: Bringing cables into the terminal box 1XB... with cable gland (Page 94) Connecting cables with cable lugs (Page 95) Connecting cables without cable lugs (Page 96) 6.3.5 Terminal box 1XB7740 Figure 6-6 Terminal box 1XB7740 The connecting cables are introduced into the 1XB7740 terminal box through the cable glands with threaded holes 4 x M80 x 2 and 3 x M25 x 1.5. The cable glands are not included in the standard scope of supply. SIMOTICS FD 1MH1 Operating Instructions 02/2019 83 Electrical connection 6.3 Terminal box You can find additional information here: Bringing cables into the terminal box 1XB... with cable gland (Page 94) Connecting cables with cable lugs (Page 95) Connecting cables without cable lugs (Page 96) 6.3.6 Terminal box 1XB7750 Figure 6-7 Terminal box 1XB7750 The connecting cables are introduced into the 1XB7750 terminal box through the cable glands with threaded holes 8 x M72 x 2 and 3 x M25 x 1.5. The cable glands are not included in the standard scope of supply. You can find additional information here: Bringing cables into the terminal box 1XB... with cable gland (Page 94) Connecting cables with cable lugs (Page 95) Connecting cables without cable lugs (Page 96) 6.3.7 Rotating the terminal box Depending on the terminal box and version, you can rotate the terminal box through 90 in accordance with the connection direction. The implementation on the other motor side is possible only with the support of the Service Center (Page 177). If you want to rotate a terminal box not listed below, then also contact the Service Center. 84 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.3 Terminal box Rotating the terminal box depends on the mount and the cross-section of the internal stator cables as well as the terminal box type: 1XB7730 - With installed internal stator cables, you can rotate the terminal box through 90. 1XB7731 - For six or fewer cables, you can rotate the terminal box with installed stator cables through 90. - For more than six cables, you must remove the internal stator cables before rotation. 1XB7740 - For 12 or fewer cables and lower cross-sections, you can rotate the terminal box with installed stator cables through 90. - For more than 12 cables - or for cables with a cross-section greater than 50 mm - you must remove the internal stator cables before rotating the terminal box. 1XB7750 - Remove the internal stator cables before rotating the terminal box. Rotating a terminal box with mounted stator cables 1. Ensure that the motor is disconnected from the power supply. 2. Release two diagonally opposed screws for the cover, and secure the cover using two M10 threaded bars screwed in diagonally opposing one another. Release the two other screws and lift the cover off the terminal box. The terminal box cover is very heavy. Especially when in a lateral position, ensure that the terminal box does not fall down. 3. If the motor is already connected: - Remove the cables of the power supply. - Release the screw connection of the cable entry. Remove the cables through the opening. 4. Remove the grounding straps on two sides of the terminal box lower section. 5. Remove the screwed joints of the lower section with the console or optionally the cable duct. 6. Screw in two eye-bolts diagonally in the M10 thread at the corners. Slightly raise the terminal box housing using a crane. 7. Rotate the terminal box through 90 in the desired direction. Carefully place the terminal box down. Take care not to damage the seal. 8. Screw the terminal box with the console / cable duct (4 x M16, tightening torque 170 Nm). SIMOTICS FD 1MH1 Operating Instructions 02/2019 85 Electrical connection 6.3 Terminal box 9. Fasten the grounding straps to the terminal box lower section and the console or cable duct: - After rotation, remove the plugs of the two nearest M8 threads on the console or cable duct. - Grind the surface at the drilled holes so that the grounding straps have metallic contact. - Then fasten the two straps to the terminal box lower section and the console or cable duct (4x M8, tightening torque 11 Nm). - Protect the bare areas at the contact with corrosion protection. 10.Reconnect the power supply cables. More information: - Connecting the grounding conductor (Page 89) - Introducing and routing the cables ... - Connecting cables ... 11.Screw in the two diagonally arranged threaded bars and slide the cover onto these bars. Take care not to damage the seal. 12.Fix the two free screw connections and tighten by hand. 13.Remove the threaded bars and screw in the two other screws. 14.Tighten all screws (4 x M10, tightening torque 40 Nm). Rotating a terminal box with removed stator cables 1. Ensure that the motor is disconnected from the power supply. 2. Release two diagonally opposed screws for the cover, and secure the cover using two M10 threaded bars screwed in diagonally opposing one another. Release the two other screws and lift the cover off the terminal box. The terminal box cover is very heavy. Especially when in a lateral position, ensure that the terminal box does not fall down. 3. If the motor is already connected: - Remove the cables of the power supply. - Release the screw connection of the cable entry. Remove the cables through the opening. 4. Release the screwed connections of the internal stator cables, optionally also those at the neutral point. 5. Remove the grounding straps on two sides of the terminal box lower section. 6. Remove the screwed joints of the lower section with the console or optionally the cable duct. 7. Screw in two eye-bolts diagonally in the M10 thread at the corners. Slightly raise the terminal box housing using a crane. 8. Rotate the terminal box through 90 in the desired direction. Carefully place the terminal box down. Take care not to damage the seal. 9. Screw the terminal box with the console / cable duct (4 x M16, tightening torque 170 Nm). 86 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.3 Terminal box 10.Fasten the grounding straps to the terminal box lower section and the console or cable duct: - After rotation, remove the plugs of the two nearest M8 threads on the console or cable duct. - Grind the surface at the drilled holes so that the grounding straps have metallic contact. - Then fasten the two straps to the terminal box lower section and the console or cable duct (4x M8, tightening torque 11 Nm). - Protect the bare areas at the contact with corrosion protection. 11.Connect the cables in accordance with the circuit diagram on the inside of the cover (M12, tightening torque 20 Nm). Ensure that the minimum air clearances are observed. More information: Minimum air clearances (Page 100) 12.Reconnect the power supply cables. More information: - Connecting the grounding conductor (Page 89) - Introducing and routing the cables ... - Connecting cables ... 13.Screw in the two diagonally arranged threaded bars and slide the cover onto these bars. Take care not to damage the seal. 14.Fix the two free screw connections and tighten by hand. 15.Remove the threaded bars and screw in the two other screws. 16.Tighten all screws (4 x M10, tightening torque 40 Nm). See also Connecting cables with cable lugs (Page 95) Connecting cables without cable lugs (Page 96) Bringing cables into the terminal box 1XB... with cable gland (Page 94) 6.3.8 Mounting/removing the terminal box When removing or installing the terminal box cover, secure it using diagonally arranged M10 threaded bars to prevent it falling. Removing the terminal box 1. Release two diagonally opposing screws at the terminal box cover and replace them by threaded bars. 2. Release the two other screws. 3. Carefully pull the terminal box cover over the threaded bars. SIMOTICS FD 1MH1 Operating Instructions 02/2019 87 Electrical connection 6.4 Preparation Mounting the terminal box 1. Screw in the two threaded bars diagonally at the lower section of the terminal box. 2. Slide the terminal box cover over the threaded bars onto the lower section of the terminal box. 3. Screw the screws into the free holes and tighten by hand. 4. Release the threaded bars. 5. Tighten all four M10 screws, tightening torque 40 Nm. 6.4 Preparation 6.4.1 Terminal designation According to IEC / EN 600348, the following basic definitions apply to the terminal designations for 3-phase machines: Table 6-1 1 U Terminal designations using the 1U1-1 as an example 1 - 1 Designation x Index for pole assignment for pole-changing machines where applicable. A lower index signifies a lower speed. Special case for split winding. x Phase designation U, V, W x Index for winding start (1) or end (2) or if there is more than one connection per winding x 6.4.2 Additional indices for cases in which it is obligatory to connect parallel power feed cables to several terminals with otherwise identical designations Selecting cables Take the following criteria into account when selecting the connecting cables: Rated current Rated voltage Possibly a service factor System-dependent conditions, such as ambient temperature, routing type, cable crosssection as defined by required length of cable, etc. Requirements according to IEC/EN 602041 Dimensioning for bundled cable routing, e.g. according to DIN VDE 0298 Part 4 or IEC 60364-5-52 Requirements according to IEC/EN 60079-14 Configuration notes 88 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.4 Preparation 6.4.3 Connecting the grounding conductor The grounding conductor cross-section of the motor must be in full conformance with the installation specifications, e.g. in accordance with IEC 60034-1. External conductor cross-section S Grounding conductor cross-section mm mm 35 25 50 25 70 35 95 50 120 70 150 70 185 95 240 120 300 150 400 185 There is a hexagon bolt with a flat washer and a spring washer on the stator frame at the designated connection point for the grounding conductor. The grounding conductor can be connected as follows: With stranded cables with cable lugs With flat cables with cable end designed accordingly As an alternative, you can connect the grounding conductor without cable lugs using a clamping plate at the marked connection point. Connecting the grounding conductor Use the connecting terminals designated for the grounding conductor in the terminal box. Ensure that the connecting surface is bare and is protected against corrosion using a suitable substance, e.g. acid-free Vaseline. Arrange the flat washer and spring washer under the screw head. SIMOTICS FD 1MH1 Operating Instructions 02/2019 89 Electrical connection 6.4 Preparation Check that the maximum permissible clamping thickness of 10 mm for the cable lug or strap is not exceeded. Fasten the clamping screw according to the following table. Screw-in depth and tightening torque are different depending on whether cable lugs or ground terminals are used. Screw Screw-in depth Tightening torque M6 > 6 mm 8 Nm When using cable lugs When using grounding terminals M8 > 8 mm 20 Nm M12 x 25 > 16 mm 38 Nm M16 x 35 > 20 mm 92 Nm M6 > 9 mm 8 Nm M8 > 12 mm 20 Nm M10 > 15 mm 40 Nm M12 > 18 mm 70 Nm M16 > 20 mm 170 Nm See also Converter operation (Page 107) 6.4.4 Connect metal shield in the terminal box If you are using metal-armored cables that are inserted into the terminal or auxiliary terminal boxes with non-intrinsically safe circuits, then ground the metal shield in the terminal box. Additional grounding points are permissible. In terminal boxes with internal grounding part, connect the metal shield to the internal grounding point. In terminal boxes without internal grounding part, connect the metal shield to one of the green-yellow grounding terminals. 6.4.5 Connection without terminal box If the machine was ordered without terminal box (where the cables are simply brought out of the motor), then the proper connection must be made in an external terminal box. WARNING Incorrect dimensioning Faults can occur if the appropriate technical data is not complied with when connecting up. For instance, degree of protection, minimum air and creepage distances. These faults can result in eventual or immediate death, serious injury or material damage. Ensure that the external terminal box is dimensioned according to the data on the rating plate and is suitable for the respective use. 90 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.4 Preparation If the motor has been ordered with brought-out leads, in this case you must comply with the relevant conditions for Zone 2. It is assumed that the buyer, the installer and users of the installation are familiar with these conditions and will carefully observe them. 6.4.6 Connecting the machine for a specific direction of rotation If the machine has one shaft extension or two shaft extensions with different diameters, the direction of rotation when looking at the front of the single or the thicker shaft extension is defined as follows: If you connect the line cables with phase sequence L1, L2, L3 to U, V, W or according to NEMA at T1 T2 T3, then a clockwise phase sequence is obtained. If you interchange two connections, e.g. L1, L2, L3 at V, U, W or according to NEMA at T2 T1 T3, then a counterclockwise phase sequence is obtained. On machines which are only allowed to run in one direction, the rating plate shows an arrow which indicates the permitted direction of rotation, and it also specifies the terminal connections in the required phase sequence. Check the appropriate data before connecting the line feeder cables. NOTICE Incorrect direction of rotation The machine will not be adequately cooled if it is operated other than how it was originally ordered or with the incorrect direction of rotation. This can result in machine damage. Observe the direction of rotation data on the nameplate. 6.4.7 Undrilled entry plate If the entry plate is undrilled, you should match the number and size of the cable glands to the operating conditions. 1. Unscrew the cable entry plate. 2. Drill the required number of holes or threads in the required size into the cable entry plate. The thickness of the plate is selected in such a way as to give a sufficient number of turns when the holes are tapped. Please note that you are responsible for ensuring that the entry plate still has sufficient strength after the holes have been drilled and tapped. 3. Mount the cable entry plate and the cables with the cable glands onto the terminal box. SIMOTICS FD 1MH1 Operating Instructions 02/2019 91 Electrical connection 6.5 Inserting and routing the cables Drill holes in the cable entry plate If you drill holes in the cable entry plate for explosion-protected motors, then document the data about these holes in the motor documentation: Number and size of the holes Type of thread, e.g. metric or NPT Data regarding the installation of pipes and accessories is provided in IEC / EN 60079-14. 6.5 Inserting and routing the cables Table 6-2 Connection technology (with cable lug / connection without cable lug) Terminal box Connection GT640 1XB1621 1XB1631 1XB7730 1XB7731 With cable lug (Page 95) Without cable lug (Page 96) 1XB7740 1XB7750 6.5.1 Bringing cables into the terminal box 1XB... with sealing insert with break-off ring The 1XB1621, 1XB1631 terminal boxes can be equipped optionally with a sealing insert with break-off ring. The connecting cable is sealed at the cable entry location using a cut-out sealing insert and is fastened using a strain relief device. 92 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.5 Inserting and routing the cables Bringing cables into the terminal box and connecting them The terminal box is opened, the cable cut to the correct length and stripped back. Make sure that no external forces are acting on the cable connection. Figure 6-8 1P Strain relief device and sealing insert Proceed as follows when connecting the cables: 1. Remove the top part of the strain relief and release the fixing screws for the bottom part of the strain relief . The strain relief device can be located either in the terminal box or externally. If necessary, switch the direction sense of the strain relief device. 2. Cut the seal insert so that its opening is 1 to 3 mm smaller than the diameter of the cable. 3. Pull the sealing insert over the end of the cable. 4. Prepare the end of the cable depending on the cable and its use, e.g. with a cable lug. 5. Connect the ends of the cables to the terminals in accordance with the circuit diagram. The circuit diagram is located in the cover of the terminal box. Refer to the "Connecting cables..." section for more information. 6. You might need to use a sleeve made of suitable sealing tape to modify the diameter where it passes through the sealing insert. Push the sealing insert onto the prepared sleeve. 7. Insert the cable with the seal insert in position into the gland opening. Screw the strain relief device together once the cable is in a concentric position in the gland opening. 8. Secure the strain relief device. 9. Tighten the clamping screws of the strain relief device so that the cable is clamped as necessary, but do not damage the cable insulation. We recommend a torque of 5 Nm. 10.Retighten the clamping screws after 24 hours. WARNING Damage to insulation If you tighten the strain relief clip clamping screws too tightly this can damage the insulation. Damaged insulation can result in arcing. This can result in death, serious injury or material damage. Tighten the strain relief clip clamping screws to the specified torque. SIMOTICS FD 1MH1 Operating Instructions 02/2019 93 Electrical connection 6.5 Inserting and routing the cables 6.5.2 Bringing cables into the terminal box 1XB... with cable gland The connection cables are inserted into the terminal box via an exchangeable cable entry plate or cable entry support. The cable entry plate is drilled by default. The cable glands are not included in the standard scope of supply. You can rotate the cable entry through 180. Table 6-3 Terminal box Cable entry plate versions Standard Cable entry plate with boreholes 1XB1621 2 x M80 x 2 + 2 x M25 x 1.5 1XB1631 4 x M80 x 2 + 2 x M25 x 1.5 1XB7730 1 x M72 x 2 + 3 x M25 x 1.5 1XB7731 2 x M72 x 2 + 3 x M25 x 1.5 1XB7740 4 x M80 x 2 + 3 x M25 x 1.5 1XB7750 8 x M72 x 2 + 3 x M25 x 1.5 Explosion protected version / op tion L01 Undrilled (Page 91) Insert the cable into the terminal box Proceed as follows when introducing cables into the terminal box: 1. Unscrew the cable entry plate. 2. Drill the required number of holes or threads in the required size in the cable entry plate. Ensure that the cable entry plate can be assembled after drilling and that it features sufficient stiffness. 3. Fit the required cable glands. 4. Route the cables through the cable glands. 5. Fit the cable entry plate to the terminal box with the assembled cables. 6. Connect the ends of the cables to the terminals in accordance with the circuit diagram. The circuit diagram is located in the cover of the terminal box. Refer to Chapter "Connecting cables ..." for more information. 6.5.3 Certified cable entries, thread adapters and sealing plugs Use only sealing plugs, cable entries & conductor entries and thread adapters that are certified and marked for use in the respective hazardous zone. 94 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.5 Inserting and routing the cables 6.5.4 Laying cables Lay the cables in accordance with IEC/EN 60364-5-52. For fixed cables, use EMC- and Ex-certified cable glands with strain relief. Screw the cable glands into the threaded holes in the entry plate, which can be unscrewed. The cable glands are not included in the scope of supply. Comply with the installation and operation conditions specified in the certificate for these cable glands and check that they have been fully complied with. For loose cables, use twist-protection cable glands with strain relief. Use shielded cables whose shields are conductively connected to a large area of the terminal box of the motor via EMC cable glands. Arrange the exposed connecting cables in the terminal box so that the PE conductor has excess length and the insulation of the cable strands cannot be damaged. In the case of aluminum connecting bars, insert a steel washer between the cable lug and the connecting bar. This prevents contact corrosion. Correctly close and seal threads or holes that are not being used ensuring that the IP degree of protection is maintained. The IP degree of protection is specified on the rating plate. Replace the cable glands that are not being used by appropriately certified screw plugs. 6.5.5 Connecting cables with cable lugs 1. Select the cable lugs according to the required cable cross-section and fixing screw or stud size. Information about the maximum cross-section for the respective standard terminal box design can be found in the catalog. A sloped/angular arrangement of the supply cables is only permitted provided the required minimum air clearances are met. 2. Remove the insulation from the conductor ends so that the remaining insulation reaches almost up to the cable lug . Connect only one conductor per cable lug. 3. Fasten the cable lug to the end of the conductor correctly, e.g. by squeezing. Figure 6-9 Connection with cable lug and fixing screw (schematic diagram) 4. Insulate the cable lug sleeves where necessary to ensure minimum air clearances and the creepage distance are maintained. SIMOTICS FD 1MH1 Operating Instructions 02/2019 95 Electrical connection 6.5 Inserting and routing the cables 5. Place the cable lug on the terminal support. If you are using a disconnecting link, check its positioning. For terminal boxes 1XB7740 and 1XB7750, place the cable lug on the busbar. 6. Tighten the fixing element with the corresponding tightening torque: Fixing element Tightening torque Fastening screw M12 20 Nm Fixing screws M16 40 Nm Fixing nuts M12 20 Nm Note You can find more information in Chapter 2 of catalog D81.8. WARNING Explosion hazard if cable lugs without side guards are used For cable cross-sections under 70 mm2, cable lugs without side guard may twist. The minimum air clearances may be underrun and cause an explosion. This can result in death, serious injury, or material damage. For cable cross-sections under 70 mm2, use only cable lugs with side guard. Make sure that the minimum air clearances (Page 100) are observed. 6.5.6 Connecting cables without cable lugs Lug terminal connections - which are suitable for connecting flexible and stranded conductors without the use of wire end ferrules - may be installed if ordered accordingly. If you wish to use conductor end sleeves, then correctly crimp these onto the end of the conductor before connecting up. NOTICE Overheating of the conductor ends If the end of the conductor is not correctly enclosed by the wire end ferrule, but is trapped by it, this can lead to overheating. Insert only one conductor end into each wire end ferrule, and attach the wire end ferrule correctly. Insert only one conductor end into each terminal. 96 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.5 Inserting and routing the cables Procedure When connecting, carefully maintain the minimum clearances and creepage distances. 1. Open the terminal box and cut the cable to the correct length. The clips of the 1XB7730/1XB7731 terminal boxes can accept cables with maximum 185 mm cross-section. 2. Prepare the end of the cable depending on the cable and its use. It is not permissible that the cable connection is subject to external forces. 3. Insulate the conductor ends in such a way that the remaining insulation reaches almost up to the cable lug. 4. Make sure the terminal clamps , are arranged correctly for the size of the conductor. Insert the cable into the terminal clamps. Tighten the clamping nuts to the tightening torque as specified in the following table. Terminal box Tightening torque GT640 / 1XB1621 / 1XB1631 / 1XB1634 8 Nm 1XB7730 / 1XB7731 4 Nm 1XB7740 / 1XB7750 8 Nm Figure 6-10 Connection using terminal clamps (schematic diagram) 5. If you have loosened the terminal body clamping bolts , then retighten them with the following torque: Terminal box Tightening torque 1XB1621 / 1XB1631 / 1XB1634 40 Nm GT640 / 1XB7730 / 1XB7731 / 1XB7740 / 1XB7750 20 Nm For terminal boxes GT640, 1XB7730 and 1XB7731, fasten the terminal element using a clamping nut M12 on the threaded stud of the terminal support with a torque of 20 Nm. Lug terminal connections may be installed if ordered accordingly, which are suitable for connecting flexible and stranded conductors without the use of wire end ferrules. If you wish to SIMOTICS FD 1MH1 Operating Instructions 02/2019 97 Electrical connection 6.5 Inserting and routing the cables use wire end ferrules, then before connecting the cable, attach these so as to form an appropriate, current-carrying crimped joint at the end of the conductor. WARNING Danger of explosion if the conductor ends become too hot If the end of the conductor is not correctly enclosed by the wire end ferrule, but is trapped by it, this can lead to overheating. The temperature class of the machine can be exceeded. This can trigger ignition of an explosive mixture. This can result in death, serious injury or material damage. Insert only one conductor end into each wire end ferrule. Attach the wire end ferrule correctly. Insert only one conductor end into each terminal. 6.5.7 Use of aluminum conductors If you are using aluminum conductors, then comply with the following: Use only cable lugs that are suitable for connecting aluminum conductors. Immediately before inserting the aluminum conductor, remove the oxide layer from the contact areas on the conductor and/or the mating piece. Do this using a brush or file. Then grease the contact areas immediately using neutral Vaseline. This prevents a new oxide layer from forming. NOTICE Aluminum flow due to contact pressure Aluminum flows following installation due to the contact pressure. The connection using clamping nuts can loosen as a result. The contact resistance increases, obstructing the current from being conducted. This can result in fire and material damage to the machine - or even in total failure, as well as material damage to the plant or system due to machine failure. Retighten the clamping nuts after approximately 24 hours and then again after approximately four weeks. Make sure that the terminals are de-energized before you tighten the nuts. For 1XB7.. terminal boxes with aluminum connection bars, you can also connect copper cables using copper cable lugs. 98 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.5 Inserting and routing the cables 6.5.8 Using single-stranded cables WARNING High temperatures from induced eddy currents With high currents and where several single-stranded cables are used instead of multiplestranded cables, high temperatures can result in the cable entry area due to induced eddy currents. A short-circuit and an explosion may occur. This can result in death, serious injury, or material damage. After commissioning, ensure that the temperature limits of the connected power cables are not exceeded during operation. This temperature effect can be reduced by altering the conditions at the entry points or by using modified cable entry plates after consultation with the manufacturing plant. Use a cable entry plate made of non-ferrous metal. 6.5.9 Internal equipotential bonding Between the ground terminal in the terminal box enclosure and the machine enclosure, the fixing screws of the terminal box serve as PE conductor connection. Between terminal box cover and terminal box enclosure, the cover fixing screws serve as equipotential bonding. A special external ground conductor is only installed if, for example, flat seals are mounted without additional support. When performing any installation work, you must always take care to ensure that all equipotential bonding measures remain effective. 6.5.10 Stepless mating face for the seal in the terminal box cover The sealing face of the terminal box cover is formed by the terminal box enclosure and the cable entry element. Therefore make sure these parts are correctly aligned, so as to ensure the seal and hence the degree of protection. Align the cable entry support and the cable entry plate to the terminal box enclosure so that the sealing surface between the terminal box and the terminal box cover form a flat face. There must be no steps in the sealing area. SIMOTICS FD 1MH1 Operating Instructions 02/2019 99 Electrical connection 6.5 Inserting and routing the cables 6.5.11 Minimum air clearances After proper installation, verify that the minimum air clearances between non-insulated parts are maintained. Be aware of any protruding wire ends. Table 6-4 Minimum air clearance dependent on rms value of the alternating voltage Urms Rms value of the alternating voltage Vrms Minimum air clearance 500 V 8 mm 630 V 10 mm 800 V 12 mm 1000 V 14 mm 1250 V 18 mm Values apply at an installation altitude of up to 2000 m. When determining the required minimum air clearance, the voltage value in the table may be increased by a factor of 1.1, so that the rated input voltage range is taken into account during general use. 6.5.12 Finishing connection work 1. Before closing the terminal box, please check that: - The electrical connections in the terminal box have been made in accordance with the specifications above and tightened with the correct tightening torque. - The machine is connected in such a way that it rotates in the direction specified. - The inside of the terminal box is clean and free of any cable debris, dirt and foreign bodies. - All of the seals and sealing surfaces of the terminal box are intact and in a good condition. - Any unused cable entries are sealed with glued-in ferrous or certified sealing elements. The sealing elements can only be removed with a tool. - The connecting cables are laid in an open arrangement, so that the cable insulation cannot be damaged during operation. 2. Close the terminal box with the cover fixing screws, see chapter Tightening torques for screw and bolt connections (Page 179). See also Mounting/removing the terminal box (Page 87) 100 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.6 Connecting the auxiliary circuits 6.6 Connecting the auxiliary circuits 6.6.1 Selecting cables Take the following criteria into account when selecting the connecting cables for the auxiliary circuits: Rated current Rated voltage System-dependent conditions, such as ambient temperature, routing type, cable crosssection as defined by required length of cable, etc. Requirements according to IEC/EN 602041 Requirements according to IEC/EN 6007914 Use only sealing plugs, cable entries & conductor entries and thread adapters that are certified and marked for use in the respective hazardous zone. 6.6.2 Bringing cables into the auxiliary terminal box and routing them The required data for connecting the auxiliary circuits is located on the terminal diagram on the inside of the respective auxiliary terminal or terminal box cover. In some cases a terminal strip is installed in the main terminal box for the auxiliary circuit connections. The required stripped length on conductors for auxiliary terminals differs according to terminal type (6 to 9 mm). When the length is correct, the conductor should reach the stop in the terminal and at the same time the conductor insulation should reach the contact part of the terminal. Adapting the cable glands A plate is bolted to the terminal box enclosure via a rectangular cutout through which the connecting cables enter. The plate is generally delivered with threaded holes and cable glands. 1. Open the auxiliary terminal box and undo the cable entry plate screws. Depending on the terminal box version, the cable entry plate is below a steel screening plate. 2. For the undrilled version, drill the required number of holes or threads in the required size of the cable gland into the cable entry plate. 3. Mark the cables if necessary for subsequent assignment. 4. Pull the cables through the cable glands and the cable entry plate, and connect the cables. 5. Fit the cable entry plate. 6. Make sure that the seal on the screwed sockets for the cable glands satisfies the degree of protection. SIMOTICS FD 1MH1 Operating Instructions 02/2019 101 Electrical connection 6.6 Connecting the auxiliary circuits 6.6.3 Intrinsically safe circuits for sensors or probes Observe Standard IEC / EN 6007914 when selecting and routing connecting cables. NOTICE Intrinsically safe circuits for sensors or probes If blue connection terminals are installed for sensors, you must connect them to certified intrinsically safe circuits. This can otherwise result in damage. Ensure that you also observe the additional requirements laid down in IEC / EN 60079-14 for intrinsically safe equipment and the associated connecting cables. NOTICE Connecting the temperature sensors Temperature sensors may be connected only to intrinsically safe circuits with certified evaluation devices. The maximum permissible input currents and powers according to the EU type-examination certificate may not be exceeded. This can otherwise result in damage. If shielded, intrinsically safe temperature sensors are fitted or mounted, they must be connected using the blue connecting terminals. The cable shield is grounded just once; multiple grounding is not permitted. 6.6.4 Connect metal shield in the terminal box If you are using metal-armored cables that are inserted into the terminal or auxiliary terminal boxes with non-intrinsically safe circuits, then ground the metal shield in the terminal box. Additional grounding points are permissible. In terminal boxes with internal grounding part, connect the metal shield to the internal grounding point. In terminal boxes without internal grounding part, connect the metal shield to one of the green-yellow grounding terminals. 6.6.5 Connecting temperature monitoring for the stator winding The stator winding is monitored for thermal loading by temperature sensors embedded in the stator winding. 102 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Electrical connection 6.6 Connecting the auxiliary circuits The connecting cables of the temperature sensors are routed to the main or auxiliary terminal box, depending on the version. The connection and assignment of the terminals is specified in the circuit diagram. WARNING Hazard due to electric shock The installation of the temperature sensors for the winding monitoring with respect to the winding is implemented according to the requirements for basic insulation. The temperature sensor connections are located in terminal boxes, safe to touch, and have no protective separation. This is the reason that in the case of a fault, a hazardous voltage can be present at the measuring sensor cable. When touched, this can result in death, severe bodily injury and material damage. When connecting the temperature sensor to external temperature monitoring devices, when required, apply additional measures to fully comply with the requirements set out in IEC 60664-1 or IEC 61800-5-1 "Hazard due to electric shock". 6.6.6 Terminating the connection work (auxiliary circuit) 1. Before closing the auxiliary terminal box, please check that: - The cables are connected in accordance with the terminal diagram. - The cables are freely arranged so that they cannot come into contact with the machine, and the cable insulation cannot be damaged. - The inside of the terminal box is clean and free of any cable debris, dirt and foreign bodies. - The cable glands are firmly tightened, are suitable with respect to the degree of protection, type of cable routing, permissible cable diameter, etc., and have been mounted in full compliance with specifications and regulations - The threads in the connection plate are sealed using cable and conductor entries, thread adapters or sealing plugs that achieve the respective degree of protection. - Unused cable entries are sealed. The sealing elements are firmly screwed in, and can only be released using a tool. - All of the seals/gaskets and sealing surfaces of the terminal box are in good condition - The screws of all of the screw clamps are fully tightened, even if they are not being used. 2. Close the auxiliary terminal box using the cover supplied for this purpose. See section "Tightening torques for screw and bolt connections (Page 179)" for the tightening torque of the fixing bolts for the cover. SIMOTICS FD 1MH1 Operating Instructions 02/2019 103 Electrical connection 6.6 Connecting the auxiliary circuits 104 SIMOTICS FD 1MH1 Operating Instructions 02/2019 7 Start-up Observe the following when carrying out any work on the machine: Comply with the general safety instructions Comply with the applicable national and sector-specific regulations at the place of installation When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. See also Safety information (Page 15) 7.1 Checks to be carried out prior to commissioning Once the system has been correctly installed, you should check the following prior to commissioning: Note Checks to be carried out prior to commissioning The following list of checks to be performed prior to commissioning does not claim to be complete. It may be necessary to perform further checks and tests in accordance with the specific situation on-site. The machine is undamaged. The machine has been correctly installed and aligned, the transmission elements are correctly balanced and adjusted. All fixing screws, connection elements, and electrical connections have been tightened to the specified tightening torques. The operating conditions match the data provided in accordance with the technical documentation, such as degree of protection, ambient temperature, etc.. Moving parts such as the coupling move freely. All touch protection measures for moving and live parts have been taken. For test operation or when commissioning without output element, carefully secure the feather key using a suitable security element. When doing this, take into account the balancing type of the motor. SIMOTICS FD 1MH1 Operating Instructions 02/2019 105 Start-up 7.1 Checks to be carried out prior to commissioning Second shaft extension If the second shaft extension is not used: Carefully secure the feather key to prevent it from being thrown out, and for balancing type "H" (standard type), ensure its weight is reduced to approximately 60 % of the original value. Using covers, carefully secure the unused shaft extension so that it cannot be touched. Cooling Check that the machine cooling is available for commissioning. Cooling water supply The cooling water supply is connected and ready for operation. The cooling water supply is switched on. The data can be found on the rating plate. Cooling water is available in the configured quality and quantity. The water cooling is switched on. The data can be found on the rating plate. Cooling water of the configured quality is used. The bearing insulation should be implemented as shown on the plates. Electrical connection The grounding and equipotential bonding connections have been made correctly. The machine is connected so that it rotates in the direction specified. Appropriately configured control and speed monitoring functions ensure that the motor cannot exceed the permissible speeds specified in the technical data. For this purpose, compare the data on the rating plate or, if necessary, the system-specific documentation. The minimum insulation resistance values are within tolerance. Minimum air clearances have been maintained. Any supplementary motor monitoring devices and equipment have been correctly connected and are functioning correctly. All brakes and backstops are operating correctly. At the monitoring devices, the values for "Warning" and "Shutdown" are set. 106 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Start-up 7.2 Converter operation 7.2 Converter operation The following chapter is relevant only if the machine has been ordered for converter operation. Note The order number shows whether the machine was ordered for converter operation. In this case, digits 1, 2, 3 or 4 is located at the 6th position of the order number. Converter operation If the design of the motor requires connection to a particular converter type, the rating plate will contain corresponding additional information. The converter is correctly parameterized. The parameterization data is specified on the rating plate of the machine. Information about the parameters is available in the operating instructions for the converter. Any supplementary motor monitoring devices and equipment have been correctly connected and are functioning correctly. In continuous operation, the motor cannot exceed the specified upper speed limit nmax or undershoot the lower speed limit nmin. The permissible acceleration time to the limit speed nmin depends on the parameter assignment. WARNING Dangerous voltage via the converter As long as the feeding converter is switched on, or the DC link of the converter is not discharged, there can be a voltage at the motor terminals even when the rotor is not moving. The voltage is up to 1000 V, depending on the converter type. Ensure that the five safety rules (Page 15) are followed before working on the motor. 7.3 Measuring the insulation resistance before commissioning Measuring the insulation resistance and polarization index (PI) provides information on the condition of the machine. It is therefore important to check the insulation resistance and the polarization index at the following times: Before starting up a machine for the first time After an extended period in storage or downtime Within the scope of maintenance work The following information is provided regarding the state of the winding insulation: Is the winding head insulation conductively contaminated? Has the winding insulation absorbed moisture? SIMOTICS FD 1MH1 Operating Instructions 02/2019 107 Start-up 7.4 Greasing the roller bearings prior to commissioning As such, you can determine whether the machine needs commissioning or any necessary measures such as cleaning and/or drying the winding: Can the machine be put into operation? Must the windings be cleaned or dried? Detailed information on testing and the limit values can be found here: "Testing the insulation resistance and polarization index" (Page 61) 7.4 Greasing the roller bearings prior to commissioning The following information assumes that the specified storage conditions have been complied with. General specifications Pay attention to the instructions on the lubricant plate. Regrease in portions. The shaft must rotate so that the new grease can be distributed in the bearings. Regreasing the roller bearings prior to commissioning If the period between delivery and commissioning is more than a year and less than four years: - Re-grease the roller bearings with twice the amount of grease specified on the lubricant plate. - Check the bearing temperature, as far as possible. Regreasing roller bearings before commissioning You must regrease the roller bearings under the following conditions: If the machine has been in storage for more than four years. If the machine has not been stored in accordance with the specifications in the "Storage" section. Procedure 1. Remove the bearing, regreasing pipes, grease nipples and the bearing cap. 2. Flush out the old grease. 3. Check the bearings before regreasing. If necessary, install new bearings. 4. Lubricate the bearings and reinstall the bearing components. 108 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Start-up 7.5 Setting the automatic regreasing system See also Regreasing intervals and types of grease for operating roller bearings (Page 138) Stoppages (Page 122) Transport (Page 44) 7.5 Setting the automatic regreasing system The relubrication is performed depending on the external voltage present at the regreasing system. Prior to commissioning, set the time interval and the relubrication quantity at the automatic regreasing system. Observe the operating instructions for the regreasing system for its operation and the replacement of the grease cartridges. See also Interlock circuit for the automatic regreasing system (option) (Page 41) 7.6 Setpoint values for monitoring the bearing temperature Prior to commissioning If the machine is equipped with bearing thermometers, set the temperature value for disconnection on the monitoring equipment before the first machine run. Table 7-1 Set values for monitoring the bearing temperatures before commissioning Set value Temperature Alarm 115 C Shutting down 120 C Normal operation Determine the maximum operating temperature of the bearings Toperation taking into account the temperature, bearing load and influences of the plant on the motor in C. Set the values for shutdown and warning corresponding to the operating temperature Top. Table 7-2 Set values for monitoring the bearing temperatures Set value Temperature Alarm Toperation + 5 K 115 C Shutting down Toperation + 10 K 120 C SIMOTICS FD 1MH1 Operating Instructions 02/2019 109 Start-up 7.7 Set values for monitoring the winding temperature 7.7 Set values for monitoring the winding temperature Prior to commissioning Before running the machine for the first time, set the temperature value for shutdown on the monitoring device. Table 7-3 Set value for commissioning Set value Temperature Alarm 145 C Shutting down 155 C Normal operation 1. Measure the normal operating temperature Top at the installation location in C. 2. Set the values for shutdown and warning corresponding to the operating temperature Top. Table 7-4 Set values during normal operation Set value 7.8 Temperature for insulation class 180(H), utilization 155(F) Alarm Top + 10 K 145 C Shutting down Top + 15 K 155 C Test run After installation or inspection, carry out a test run: 1. Start up the machine without a load. To do this, close the circuit breaker and do not switch off prematurely. Check whether it is running smoothly. Switching the machine off again while it is starting up and still running at slow speed should be kept to a bare minimum, for example for checking the direction of rotation or for checking in general. Allow the machine to run down before switching it on again. 2. If the machine is running smoothly and evenly, switch on the cooling equipment. Continue to observe the machine for a while in no-load operation. 110 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Start-up 7.8 Test run 3. If it runs perfectly, connect a load. NOTICE Thermal overload of motors connected directly to the line supply In addition to the load torque, the ramp-up (accelerating) time is essentially influenced by the moment of inertia to be accelerated. While ramping up when connected to the line supply, the inrush (starting) current is a multiple of the rated current. This can result in thermal overload. This can damage the motor. As a consequence, when ramping up, observe the following: Monitor the ramp-up time and number of consecutive starts. Comply with the limit values and/or ramp-up conditions specified in the catalog or the order documentation. 4. During the test run, check and document the following: - Check whether it is running smoothly. - Document the voltage, current and power values. As far as possible, document the corresponding values of the driven machine. - If this is possible using the available measuring equipment, check the bearing and stator winding temperatures until they have reached steady-state values. - Check the machine for noise or vibrations on the bearings or bearing shields as it runs. 5. In case of uneven running or abnormal noise, switch off the machine. As the machine runs down, identify the cause. - If the mechanical operation improves immediately after the machine is switched off, then the cause is magnetic or electrical. - If the mechanical running does not improve immediately after switching the machine off, then the cause is mechanical. - Imbalance of the electrical machine or the driven machine - The machine set has not been adequately aligned - The machine is being operated at the system resonance point. System = motor, base frame, foundation, ... NOTICE Serious damage to the machine If the vibration values in operation are not maintained in accordance with DIN ISO 10816-3, then the machine can be mechanically destroyed. During operation, observe the vibration values in accordance with DIN ISO 108163. Note You can find more information in Chapter 2 of catalog D81.8. SIMOTICS FD 1MH1 Operating Instructions 02/2019 111 Start-up 7.9 Switching off If you want to start the machine for a trial run, ensure that it is connected to the cooling water supply. WARNING Risk of burns from hot steam If the cooling water supply fails, the motor will overheat. If cooling water enters the hot cooling water tubes, hot steam will suddenly be generated, which then escapes under high pressure. The cooling water system can burst. This can result in death, serious injury or material damage. Do not connect the cooling water supply until the machine has cooled down. 7.9 Switching off If the controller does not do this automatically, switch on any anti-condensation heating during stoppages. This will avoid the formation of condensation. Do not switch on the anti-condensation heating for at least two hours after the motor has been switched off. This prevents damage to the winding insulation. 7.10 Setting the motor parameters at the converter The selection of the motor type is used to pre-assign specific motor parameters and to optimize the operating characteristics and behavior. If the incorrect motor type has been selected, then this can result in undesirable operating states, for instance increased noise. If you use the SINAMICS G120/G150 or SINAMICS S120/S150 converter, you can set the motor parameters using STARTER or the "Advanced Operating Panel" AOP30. If you use the SINAMICS G120P converter, you can set the motor parameters using the "Intelligent Operator Panel" (IOP). Note Preset space-vector modulation for SINAMICS S converters Unlike SINAMICS G converters, space-vector modulation is preset for SINAMICS S converters. Provided permitted by the application, the space-vector modulation can be changed manually to an optimized pulse pattern for SIMOTICS FD motors. The SINAMICS parameter is p1802 = 19 in the STARTER and in the AOP30. 112 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Start-up 7.10 Setting the motor parameters at the converter 7.10.1 Selecting the motor type and motor data in the STARTER program Prerequisites The motor is connected to the converter and is ready for operation. The converter must have at least software version 4.6. You have installed the STARTER software with at least version 4.3.1 with SSP, and you are connected to the converter. You require SSP V4.6 for the SINAMICS G120P inverter. The STARTER program has been started. You are in the "Configuration" dialog screen form. Selecting motor parameters 1. Enter a name for the motor in the "Motor name" input field. Subsequent motor assignment is simplified by selecting a unique name. 2. Select the "Enter motor data" option. 3. In the "Motor type" field, select the entry "[14] SIMOTICS FD induction motor series". Figure 7-1 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Selecting a motor type 113 Start-up 7.10 Setting the motor parameters at the converter 4. Click "Continue" to confirm your entries. 5. Enter the appropriate motor data in the "Motor data" table in the "Value" column. - You can find the values for parameters p304...p311 on the motor rating plate. - The value for parameter p335 (motor cooling method) is encrypted from the motor order number: Motor order number Cooling method 1LL1 IC01 0 1LP1 IC06 1 1LM1/1MM1 IC411 4 1LQ1/1MQ1 IC416 5 1LH1/1MH1 IC71W 6 1LN1/1MN1 IC86W 6 Figure 7-2 Parameter p335 Entering the motor data 6. Click "Continue" to confirm your entries. 114 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Start-up 7.10 Setting the motor parameters at the converter 7.10.2 Commissioning at the SINAMICS S/G converter using the AOP30 In the AOP30, navigate as follows: Navigate within the selection fields using and . In the entry fields, you can either directly enter the required value or select it from a list. Activate the selection with . SIMOTICS FD 1MH1 Operating Instructions 02/2019 115 Start-up 7.10 Setting the motor parameters at the converter Selecting the motor type and motor data at the AOP30 1. In the dialog screen form, select the motor standard and motor type. As motor type, select the entry "SIMOTICS FD induction motor series". ^9(&725PRWRUVWDQGDUGPRWRUW\SH &RQWLQXH SPRWRUVWDQGDUG,(&1(0$ ,(&>+]N:@ SP0RWRUW\SHVHOHFWLRQ LQGXFWLRQBPRWRU ,QWHUU&200 +HOS p q ) ) ) &RQWLQXH 2. ) ) 2. Enter the motor parameters. - You can find the values for parameters p304...p311 on the motor rating plate. - The value for parameter p335 (motor cooling method) is encrypted from the motor order number: 116 Motor order number Cooling method Parameter p335 1LL1 IC01 0 1LP1 IC06 1 1LM1/1MM1 IC411 4 1LQ1/1MQ1 IC416 5 1LH1/1MH1 IC71W 6 1LN1/1MN1 IC86W 6 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Start-up 7.10 Setting the motor parameters at the converter ^9(&725PRWRUSDUDPHWHUV %DFN P S8BFRQQHFWLRQ 9 SP0RW8BUDWHG 9UPV SP0RW,BUDWHG $UPV +HOS p q ) ) ) 2. ) ^9(&725PRWRUSDUDPHWHUV SP0RWQXPEHU ) P N: SP0RW3BUDWHG SP0RWFRVSKLBUDWHG ,QWHUU&200 +HOS p q ) ) ) ) ^9(&725PRWRUSDUDPHWHUV SP0RWIBUDWHG SP0RWQBUDWHG &RQWLQXH 2. ) +] P USP SP0RWFRROLQJPHWKRG QDWXUDOFRROLQJ ,QWHUU&200 +HOS p q ) ) ) ) &RQWLQXH 2. ) 3. Exit the motor data input by selecting the "Continue" field and activating the selection with . SIMOTICS FD 1MH1 Operating Instructions 02/2019 117 Start-up 7.10 Setting the motor parameters at the converter 7.10.3 Commissioning at the SINAMICS G120P inverter using the IOP The SINAMICS G120P provides the IOP (Intelligent Operator Panel) located in the enclosure door for operating, monitoring, and commissioning tasks. It can be used to set the motor parameters. 1. Select the "basic commissioning" wizard. Only so can you enter unusual frequencies, such as 50.39 Hz or 100 Hz. :,=$5'6 %DVLFFRPPLVVLRQLQJ 2SHQORRSFRQWUROOHGFRPSUHVVRU &ORVHGORRSFRQWUROOHGFRPSUHVVRU 2SHQORRSFRQWUROOHGIDQ &ORVHGORRSFRQWUROOHGIDQ 2SHQORRSFRQWUROOHGSXPS &ORVHGORRSFRQWUROOHGSXPS 2. Select "speed control" as control type. %DVLFFRPPLVVLRQLQJ &RQWUROW\SH 9IFRQWUROZLWKOLQHDUFKDUDFWHULVWLF 9IFRQWUROZLWKOLQHDUFKDUDFWHULVWLF 9IFRQWUROZLWKSDUDEROLF 9IFRQWUROZLWKOLQHDUFKDUDFWHULVWLF 9IFRQWUROZLWKSDUDEROLF 6SHHGFRQWURO ZLWKRXWHQFRGHU 3. Select "SIMOTICS FD" as motor type. This sets specific motor parameters for optimizing the operating behavior. %DVLFFRPPLVVLRQLQJ 0RWRUW\SH ,QGXFWLRQPRWRU URWDWLQJ /(VWDQGDUGLQGXFWLRQPRWRU /*VWDQGDUGLQGXFWLRQPRWRU 6,027,&6)'LQGXFWLRQPRWRU /$VWDQGDUGLQGXFWLRQPRWRU /$VWDQGDUGLQGXFWLRQPRWRU 4. Enter the performance plate data. - Motor voltage - Motor current - Rated power - Rated power factor cos - Motor speed The optimized pulse patterns are activated automatically once the "SIMOTICS FD" motor type is selected (p300=14). 118 SIMOTICS FD 1MH1 Operating Instructions 02/2019 8 Operation 8.1 Safety instructions for operation Observe the following when carrying out any work on the machine: Comply with the general safety instructions Comply with the applicable national and sector-specific regulations. When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. See also Safety information (Page 15) Risk of injury due to rotating parts Rotating parts are dangerous. Touch protection against rotating parts is no longer guaranteed if covers are removed. Touching rotating parts can result in death, serious injury or material damage. Carefully ensure that all of the covers are closed while operational. First switch off and disconnect the machine if you must remove covers. Comply with the "Five safety rules": Only remove the covers when the rotating parts have come to a complete standstill. Danger as a result of stationary parts under voltage (live parts) Live parts represent a hazard. Touch protection against active (live) parts is no longer guaranteed if covers are removed. The minimum air and creepage distances may be fallen below (violated) when coming close to active parts. Touching or coming close can result in death, serious injury or material damage. Carefully ensure that all of the covers are closed while operational. First switch off and disconnect the machine if you must remove covers. Comply with the "Five safety rules": When the machine is in operation, the terminal boxes must remain closed at all times. Terminal boxes may be opened only when the machine is stopped and in a no-voltage condition. SIMOTICS FD 1MH1 Operating Instructions 02/2019 119 Operation 8.1 Safety instructions for operation Faults in operation Any changes with respect to the normal condition can indicate that the machine is not functioning correctly. Higher power consumption, temperatures or vibration levels. Unusual noise or smells. Monitoring devices respond. These changes can cause faults which can result in eventual or immediate death, serious injury or material damage. Immediately inform the service personnel. If you are in doubt, immediately switch off the machine, carefully observing the systemspecific safety conditions. Damage caused by condensation Humidity in the air can condense for intermittent duty or load fluctuations. Condensate can collect. Moisture can have a negative impact on the winding insulation or result in damage, such as corrosion. Ensure that any condensation can freely flow away. Risk of burn injuries as a result of hot surfaces Individual machine parts can become hot in operation. Burns can result when coming into contact with these parts. Never touch machine parts during operation. Allow the machine to cool down before starting work. Check the temperature of parts before touching them. If required, wear suitable protective equipment. Excessively high machine temperature when heating is switched on If the anti-condensation heating is operated while the machine is running, this can increase the temperatures inside the machine. Material damage can result. Make sure that the anti-condensation heating is switched off before the machine is switched on. Only operate anti-condensation heating when the machine is switched off. Explosion hazard if the bridging is removed from the insulated bearing Removing the factory-fitted bridging of the insulated bearing leads to potential differences between the rotor and the grounded motor. This can cause the generation of sparks, which 120 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Operation 8.2 Operation in hazardous areas of Zone 2 especially in an explosive atmosphere can ignite surrounding dust or combustible gases. Explosions can occur. There is also a risk of an electric shock. Death, serious injury, or material damage will result. Do not open the bridging of the bearing insulation during operation. 8.2 Operation in hazardous areas of Zone 2 Safe handling In addition to the danger notices in the previous section, the following also applies: Electrical systems in hazardous zones must be mounted, installed, and operated in accordance with the applicable rules and regulations. It is assumed that companies operating these plants and systems take the appropriate measures to ensure that these regulations and directives are observed during mounting, installation and operation, and that the appropriate tests are carried out. We recommend that these tests be carried out and documented in coordination with the responsible authorities. System-specific ignition hazards The criteria for the respective zonal classification are not harmonized and the assessment of the operational risks, the local operating conditions and the various monitoring methods are not standard. As a consequence, the remedial measures recommended by the supervisory authorities may also differ depending on the authority's area of responsibility. The machine manufacturer cannot provide general recommendations in this regard. Note Binding clarification of the local risks and of any required measures can only be provided by the company operating the plant or system in agreement with the supervisory authority responsible. The risk assessments from IEC / EN 60079-15 or -7 can be used to assess systemspecific ignition hazards. If you using antifreeze in the cooling water, ensure that the coolant temperature does not fall below -15 C. SIMOTICS FD 1MH1 Operating Instructions 02/2019 121 Operation 8.3 Switching on the machine 8.3 Switching on the machine 1. If at all possible, run the machine without load and check that it is running smoothly. 2. If it runs perfectly, connect a load. NOTICE Thermal overload of motors connected directly to the line supply In addition to the load torque, the ramp-up (accelerating) time is essentially influenced by the moment of inertia to be accelerated. While ramping up when connected to the line supply, the inrush (starting) current is a multiple of the rated current. This can result in thermal overload. This can damage the motor. As a consequence, when ramping up, observe the following: Monitor the ramp-up time and number of consecutive starts. Comply with the limit values and/or ramp-up conditions specified in the catalog or the order documentation. 3. If this is possible using the available measuring equipment, check the bearing and stator winding temperatures. 8.4 Regreasing roller bearings Refer to the regreasing instructions for the roller bearings on the lubricant plate. 8.5 Stoppages The stoppage is a shutdown for a period of time, during which the machine is stopped but remains at the location of use. Under normal ambient conditions, e. g. the stopped machine is not exposed to any vibration, no increased level of corrosion, etc. in general, the following measures are necessary during stoppages. NOTICE Damage due to improper storage Damage may occur to the motor if it is not stored properly. If the machine is to be taken out of operation for more than 12 months, suitable anti-corrosion, preservation, packaging, and drying measures must be taken. See also Transport (Page 44) Start-up (Page 105) 122 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Operation 8.5 Stoppages 8.5.1 Avoidance of frost and corrosion damage in the cooling system For avoidance of frost and corrosion damage, completely drain the water from the cooling system. Then blow air through the cooling system to dry it. If the cooling system cannot be drained because standby capability is required at short notice, protect the cooling circuit against frost and corrosion damage. To do this, add suitable additives to the cooling water. NOTICE Impairment of the heat transport Additives such as anti-freeze and corrosive inhibitor can impair the heat transport. Operate the motor only with the contractually agreed water quality. For avoidance of deposits, the cooling water circuit must then be kept running. So as to be certain of excluding the possibility of formation of condensation within the machine, the anticondensation heating should also remain switched on (if fitted). 8.5.2 Avoidance of condensation or formation of condensation within the machine If the controller does not do this automatically, switch on any anti-condensation heating during stoppages. This will avoid the formation of condensation. Do not switch on the anti-condensation heating for at least two hours after the motor has been switched off. This prevents damage to the winding insulation. WARNING Explosion hazard If the anti-condensation heating is switched on directly after the machine is switched off, the temperature class or the maximum surface temperature of the machine can be exceeded. In an explosive atmosphere, there is a risk of an explosion. This can result in death, serious injury or material damage. Only switch on the anti-condensation heating after the motor has been switched off. Carefully comply with the data on the anti-condensation heating plate. SIMOTICS FD 1MH1 Operating Instructions 02/2019 123 Operation 8.5 Stoppages 8.5.3 Avoidance of damage to roller bearings during stoppages Extended stoppages at the identical or almost identical resting position of the roller bearings can lead to damage such as brinelling or corrosion, for example. During stoppages, regularly start the machine up for a brief period once a month. As a minimum, rotate the rotor several times. If you have uncoupled the machine from the driven machine and secured the rotor with a rotor shipping brace, then remove this before turning the rotor over or starting the machine up. Make sure that the resting position of the roller bearings after the rotor has been turned over is different from what it previously had been. Use the fitted key or the coupling halves as reference markers. During re-commissioning, refer to the information in the "Commissioning" section. See also Start-up (Page 105) 8.5.4 Measurement of the insulation resistance after an extended stoppage Measuring the insulation resistance and polarization index (PI) provides information on the condition of the machine. It is therefore important to check the insulation resistance and the polarization index at the following times: Before starting up a machine for the first time After an extended period in storage or downtime Within the scope of maintenance work The following information is provided regarding the state of the winding insulation: Is the winding head insulation conductively contaminated? Has the winding insulation absorbed moisture? As such, you can determine whether the machine needs commissioning or any necessary measures such as cleaning and/or drying the winding: Can the machine be put into operation? Must the windings be cleaned or dried? Detailed information on testing and the limit values can be found here: "Testing the insulation resistance and polarization index" (Page 61) 124 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Operation 8.6 Decommissioning the machine 8.6 Decommissioning the machine NOTICE Damage as a result of an extended period out of service If the machine is going to be out of service for longer than six months, then take the necessary measures for preservation and storing. Otherwise damage to the machine will result. Record the decommissioning steps. This log will be useful upon recommissioning. 8.7 Switching off the water-cooling system Switch off the water-cooling system after switching off the machine. Condensation can form inside the machine if cooling water flows while the machine is at a standstill. Only switch off the water cooling system once the machine has cooled down. This will prevent the accumulation of residual heat. 8.8 Draining the coolant If you take the machine out of service, drain the coolant if this is necessary for the ambient conditions. Type of construction IM B3 Use the coolant drain hole in the bearing shield to drain the coolant. SIMOTICS FD 1MH1 Operating Instructions 02/2019 125 Operation 8.9 Re-commissioning the machine Coolant connection Coolant connection and coolant drain hole Other types of construction In other types of construction, you must blow the coolant out with compressed air. 8.9 Re-commissioning the machine When you re-commission the machine, proceed as follows: Study the record made when the machine was decommissioned, and reverse the measures that were taken for conservation and storage. Perform the measures listed in the "Commissioning" section. See also Start-up (Page 105) 8.10 Switching on again after an emergency switching-off Check the machine before recommissioning the driven machine after an Emergency Off. Eliminate all the causes that have led to the emergency off 126 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Operation 8.11 faults 8.11 faults 8.11.1 Inspections in the event of faults Natural disasters or unusual operating conditions, such as overloading or short circuit, are faults that overload the machine electrically or mechanically. Immediately perform an inspection after such faults. Correct the cause of the fault as described in the respective remedial measures section. Repair any damage to the machine. SIMOTICS FD 1MH1 Operating Instructions 02/2019 127 Operation 8.11 faults 8.11.2 Electrical faults Note If you are operating the motor with a converter, the operating instructions of the converter must also be observed if electrical faults occur. Table 8-1 Electrical faults Motor fails to start Motor accelerates sluggishly Rumbling noise during startup Rumbling noise during operation High temperature rise during no-load operation High temperature rise with load High temperature rise of individual winding sections X X X X X X X X X Remedial measures Overload Reduce the load. Interrupted phase in the supply cable Check the switches and cables. Interrupted phase in the feeder cable af Check the switches and cables. ter switching on X Mains voltage too low, frequency too high Check the power supply conditions. X X Possible causes of faults Mains voltage too high, frequency too low Check the power supply conditions. X X X X Stator winding incorrectly connected Check the winding connection in the terminal box. X X X X Winding short circuit or phase short cir cuit in stator winding Determine the winding resistances and insulation resistances. Carry out repair work after consulta tion with the manufacturer. Incorrect direction of rotation Check the connection. X 8.11.3 Mechanical faults The following table shows the possible causes of and remedial measures for mechanical faults. Table 8-2 Mechanical faults Grinding noise Overheating Radial vibrations Axial vibrations Possible causes of faults Remedial measures Rotating parts are grinding Establish the cause and realign the parts. X Rotor not balanced Decouple the rotor and then rebalance it. X Rotor out of true, shaft bent Contact the Service Center. X 128 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Operation 8.11 faults Grinding noise Overheating Radial vibrations Axial vibrations Possible causes of faults Remedial measures Poor alignment Align the machine set and check the coupling. 1) Coupled machine not balanced Rebalance the coupled machine. X Shocks from coupled machine Examine the coupled machine. X X Resonance of the overall system comprising mo Reinforce the foundation after prior consultation with the tor and foundation Service Center. X X Changes in foundation Determine the cause of the changes and, if necessary, rectify. Realign the machine. Reduced air supply, direction of rotation of fan possibly incorrect Check the air ducts; clean the machine. Uneven gearbox operation Resolve any gearbox faults. X X X X X 1) X Take into account possible changes which may occur during overheating. SIMOTICS FD 1MH1 Operating Instructions 02/2019 129 Operation 8.11 faults 8.11.4 Water cooling faults The following table shows the possible causes of and remedial measures for faults on watercooled machines. Table 8-3 Cooling system faults Overheating Water leaking Possible causes of faults Remedial measures X Reduced cooling Check the cooling water flow, increase the amount of cooling water if necessary. X Cooling water flow rate too low Consult the manufacturer. If the specified cooling water quality is ob served, the cooling system is maintenance-free. X Inlet temperature too high Set the correct upstream temperature. X Cooling water supply switched off Switch on the cooling water supply. X Cooling water contains too many or unsuit Use cooling water of the agreed quality. able antifreeze and corrosion-protection agents 130 X Leaks in the cooling system Consult the manufacturer. X Defective cooling water connection Find the leak and seal it. SIMOTICS FD 1MH1 Operating Instructions 02/2019 Operation 8.11 faults 8.11.5 Roller bearing faults Damage to roller bearings can be difficult to detect in some cases. If in doubt, replace the bearing. Use other bearing designs only after consulting the manufacturer. Table 8-4 Roller bearing faults Bearing overheats Bearing "whistles" Bearing "knocks" Possible causes of faults Remedial measures X High coupling pressure Align the machine more accurately. X Belt tension too high Reduce the drive belt tension. X Bearing contaminated Clean or replace the bearing. Check the seals. X High ambient temperature Use a suitable high-temperature grease. X X Insufficient lubrication Grease the bearings as instructed. X X Bearing canted Properly install the bearing. X X Insufficient bearing play Contact the Service Center. Excessive bearing play Contact the Service Center. X X X X X Bearing corroded Replace the bearing. Check the seals. Too much grease in bearing Remove surplus grease. Wrong grease in the bearing Use the correct grease. X Friction marks on raceway Replace the bearing. X Brinelling or scoring Replace the bearing. Avoid any vibration at standstill SIMOTICS FD 1MH1 Operating Instructions 02/2019 131 Operation 8.11 faults 132 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9 Through careful and regular maintenance, inspections, and overhauls you can detect faults at an early stage and resolve them. This means that you can avoid consequential damage. Operating conditions and characteristics can vary widely. For this reason, only general maintenance intervals can be specified here. Maintenance intervals should therefore be scheduled to suit the local conditions (dirt, starting frequency, load, etc.). Observe the following when carrying out any work on the machine: Comply with the general safety instructions Comply with the applicable national and sector-specific regulations. When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. See also Safety information (Page 15) Comply with the IEC / EN 6007917 standard during all service and maintenance work on the machine. Note Please contact the service center (Page 177), if you require support with service, maintenance or repair. 9.1 Inspection and maintenance 9.1.1 Safety instructions for inspection and maintenance Danger as a result of stationary parts under voltage (live parts) Live parts represent a hazard. Touch protection against active (live) parts is no longer guaranteed if covers are removed. The minimum air and creepage distances may be fallen SIMOTICS FD 1MH1 Operating Instructions 02/2019 133 Maintenance 9.1 Inspection and maintenance below (violated) when coming close to active parts. Touching or coming close can result in death, serious injury or material damage. Take the machine out of operation. Switch off the machine and ensure that it is in a no-voltage condition. Carefully comply with the "5 safety rules". Only open the terminal box when the motor is stationary and in a no voltage condition. Risk of injury due to rotating parts Rotating parts are dangerous. Touch protection against rotating parts is no longer guaranteed if covers are removed. Touching rotating parts can result in death, serious injury or material damage. Before carrying out any repair work on the machine, take it out of operation, and carefully lock it out so that it cannot be switched on again. Only remove the covers when the rotating parts have come to a complete standstill. Risk of burn injuries due to hot surfaces In operation, the temperature of individual machine parts can increase - and only decrease slowly after switching off. You can burn yourself if you touch hot surfaces. Allow the machine to cool before starting any maintenance and service work on the machine. Check the temperature of parts before touching them. If required, wear suitable protective equipment. Damage if the machine is not maintained The machine can be damaged if it is not appropriately maintained. This can cause faults which can result in eventual or immediate death, serious injury or material damage. Maintain the machine at the specified maintenance intervals. Damage from foreign bodies in the machine Foreign bodies such as dirt, tools or loose components can be left by accident inside the machine after maintenance is performed. These can cause short circuits, reduce the performance of the cooling system or increase noise in operation. They can also damage the motor. Ensure that no foreign bodies are left in or on the motor. Securely attach all loose parts once you have completed the work. Carefully remove any dirt. 134 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.1 Inspection and maintenance WARNING Risk of explosion due to static charging If you clean the machine with compressed air, plastic components may become statically charged and create a potentially explosive atmosphere. An explosion can occur. This can result in death, serious injury or material damage. Do not use compressed air to clean plastic parts in an explosive atmosphere. When cleaning the machine, make sure that the air in the vicinity of the machine is free of gas and dust. 9.1.2 Measuring the insulation resistance during the course of maintenance work Measuring the insulation resistance and polarization index (PI) provides information on the condition of the machine. It is therefore important to check the insulation resistance and the polarization index at the following times: Before starting up a machine for the first time After an extended period in storage or downtime Within the scope of maintenance work The following information is provided regarding the state of the winding insulation: Is the winding head insulation conductively contaminated? Has the winding insulation absorbed moisture? As such, you can determine whether the machine needs commissioning or any necessary measures such as cleaning and/or drying the winding: Can the machine be put into operation? Must the windings be cleaned or dried? Detailed information on testing and the limit values can be found here: "Testing the insulation resistance and polarization index" (Page 61) 9.1.3 Inspections in the event of faults Natural disasters or unusual operating conditions, such as overloading or short circuit, are faults that overload the machine electrically or mechanically. Immediately perform an inspection after such faults. SIMOTICS FD 1MH1 Operating Instructions 02/2019 135 Maintenance 9.1 Inspection and maintenance 9.1.4 First service after installation or repair Perform the following checks after approximately 500 operating hours or at the latest six months after commissioning: Table 9-1 Checks after assembly or repair Check When the motor is running The stated electrical characteristics are being observed. At stand still X The permissible bearing temperatures are not exceeded (Page 109). X The smooth running characteristics and machine running noise have not deteriorated. X The motor foundation has no cracks and indentations. (*) X X (*) You can perform these checks while the motor is running or at a standstill. Additional tests may also be required according to the system-specific conditions. NOTICE Machine damage When carrying out the inspection, if you detect any impermissible deviations from the normal state, you must rectify them immediately. They may otherwise cause damage to the machine. 9.1.5 General inspection Check that the installation conditions are observed. We recommend that the following checks are performed after approx. 16 000 operating hours or at the latest after two years: Table 9-2 Checks that have to be performed during the general inspection Checking 136 When the motor is running The electrical parameters are maintained X The permissible bearing temperatures are not exceeded (Page 109) X The smooth running characteristics and machine running noise have not deteriorated X The motor foundation has no cracks and indentations (*) X At stand still X The machine is aligned within the permissible tolerance ranges X All the fixing bolts/screws for the mechanical and electrical connections have been securely tightened X All the potential connections, grounding connections and shield supports are correctly seated and properly bonded X The winding insulation resistances are sufficiently high X SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.1 Inspection and maintenance Checking When the motor is running At stand still Any bearing insulation is fitted as shown on the plates and labels X The CABLES and insulating parts and components are in good condition and there is no evidence of discoloring X (*) You can perform these checks while the motor is at standstill or, if required, while running. NOTICE Machine damage When carrying out the inspection, if you detect any impermissible deviations from the normal state, you must rectify them immediately. They may otherwise cause damage to the machine. See also Set values for monitoring the winding temperature (Page 110) Checking the cooling system With the machine stopped, check the condition of the cooling system: - The cooling system is in good condition. - The pressure drop between entry and exit has not increased appreciably. 9.1.6 Servicing and maintaining the anti-condensation heating The anti-condensation heating is maintenance-free. If it is defective, contact the Service Center (Page 177). 9.1.7 Assessing the roller bearings To assess the roller bearings, it is generally not necessary to dismantle the machines. The motor only has to be dismantled if the bearings are to be replaced. The state of a roller bearing can be assessed by analyzing the bearing vibration. The measured values provide an indication and can be assessed by specialists. Contact the Service Center. SIMOTICS FD 1MH1 Operating Instructions 02/2019 137 Maintenance 9.1 Inspection and maintenance WARNING Explosion hazard due to overheating of the rolling bearings If the rolling bearings are not regularly regreased, local overheating may be possible, and, as a consequence, an explosion in an explosive atmosphere. This can result in death, serious injury, or material damage. Regrease the rolling bearings regularly according to the lubrication plate. Implement bearing temperature monitoring if not yet in existence. 9.1.8 Roller bearings with automatic regreasing system The roller bearings are supplied with new grease by the regreasing system. Replace the grease cartridge timely. Observe the operating instructions for the regreasing system when replacing the grease cartridges. See also Interlock circuit for the automatic regreasing system (option) (Page 41) Only use the grease that is specified on the lubricant plate. 9.1.9 Regreasing intervals and types of grease for operating roller bearings The specified grease data applies to the data specified on the rating plate and for high-quality grease in accordance with the specifications in these operating instructions. Because these greases exceed significantly the requirements according to DIN 51825 and ISO 67439, they permit the specified relubrication intervals. Initial lubrication The grease specified on the lubricant plate is selected according to the operating conditions known at the time of ordering and should be used for initial lubrication. Criteria for selecting rolling bearing greases High quality ISOLX BDEA3 lubricating grease according to ISO 6743-9 and K3K20 lubricating grease according to DIN 51825 with lithium soap as a thickener and an upper service temperature of at least +130 C / +266 F are permissible for standard applications without special requirements. The technical data of the rolling bearing grease must be suitable for the application. Only use the grease type that is specified on the lubricant plate. 138 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.1 Inspection and maintenance If the operating conditions differ from those mentioned, other lubricating greases may only be used after prior consultation with the manufacturer. If lubricating greases other than those named on the lubricant plate are used, it cannot be guaranteed that they are compatible with the complete system. - If you use lubricating greases that satisfy only the minimum requirements of DIN 51825 or ISO 6743-9, then reduce the lubrication intervals by half or adapt them as appropriate. - If in doubt, consult the manufacturer. The lubrication properties will be impaired if you mix different lubricating greases. This can result in material damage. Only the manufacturer can provide a guarantee for the miscibility of particular lubricating greases. The lubricating grease must satisfy the criteria listed in the table below and must match the operating conditions. If different special lubricating greases are stated on the lubricant plate, then different criteria apply. Table 9-3 Criteria for selecting rolling bearing greases Criteria Standard Property, characteristic value Unit Type of base oil - Mineral oil - Thickener - Lithium - Consistency in accordance with NLGI class DIN 51818 "3" for vertical and horizontal types of construction - "2" alternatively for horizontal type of construction with reduced lubrication interval Operating temperature range - At least -20 C ... +130 C C Dropping point DIN ISO 2176 At least +180 C C Basic oil viscosity DIN 51562-1 Approx. 100 mm/s at 40 C mm/s Approx. 10 mm/s at 100 C Additives - Anti-Oxidation (AO), Anti-Wear (AW) - No solid lubricants Alternatively: Extreme-pressure (EP) only after prior consultation with grease and bearing manufacturers FE9 test: A/1500/6000 DIN 51821-1/-2 F10 50 h at +130 C H F50 100 h at +130 C Behavior in the presence of water DIN 51807 0 or 1 at a test temperature of +90 C - Corrosive effect on copper DIN 51811 0 or 1 at a test temperature of +120 C Korr. Corrosion resistance (EMCOR) DIN 51802 / 0-0 Korr. ISO 11007 Solid matter content, particle sizes > 25 m DIN 51813 <10 mg/kg mg/kg Suitability of bearings - Suitable for the built-in motor bearings, seals and these speeds - Speed parameter nxdm SIMOTICS FD 1MH1 Operating Instructions 02/2019 mm/min 139 Maintenance 9.1 Inspection and maintenance Recommended greases for rolling bearings For standard applications, the following high-quality greases are recommended for rolling bearings for vertical and horizontal motor constructions due to their technical properties: Table 9-4 Rolling bearing greases for vertical and horizontal types of construction Manufacturer Grease type Shell Gadus S2 V100 3 ExxonMobil/Esso Unirex N3 BP Energrease LS3 Fuchs Renolit H443 HD88 Lubcon Turmoplex 3 Addinol LM 3 EP FAG Arcanol Multi 3 For motors of horizontal construction you can alternatively use greases with NLGI class 2. However, this reduces the lubrication interval by 20%. Table 9-5 Alternative greases with NLGI class 2 for motors of horizontal construction Manufacturer Grease type Shell Gadus S2 V100 2 ExxonMobil/Esso Unirex N2 BP Energrease LS2 Castrol Longtime PD2 Lubcon Turmogrease L 802 EP plus Shell Retinax LX2 FAG Arcanol Multi 2 Lubrication data The following data is provided on the lubricant plate of the machine. Regreasing intervals in operating hours Regreasing amount in grams Grease type Grease replacement intervals The grease replacement intervals in these operating instructions or the regreasing intervals indicated on the plate apply to the following conditions: Normal load Operation at speeds in accordance with rating plate Low-vibration operation 140 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.1 Inspection and maintenance Neutral ambient air High-quality rolling bearing greases In the case of unfavorable operating conditions, reduce the relubrication intervals after prior consultation with the manufacturer. Regreasing rolling bearings Regrease the rolling bearings at the latest every 12 months irrespective of the actual number of operating hours. The regreasing intervals for rolling bearings differ from the service intervals for the machine. The rolling bearings may be damaged if the relubrication intervals are not complied with. Pay attention to the instructions on the lubricant plate. 1. Clean the grease nipple. 2. Rotate the shaft when regreasing, so that the new grease can be distributed throughout the bearing. Motors that are operated with converters: Regrease the bearings at a low to medium speed (nmin = 250 rpm, nmax = 3600 rpm) to ensure an even distribution of grease. WARNING Risk of injury due to rotating parts The shaft must rotate to allow the grease to be distributed. This can result in death, serious injury or material damage. When regreasing, pay attention to all rotating components. 3. Gradually press in an appropriate type and amount of grease, as stamped on the lubricant plate and specified in these operating instructions - max. 50 g per 30 min. The rolling bearing temperature rises sharply at first, then drops to the normal value again when the excess grease is displaced out of the bearing. The used grease collects outside each bearing in a spent grease chamber. Greasing the rolling bearings prior to commissioning When properly stored prior to commissioning for a longer period of time, normally the grease in the bearings does not deteriorate within two years. When commissioning, the bearings must be relubricated with twice the amount of lubricating grease. When doing this, the shaft must rotate so that the grease is replaced in the bearings. Carefully observe the information relating to long-term storage. SIMOTICS FD 1MH1 Operating Instructions 02/2019 141 Maintenance 9.1 Inspection and maintenance 9.1.10 Sealing the rolling-contact bearings ("Increased degree of protection" option) Relubricating the grease tank In order to achieve optimum sealing of the rolling contact bearings and to reliably seal the labyrinth joints with grease, the chamber must be relubricated at regular intervals. The procedure is the same as that for lubricating grease. The sealing effect during operation is optimum as long as a small amount of relatively clean grease is forced out. Regreasing intervals The necessary relubrication intervals depend essentially on the level of dirt in the environment and on the ON time of the motor. For this reason, they can only be defined taking into account the respective operating conditions. Make sure that the groove in the seal is full of grease at all times. 9.1.11 Cleaning the cooling water ducts To ensure proper functioning of the machine cooling system, the cooling water ducts must be free of dirt deposits. Have the cooling water ducts cleaned by a specialist company. Cleaning devices are connected to the coolant connections. Dirt is dissolved and rinsed out through the circulation of suitable solutions in the cooling water ducts. You can also remove limescale deposits with a commercially available scale solvent. 9.1.12 Touch up any damaged paintwork If the paint is damaged, it must be repaired in order to protect the unit against corrosion. Note Paint system Contact the Service Center (Page 177) before you repair any paint damage. They will provide you with more information about the correct paint system and methods of repairing paint damage. 142 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.1 Inspection and maintenance 9.1.13 Repainting WARNING Explosion hazard caused by incorrect painting The paint coat can become electrostatically charged where there is a thick coat. Electrostatic discharges can occur. There is a risk of explosion if potentially explosive mixtures are also present at this moment. This can result in death, serious injury or material damage. You must comply with one of the following requirements when you repaint painted surfaces: Limit the total paint film thickness according to the explosion protection group: - IIA, IIB: Total paint coating thickness 2 mm - IIC: Overall coating thickness 0.2 mm for motors of group II (gas) Limit the surface resistance of the paint used: - Surface resistance 1 G for motors of groups II and III (gas and dust) Charge transfer limit - 60 nC for Group I or Group IIA devices - 25 nC for Group IIB devices - 10 nC for Group IIC devices - 200 nC for Group III devices (values not valid for strongly charge generating processes) Breakdown voltage 4 kV for explosion group III (gas and dust) Suitability test of the paint system for hazardous areas Proof is available for the electrostatic suitability with explosion-proof machines for the paint systems ordered by default. Such evidence is not available for paint systems that are nonstandard or specifically requested by customers. Take into consideration that the provided evidence is not valid for repaintings. 9.1.14 Maintaining terminal boxes Requirement The machine is de-energized. SIMOTICS FD 1MH1 Operating Instructions 02/2019 143 Maintenance 9.2 Corrective Maintenance Checking the terminal box Terminal boxes must be regularly checked for tightness, undamaged insulation, and tight terminal connections. If dust or humidity have infiltrated the terminal box, this should be cleaned and dried (particularly the insulators). Check all the seals and sealing surfaces and address the cause of the leakiness. Check the insulators, connectors and cable connections in the terminal box. Replace any damaged components. WARNING Short-circuit hazard Short-circuits can occur as a result of damaged components. This can result in death, serious injury or material damage. Replace damaged components. 9.2 Corrective Maintenance Observe the following when carrying out any work on the machine: Comply with the general safety instructions Comply with the applicable national and sector-specific regulations. When using the machine within the European Union, comply with the specifications laid down in EN 501101 regarding safe operation of electrical equipment. See also Safety information (Page 15) Risk of explosion as a result of inadmissible repair work Repairs are only permissible within the scope of the work described in these operating instructions. Otherwise an explosion can occur in an explosive atmosphere. This can result in death, serious injury or material damage. For repairs to go beyond this scope, please contact the Service Center. See also Service and Support (Page 177) Comply with the IEC / EN 6007917 standard during all service and maintenance work on the machine. If the motor has to be transported, please observe the information and instructions in the "Transport" chapter. 144 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.2 Corrective Maintenance 9.2.1 Prepare servicing work The drawings and parts lists do not contain any detailed information about the type and dimensions of fixing elements and components. For this reason, you should establish this information when dismantling them and make a note of it for the purpose of reassembly. Document the type, dimensions and arrangement of the parts so that you will be able to reassemble the machine to its original state. Use suitable tools to disassemble the machine. Take measures to prevent parts from dropping down before you dismantle them, e.g. by replacing fastening elements with extra-long screws, threaded bolts or similar. This ensures that the part is supported after it is pulled off. The centerings in the shaft extensions have reset threads. Use lifting gear which is suitable for the rotor weight and direction of loading. Danger when a rotor falls Eyebolts in accordance with DIN 580 are unsuitable for suspending the rotor. The rotor can fall off. This can result in death, serious injury or material damage. Use lifting gear which is suitable for the rotor weight and direction of loading. Machine damage caused by improper repair work Improper servicing work can damage the machine. This can cause damages and/or faults which can result in eventual or immediate death, serious injury, or property damage. Properly assemble or disassemble the machine. Use only suitable tools and equipment. Immediately replace damaged components. If necessary, contact the Service Center (Page 177). Danger as a result of rotor falling out If the motor is in a vertical position, the rotor can fall out while work is being performed on the locating bearing. This can result in death, serious injury or damage. Support or unload the rotor when carrying out work with the machine in a vertical position. SIMOTICS FD 1MH1 Operating Instructions 02/2019 145 Maintenance 9.2 Corrective Maintenance Explosion hazard due to improper maintenance of the anti-condensation heating If the anti-condensation heating is not correctly repaired, e.g. if unauthorized or untested spare parts are used, this can result in explosions during operation in a potentially explosive atmosphere. This can result in death, serious injury or material damage. Only appropriately trained specialists in the service center (Page 177) are authorized to repair anti-condensation heating systems. The anti-condensation heating must then be subject to a routine test, which requires extensive specialist knowledge. Only use authorized and tested spare parts. 9.2.2 Screws with preCOTE coating The motor can partly be fitted with screws with preCOTE coating. To ensure screw locking, use new screws with preCOTE coating during assembly/repair. As an alternative, use normal screws with a threadlocker such as Loctite. 9.2.3 Roller-contact bearings 9.2.3.1 Removing roller bearing Preparation Remove any grease feeders, shock pulse measurement equipment and possibly mounted instrumentation at the DE and NDE. Ensure that the DE shaft extension is freely accessible. Remove the coupling. Note For a schematic diagram of the respective component layout, see the chapter "Spare parts (Page 155)". 146 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.2 Corrective Maintenance Procedure 1. Remove the components of the bearing mounting. - Dismount the outer bearing cover. If present: Remove the V ring (Page 147). Uninstall the labyrinth sealing ring (only for the option "Increased degree of protection") (Page 148). - Ensure that the inner bearing cover is no longer attached to the bearing housing or end shield. There may be springs in the inner bearing cover. - Support the rotor for the uninstallation of bearing housing or end shield. - If necessary, remove the bearing housing from the end shield. - Remove the end shield. Dependent on shaft height, roller bearing type and design, it is either a bearing head design or a bearing housing design. - Remove the locking ring from the shaft or the set screw, depending on the version. 2. Pull off the roller bearing together with the grease slinger. 9.2.3.2 Remove V ring Depending on the particular version, there is a V ring. The V ring must be replaced if unusual amounts of grease escape the roller bearing or the V ring is visibly damaged. Figure 9-1 Remove the V ring 1. Mark the components so that they can be correctly assembled. 2. Remove the V ring with the bearing cap - or by using a suitable tool from the shaft. Removing the protective ring for IP56 degree of protection The V ring for the outer bearing seal is fitted with a protective ring for degree of protection IP56. The protective ring does not have to be removed for disassembling the bearing bush. Remove the protective ring together with the V ring and the outer bearing cover or end shield from the shaft. See also Install the V ring (Page 149) SIMOTICS FD 1MH1 Operating Instructions 02/2019 147 Maintenance 9.2 Corrective Maintenance 9.2.3.3 Removing the labyrinth sealing ring Note For the "Increased degree of protection" option, the machine is equipped with a labyrinth sealing ring on the drive side and the non-drive side. Before uninstalling the roller bearing, the labyrinth sealing ring must be removed. The labyrinth sealing ring is fixed with three grub screws that are separably secured with adhesive such as Loctite 243. Figure 9-2 Disassembling the labyrinth sealing ring (schematic diagram) 1. Mark the components of the bearing units so that they can be assembled correctly. 2. Remove the protective coating from the shaft in front of the Iabyrinth sealing ring. 3. Unscrew the three radially arranged set screws for fixing the ring axially. 4. Screw suitable bolts or screws into the radial threads for pulling off. Note the length of engagement to avoid clamping to the shaft or damaging the thread. 5. Warm the labyrinth sealing ring as you pull it off. See also Installing the labyrinth sealing ring (Page 151) 148 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.2 Corrective Maintenance 9.2.3.4 Installing roller bearings Extreme caution and attention to cleanliness are vital to installation. Observe the correct assembly sequence of the components. Attach all components with the specified tightening torques (Page 179). Note For further information about mounting the roller bearing, please refer to the catalog or the information provided by the roller bearing manufacturer. Procedure 1. Replace the damaged components. 2. Remove any dirt from the components. Remove any grease and the remains of sealant or liquid threadlocker. 3. Prepare the bearing seats: - Lightly oil the inner ring seat. - Grease the outer ring seat with a solid lubricant such as Altemp Q NB 50. - Press the inner bearing cover onto the shaft. 4. Warm up the roller bearing. 5. Push the inner ring of the warmed up roller bearing onto the shaft. Avoid any blows that might damage the bearing. 6. Make sure that the roller bearing is resting against the shaft shoulder or the second bearing. 7. Fill the bearing to the top with the specified lubricating grease as stamped on the lubricant plate. 8. Warm up the grease slinger and push it onto the shaft. 9. Depending on the particular version, fix the bearing with a locking ring or shaft nut. 10.Support the rotor when installing the bearing housing or bearing end shield. 11.Use a suitable sealant when assembling. 12.Assemble the bearing shield or bearing housing together with the bearing shield. 13.Install the outer bearing cover if one is being used. 14.Install the sealing elements: If present: V ring (Page 149) Labyrinth sealing ring (special design) (Page 151) 9.2.3.5 Install the V ring Requirement The roller bearing is already fitted. SIMOTICS FD 1MH1 Operating Instructions 02/2019 149 Maintenance 9.2 Corrective Maintenance Install the V ring 1. Grease the axial sealing surface. The shaft seating remains ungreased. V ring Mounting aid washer Protective ring Figure 9-3 Install the V ring 2. Push the V ring onto the shaft using an assembly disk . The V ring is in the correct axial position when the face surface is flush with the outer edge of the V ring. Install the protective ring for IP56 degree of protection For degree of protection IP56, the V ring for the outer bearing seal is fitted with a sheet steel protective ring in the bearing cover. 1. Push the protective ring onto the shaft. 2. Verify that the ring is sufficiently pretensioned. Replace the protective ring, if necessary. 3. Position the protective ring so that one of the longitudinal grooves meets the corresponding water separation groove at the bottom in the bearing cover flange or end shield. 9.2.3.6 Installing the V ring ("Increased degree of protection" option) The grease chamber of the labyrinth sealing ring together with the V ring ensures compliance with degree of protection IP65. 150 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.2 Corrective Maintenance When installing the V ring, proceed in the same way as when installing the labyrinth ring. 1. Grease the axial sealing surface. The shaft seating remains ungreased. 2. Push the V ring onto the shaft. The correct axial position of the V ring for the design with grease chamber has been reached if the V ring sits approx. 0.2 mm behind the edge of the shaft heel. This position is the result of installing the labyrinth sealing ring. Felt ring V ring Figure 9-4 Labyrinth sealing ring Grease chamber Roller-contact bearing with grease chamber (schematic diagram) See also Install the V ring (Page 149) 9.2.3.7 Installing the labyrinth sealing ring The labyrinth sealing ring is the last component to be fitted when fitting the roller-contact bearing. It ensures degree of protection IP65 and prevents the penetration of dirt and foreign bodies into the roller-contact bearing. 1. Apply a soluble adhesive to the three set screws such as Loctite 243) and screw them partially into the labyrinth sealing ring. 2. Apply an corrosion protection paint to the shaft in the area of the labyrinth sealing ring. SIMOTICS FD 1MH1 Operating Instructions 02/2019 151 Maintenance 9.2 Corrective Maintenance 3. Warm up the labyrinth sealing ring. Push the labyrinth sealing ring to approx. 3 mm before the bearing cover before the paint or adhesive cures on the set screws. 3 mm Figure 9-5 Position the set screws for the labyrinth sealing ring on the outer bearing cover 4. Locate the labyrinth sealing ring in position by screwing the set screws in. Check that the tips of the set screws engage with the keyway with a short axial movement. The correct axial position is obtained when the locating setscrews screwed into the keyway engage. 9.2.4 Seal the motor Extreme caution and attention to cleanliness are vital to installation. Clean all bare joints between parts such as housings, bearing shields and bearing bushes etc., and remove old sealant material. Smear bare joints between parts with non-hardening, permanently flexible sealant, such as "Hylomar M". Follow the manufacturer's application and safety instructions when doing this. Check all sealing elements, such as those on the terminal boxes, for elasticity, aging or damage, and renew them if they are no longer effective. Replacing seals 1. Replace the seals if necessary with original parts or with tested sealing elements. 2. Completely bond the seals to the motor and the air intake housing. It is impermissible to have gaps and holes where seals make contact. 3. Surfaces whose mating faces are sealed using liquid sealant can be resealed by applying the original liquid sealant (Hylomar M). 4. Surfaces whose mating faces are sealed using sealings that adhere to one side only can be resealed with the original sealing using the original adhesives (Loctite). 152 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Maintenance 9.2 Corrective Maintenance Attaching the cover If you are installing covers that are sealed with liquid gasket, proceed as follows to maintain the IP degree of protection of the machine before closing it again: 1. Use only approved liquid sealants. 2. Clean the sealing surfaces according to the technical data sheet of the liquid sealant. The sealing surfaces must be clean and dry before reassembly. 3. Apply the liquid gasket as a continuous bead with a diameter of approx. 3 mm. 4. Assemble the components after the solvent has had a chance to vaporize, while still assembling within the specified assembly time. 5. Retighten the fixing screws of the cover after the liquid sealant has set. If you have any questions, contact the Service Center. See also Service and Support (Page 177) SIMOTICS FD 1MH1 Operating Instructions 02/2019 153 Maintenance 9.2 Corrective Maintenance 154 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.1 10 Ordering data When ordering spare parts, in addition to the precise designation of the spare part, specify the motor type and the serial number of the motor. Ensure that the spare part designation matches the designation in the spare part lists and add the associated part number. Example Bearing shield, drive end (Part 5.00) Machine type 1MH1 Serial number D21234567010001 The machine type and the serial number are indicated on the rating plate and in the technical data, and are also embossed on the drive end of the shaft. Note The graphical representations in this chapter show schematic diagrams of the basic versions. They are used for spare parts definitions. The supplied version may differ in details from these representations. Data matrix code A data matrix code is provided on the machine. You can retrieve the following information from the data matrix code: Machine type Serial number Using the Data Matrix code and the "Siemens Industry Online Support" App, you can access product information such as the operating instructions and certificates of your machine. See also Service and Support (Page 177) Quality documents (Page 181) SIMOTICS FD 1MH1 Operating Instructions 02/2019 155 Spare parts 10.2 Ordering spare parts via the Internet WARNING Explosion hazard due to unsuitable spare parts If you use parts other than the original spare parts, the type of protection can no longer be guaranteed. This can result in an explosion during operation in a potentially explosive atmosphere. This can result in death, serious injury, or material damage. Use only original spare parts for explosion-proof machines, including components, such as seals, terminals, cables, and cable entries. If you have any questions, please contact the service center (Page 177). Commercially available equivalent standard parts such as screws and bolts may be used. 10.2 Ordering spare parts via the Internet You can use "Spares on Web" to determine the order numbers for motor spare parts quickly and easily. Spares on Web (https://www.sow.siemens.com/). See also Guide for Spares on Web (http://support.automation.siemens.com/WW/news/en/25248626) Rolling bearings When ordering rolling bearings, in addition to the bearing identification code, the supplementary specifying code is also necessary for the bearing version. Both of these codes are stamped on the lubricant plate and specified in the motor documentation, or can also be taken from the installed bearings. Always replace the rolling bearings with the identical bearings. If insulated rolling bearings are fitted, use insulated rolling bearings of the same type as spare parts. This will prevent any bearing damage being caused by bearing currents. 156 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.3 Anti-condensation heating 10.3 Anti-condensation heating WARNING Explosion hazard due to improper maintenance If repairs to the anti-condensation heating are not carried out correctly, e.g. if unauthorized or untested spare parts are used, this can result in explosions during operation in a potentially explosive gaseous atmosphere. This can result in death, serious injury, or material damage. Repairing and mounting the anti-condensation heating and the subsequent routine testing must always be undertaken by experts from the service center (Page 177), because this work requires extensive specialist knowledge. Only authorized and tested spare parts may be used. SIMOTICS FD 1MH1 Operating Instructions 02/2019 157 Spare parts 10.4 Housing, stators and rotors 10.4 Housing, stators and rotors Figure 10-1 Table 10-1 Housing, stators and rotors Spare parts for housing, stators and rotors Part Description 5.41 Gill plate and cover for air discharge opening 5.49 Enclosure cover 8.00 Rotor, complete 8.20 Stator core with winding 10.00 Stator frame 10.50 Lifting lugs 20.00 Terminal box without cable entry See also Terminal box 1XB1621 (Page 162) Terminal box 1XB1631 (Page 164) Terminal box 1XB7730 (Page 165) Terminal box 1XB7731 (Page 166) 158 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.4 Housing, stators and rotors Terminal box 1XB7740 (Page 167) Terminal box 1XB7750 (Page 168) SIMOTICS FD 1MH1 Operating Instructions 02/2019 159 Spare parts 10.5 Roller bearing cartridge at the drive and non-drive end 10.5 Roller bearing cartridge at the drive and non-drive end Figure 10-2 Bearing cartridge at the drive end and non-drive end Table 10-2 Spare parts for the bearing cartridge at the drive end and non-drive end Part Description Part Description 3.20 Outer bearing cover 4.20 Outer bearing cover 3.35 Grease slinger 4.35 Grease slinger 3.60 Inner bearing cover 4.60 Inner bearing cover 5.00 End shield 6.00 End shield Bearing kit at the drive end and non-drive end consists of the following components 160 Deep-groove ball bearing (locating bearing) Deep-groove ball bearings Shaft sealing ring, labyrinth ring (optional) Shaft sealing ring Locking ring, guard ring Locking ring SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.6 Roller bearing cartridge at the drive and non-drive end 10.6 Roller bearing cartridge at the drive and non-drive end The following description applies to the standard version for IM B3. The bearing type used is stamped on the lubricant plate. Different bearings can be used for different types of construction. As of shaft height 400, fast running motors have bearing cartridges with a reduced diameter in the bearing housing design. Figure 10-3 Bearing cartridge at the drive end and non-drive end Table 10-3 Spare parts for the bearing cartridge at the drive end and non-drive end Part Description Part Description 3.20 Outer bearing cover 4.20 Outer bearing cover 3.35 Grease slinger 4.35 Grease slinger 3.60 Inner bearing cover 4.60 Inner bearing cover 5.00 End shield 6.00 End shield Bearing kit at the drive end and non-drive end consists of the following components Deep-groove ball bearing (locating bearing) Deep-groove ball bearings Shaft sealing ring, labyrinth ring (optional) Shaft sealing ring Locking ring, guard ring Locking ring SIMOTICS FD 1MH1 Operating Instructions 02/2019 161 Spare parts 10.7 Terminal box 1XB1621 10.7 Terminal box 1XB1621 Figure 10-4 Terminal box 1XB1621 with standard cable entry Figure 10-5 Table 10-4 Part Two-part cable entry Terminal box 1XB1621 spare parts Description Part Description 20.00 Terminal box without cable entry comprising the following components: 162 20.20 Terminal box housing 21.41 Terminal supports 20.27 Mounting rail 21.61 Terminal strip for auxiliary circuit 20.28 Seal 22.01 Saddle terminal, complete SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.7 Terminal box 1XB1621 Part Description Part Description 20.30 Cover 22.43 Terminal link, stepped with two holes 20.38 Seal 22.70 Fixing lug for PE conductor 21.11 Connecting plate with internal cable Table 10-5 Additional spare parts Part Description Part Description 20.60 Cable gland 20.66 Strain relief - lower part 20.61 Cable gland - upper part 20.68 Seal 20.62 Cable gland - lower part 20.70 Sealing insert for cable entry 20.65 Strain relief - upper part SIMOTICS FD 1MH1 Operating Instructions 02/2019 163 Spare parts 10.8 Terminal box 1XB1631 10.8 Terminal box 1XB1631 Figure 10-6 1 Terminal box 1XB1631 Part Description Part Description 20.00 Complete terminal box with undrilled cable entry plate1 22.01 Saddle terminal, complete 20.51 Cable entry plate with seal, undrilled 22.41 Terminal link, straight with 2 holes 21.41 Terminal bushings 22.43 Terminal link, stepped with 2 holes You can only order the terminal box as part. ; ; Table 10-6 Additional spare parts for terminal box 1XB1631 with split cable entry Part Description Part Description 20.61 Cable gland - upper part 20.66 Strain relief - lower part 20.62 Cable gland - lower part 20.70 Sealing insert for cable entry 20.65 Strain relief - upper part 164 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.9 Terminal box 1XB7730 10.9 Terminal box 1XB7730 Figure 10-7 Table 10-7 Part Main terminal box 1XB7730 Main terminal box 1XB7730 spare parts Description Part Description 20.00 Terminal box without cable entry comprising the following components 20.20 Terminal box housing 21.61 Terminal strip for auxiliary circuit 20.28 Seal 21.74 Anti-rotation cartridge 20.30 Cover 22.01 Saddle terminal, complete 20.38 Seal 22.39 Neutral point connection 21.11 Connecting plate with internal cable 22.70 Fixing lug for PE conductor 21.41 Terminal bushings Part Description Table 10-8 Additional spare parts Part Description 20.51 Entry plate with seal SIMOTICS FD 1MH1 Operating Instructions 02/2019 165 Spare parts 10.10 Terminal box 1XB7731 10.10 Terminal box 1XB7731 Figure 10-8 Table 10-9 Part Main terminal box 1XB7731 Main terminal box 1XB7731 spare parts Description Part Description 20.00 Terminal box without cable entry comprising the following components 20.20 Terminal box housing 21.61 Terminal strip for auxiliary circuit 20.28 Seal 21.74 Anti-rotation cartridge 20.30 Cover 22.01 Saddle terminal, complete 20.38 Seal 22.39 Neutral point connection 21.11 Connecting plate with internal cable 22.41 Terminal link, straight with two holes 21.41 Terminal bushings 22.70 Fixing lug for PE conductor Part Description Table 10-10 Additional spare parts 166 Part Description 20.51 Entry plate with seal SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.11 Terminal box 1XB7740 10.11 Terminal box 1XB7740 Figure 10-9 Main terminal box 1XB7740 Table 10-11 Main terminal box 1XB7740 spare parts Part Description Part Description 20.00 Terminal box without cable entry comprising the following components 20.20 Terminal box housing 21.61 Terminal strip for auxiliary circuit 20.28 Seal 21.74 Anti-rotation cartridge 20.30 Cover 22.01 Saddle terminal, complete 20.38 Seal 22.30 Connecting bar for the power circuit 21.11 Connecting plate with internal cable 22.39 Neutral point connection 21.41 Terminal bushings 22.70 Fixing lug for PE conductor Part Description Table 10-12 Additional spare parts Part Description 20.51 Cable entry plate with seal SIMOTICS FD 1MH1 Operating Instructions 02/2019 167 Spare parts 10.12 Terminal box 1XB7750 10.12 Terminal box 1XB7750 Figure 10-10 Terminal box 1XB7750 with standard cable entry Table 10-13 Terminal box 1XB7750 1 Part Description Part Description 20.00 Complete terminal box with undrilled cable entry plate1 22.30 Connecting bar for the power circuit 20.51 Cable entry plate with seal, undrilled 22.39 Neutral point connection 22.01 Saddle terminal, complete You can only order the terminal box as part. 168 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.13 Auxiliary terminal box 1XB9014 10.13 Auxiliary terminal box 1XB9014 $$ $ [0[ $ Figure 10-11 Auxiliary terminal box 1XB9014 The auxiliary terminal box can only be ordered as one complete part, single parts are not available. In this case, please contact the Service Center (Page 177). SIMOTICS FD 1MH1 Operating Instructions 02/2019 169 Spare parts 10.14 Auxiliary terminal box 1XB9015 10.14 Auxiliary terminal box 1XB9015 [0[ $ $$ $ Figure 10-12 Auxiliary terminal box 1XB9015 The auxiliary terminal box can only be ordered as one complete part, single parts are not available. In this case, please contact the Service Center (Page 177). 170 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Spare parts 10.15 1XB9016 auxiliary terminal box 10.15 1XB9016 auxiliary terminal box $ $$ [0[ $ Figure 10-13 1XB9016 auxiliary terminal box The auxiliary terminal box can only be ordered as one complete part, single parts are not available. In this case, please contact the Service Center (Page 177). SIMOTICS FD 1MH1 Operating Instructions 02/2019 171 Spare parts 10.16 Auxiliary terminal box 1XB302. 10.16 Auxiliary terminal box 1XB302. $$ 0[ $ [0 [0 0[ $ Figure 10-14 Auxiliary terminal box 1XB302. The auxiliary terminal box can only be ordered as one complete part, single parts are not available. In this case, please contact the Service Center (Page 177). 172 SIMOTICS FD 1MH1 Operating Instructions 02/2019 11 Disposal Protecting the environment and preserving its resources are corporate goals of the highest priority for us. Our worldwide environmental management system to ISO 14001 ensures compliance with legislation and sets high standards in this regard. Environmentally friendly design, technical safety and health protection are always firm goals even at the product development stage. Recommendations for the environmentally friendly disposal of the machine and its components are given in the following section. Be sure to comply with local disposal regulations. Country-specific legislation The machine uses materials that can be recovered or recycled. Correctly separating materials helps to simply recycle important materials. When disposing of the machine or of waste that is created during the individual phases of its life cycle, please observe the statutory requirements applicable in the country of use. Please contact your local authorities for more information about disposal. 11.1 RoHS - restricting the use of certain hazardous substances In compliance with RoHS ("Restriction of certain Hazardous Substances" ) we replace substances that are damaging to the environment by those that are not based on state-of-theart technology. In doing so, safety in operation and handling will take priority at all times. 11.2 Information according to Article 33 of the REACH regulation This product contains one or several subproducts in which the following substance - belonging to the "list of candidates" - exists in a concentration exceeding 0.1 percent by weight. CAS No. 7439-92-1, lead Based on the currently available information, we assume that this substance does not represent any risk when correctly used, including its disposal. SIMOTICS FD 1MH1 Operating Instructions 02/2019 173 Disposal 11.3 Preparing for disassembly 11.3 Preparing for disassembly Disassembly of the machine must be carried out and/or supervised by qualified personnel with appropriate expert knowledge. 1. Contact a certified waste disposal organization in your vicinity. Clarify what is expected in terms of the quality of dismantling the machine and provision of the components. 2. Follow the five safety rules (Page 15). 3. Disconnect all electrical connections and remove all cables. 4. Remove all liquids such as oil and cooling liquids. Collect the liquids separately and dispose of them in a professional manner. 5. Detach the machine fixings. 6. Transport the machine to a suitable location for disassembly. 11.4 Dismantling the machine Dismantle the machine using the general procedures commonly used in mechanical engineering. WARNING Machine parts can fall The machine is made up of heavy parts. These parts are liable to fall during dismantling. This can result in death, serious injury or material damage. Before you release any machine parts, secure them so that they cannot fall. 11.5 Disposal of components Components The machines consist mainly of steel and various proportions of copper and aluminum. Metals are generally considered to be unlimitedly recyclable. Sort the components for recycling according to whether they are: Iron and steel Aluminum Non-ferrous metal, e.g. windings The winding insulation is incinerated during copper recycling. Insulating materials Cables and wires Electronic waste 174 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Disposal 11.5 Disposal of components Process materials and chemicals Sort the process materials and chemicals for recycling according to whether they are for example: Oil Grease Cleaning substances and solvents Paint residues Anti-corrosion agent Coolant additives such as inhibitors, antifreeze or biocides Dispose of the separated components according to local regulations or via a specialist disposal company. The same applies for cloths and cleaning substances which have been used while working on the machine. Packaging material If necessary, contact a suitable specialist disposal company. Wooden packaging for sea transport consists of impregnated wood. Observe the local regulations. The foil used for water-proof packaging is an aluminum composite foil. It can be recycled thermally. Dirty foil must be disposed of via waste incineration. SIMOTICS FD 1MH1 Operating Instructions 02/2019 175 Disposal 11.5 Disposal of components 176 SIMOTICS FD 1MH1 Operating Instructions 02/2019 A Service and Support Technical questions or additional information If you have any technical questions or require additional information, please contact Technical Support (https://support.industry.siemens.com/cs/ww/en/ sc/4868). Please have the following data ready: Type Serial number You can find this data on the rating plate. Contact person If you wish to request on-site service or order spare parts, please contact your local office. This office will contact the responsible service center on your behalf. You can find your contact person in the relevant contact data base: www.siemens.com/yourcontact (www.siemens.com/yourcontact) Siemens Support for on the move With the "Siemens Industry Online Support" App, you can access more than 300,000 documents for Siemens Industry products - any time and any where. The App supports you in the following areas: Resolving problems when executing a project Troubleshooting when faults develop Expanding a system or planning a new system Further, you have access to the Technical Forum and other articles that our experts have drawn-up: FAQs Application examples Manuals Certificates Product announcements and many more The app is available for Apple iOS, Android and Windows Phone. SIMOTICS FD 1MH1 Operating Instructions 02/2019 177 Service and Support 178 SIMOTICS FD 1MH1 Operating Instructions 02/2019 B Technical data and drawings B.1 Tightening torques for screw and bolt connections Bolt locking devices Refit nuts or bolts that are mounted together with locking, resilient, and/or force-distributing elements with identical, fully-functional elements when re-assembling. Always renew keyed elements. When screwing together threads secured with a liquid adhesive, use a suitable medium such as Loctite 243. Always use suitable securing devices or removable adhesives (e.g., Loctite 243) when installing fixing bolts with a clamping length of less than 25 mm. The clamping length is taken as the distance between the head of the bolt and the point at which the bolt is screwed in. Tightening torques The bolted connections with metal contact surfaces, such as end shields, bearing cartridge parts, terminal box parts bolted onto the stator frame, should be tightened to the following torques, depending on the thread size: Table B-1 Tightening torques for bolted connections with a tolerance of 10%. Case M4 M5 M6 M8 M10 M12 M16 M20 M24 M30 M36 M42 M48 M56 A 1.2 2.5 4 8 13 20 40 52 80 150 - - - - Nm B 1.3 2.6 4.5 11 22 38 92 180 310 620 1080 1700 2600 4200 Nm C 3 5 8 20 40 70 170 340 600 1200 2000 3100 4700 7500 Nm SIMOTICS FD 1MH1 Operating Instructions 02/2019 179 Technical data and drawings B.1 Tightening torques for screw and bolt connections Applications The above-mentioned tightening torques apply for the following applications: Case A Applies to electrical connections in which the permissible torque is normally limited by the bolt materials and/or the current carrying capacity of the insulators, with the exception of the busbar connections in case B. Case B Applies to bolts screwed into components made from materials with lower property class (e. g. aluminum) and to bolts with property class 8.8 according to ISO 898-1. Case C Applies to bolts with property class 8.8, A4-70 or A4-80 according to ISO 898-1, however only to bolts screwed into components made from materials with higher property class, e.g. cast iron, steel or cast steel. Note Non-standard tightening torques Different tightening torques for electrical connections and bolted connections for parts with flat seals or insulating parts are specified in the relevant sections and drawings. See also Securing the rotor (Page 47) 180 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Quality documents C You can find the quality documents here: https://support.industry.siemens.com/cs/ww/de/ps/13318/cert (https:// support.industry.siemens.com/cs/ww/en/ps/13318/cert) SIMOTICS FD 1MH1 Operating Instructions 02/2019 181 Quality documents 182 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Index Brought-out cables, 90 " "Siemens Industry Online Support" App, 177 5 5 safety rules, 15 A Aligning, 71, 74, 75 Accuracy, 75 Prerequisites, 64 Aluminum conductors, 98 Anti-condensation heating, 41, 112, 120, 123, 137, 146 Insulation resistance, 63 Repairs, 157 Anti-corrosion agent Removing, 66 Anti-freeze, 39 Anti-freeze protection, 39, 123 Applications, 23 Assembly Labyrinth sealing ring, 151 Outer bearing seal, 151 Roller bearings, 149 Sealing, 152 V ring, 149 Auxiliary terminal box close, 103 Axial force, 75 Axial gap, 73 B Bearing cover, 147 Bearing currents Reduction, 55 Bearing insulation, 56, 106 Bearing seizure damage, 49 Bearing temperature Monitoring, 109 Set values, 109 Biocides, 39 Bolt locking device, 179 SIMOTICS FD 1MH1 Operating Instructions 02/2019 C Cable entries, 95 certified, 94, 101 Cable entry and routing, 93 Cable entry plate, 94 Cable gland, 95 Cable lugs without side guard, 96 Center of gravity, 68 Centering flange, 74, 75 Certificates EAC, 27 UL and cUL, 27 Checks to be carried out prior to commissioning, 105 Common-mode filters, 56 Condensate, 70 Connecting cables Selection, 88, 101 Connecting the auxiliary circuit, 102 Converter, 28 Converter documentation, 56 Cooling capacity derating, 40 Cooling system Faults, 130 Cooling water connecting, 77 Cooling water ducts Cleaning, 142 Cooling water intake temperature, 37 Cooling water quality, 38 Cooling water supply, 106 Correct usage, 26 Corrosion protection, 52, 53, 123, 151 Coupling, 57 Cross-section of grounding conductor, 89 Cross-section of the line conductor, 89 D Damage during transport, 47 Damage during transportation, 46 Damping cores, 56 Data matrix code, 155 De-energizing Anti-condensation heating, 112, 123 183 Index Degree of protection, 29 Derating, 71 Increased, 30 Delivery, 46 Derating, 40 Differential pressure, 34 Direction of rotation, 91 Disassembly Disposal, 174 Machine, 145 Roller bearings, 147 Disposal Chemicals, 175 Components, 174 Distance over surface, 97 Drive, 28 E Electrical faults, 128 Electromagnetic fields, 21 Emergency off, 126 Emitted interference, 21 End shield, 147 Equipotential bonding, 35, 99 Equipotential bonding conductor, 55 ESD guidelines, 18 Explosion hazard, 23, 157 Bridging the insulated bearing, 120 Electrostatic discharge, 19 Spare parts, 156 F Faults Cooling system, 130 Electric, 128 Inspection, 127, 135 Mechanical, 128 Roller bearings, 131 Faults in operation, 120 Flammable substances, 17 Foundation surfaces, 64 Frequency fluctuation, 43 Grease replacement intervals, 140 Grease tank, 142 Grounding conductor Connecting, 89 Grounding system Meshed, 56 H Hazardous substances, 17 Hearing damage, 17, 42 Hot surfaces, 16 I Ignition hazard, 18, 121 Increased degree of protection, 30 Induced eddy currents, 99 Inhibitors, 39 Initial lubrication, 138 Insert cable, 94 Inspection Faults, 127, 135 Installation Initial inspection, 136 Installing the protective ring, 150 Insulated bearings, 29, 56, 121 Insulated coupling, 57 Insulation resistance, 61, 107, 124, 135 Anti-condensation heating, 63 measure, 61 Interference immunity, 20 Interference voltages, 20 Interlocking circuit Anti-condensation heating, 41 Intrinsically safe circuits, 102 L Labyrinth ring, 148 Lifting, 68 Line operation, 28 Live parts, 16 Long-term storage, 51 Lubrication data, 140 G General inspection, 136 Geometry of the flange, 64 GOST standards, 24 Grease chamber, 150 184 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Index M Q Machine Aligning to the driven machine, 72 setting down, 69 Machine design IEC, 23 Machine expansion, 73 Maintenance Maintenance intervals, 133 Materials, 35 Metal shield, 90, 102 Metal-armored cables, 90, 102 Minimum air clearances, 100 More information, 177 Mounting the terminal box, 88 Mounting-foot hole dimensions, 64 Qualified personnel, 15 N Noise emissions, 17, 42 O On-site service, 177 Operating mode, 33 Operation with converter Explosion-protected machine, 53 Output element, 67 Overpressure, 34 Overspeed, 33 P Paint system, 142 Paintwork damage, 142 Polarization index, 61, 63, 107, 124, 135 Positioning, 72 Precision alignment, 73 Preload Rotor bracing, 48 Preparations for assembly, 60 Processes that generate high levels of electrostatic charge, 19 Protective conductor, 57 Protective ring, 147 SIMOTICS FD 1MH1 Operating Instructions 02/2019 R Radial force, 75 Rating plate, 26 REACH regulation, 173 Re-commissioning, 126 Regreasing, 122, 141 Regreasing interval, 142 Regreasing rolling bearings, 141 Regreasing system, 29 Commissioning, 109 Interlocking circuit, 41 Maintenance, 138 Removing the terminal box, 87 Repainting, 143 Repair Initial inspection, 136 Residual risks, 33 Restriction of certain Hazardous Substances, 173 RF grounding point, 55 Risk of explosion, 51, 146 Cleaning with compressed air, 135 RoHS, 173 Roller bearings Assembly, 149 faults, 131 Inspection, 137 Regreasing, 108 Roller-contact bearings, 29 Rolling bearings Replacement, 156 Rotating parts, 16 Rotor, 28 Rotor shipping brace, 45, 47, 51, 65 Remove, 65 Rotor winding, 28 S Safety instructions Flammable substances, 17 Hazardous substances, 17 Hot surfaces, 16 Live parts, 16 Rotating parts, 16 Screws with preCOTE coating, 146 185 Index Seal insert, 93 Sealing, 99 Sealing grease, 30 Sealing insert with break-off ring, 92 Sealing plugs certified, 94, 101 Selecting rolling bearing grease, 139 Setting the motor parameters, 112 Shaft assembly, 44 Shipping, 47 Siemens Industry Online Support App, 177 SIMOTICS Digital Data, 155 Spare parts, 156, 177 1XB9016 auxiliary terminal box, 171 Auxiliary terminal box 1XB302., 172 Auxiliary terminal box 1XB9014, 169 Auxiliary terminal box 1XB9015, 170 Bearing housing design, 161 Bearing shield cartridge, 160 enclosure, 158 Main terminal box 1XB7730, 165 Main terminal box 1XB7731, 166 Main terminal box 1XB7740, 167 Rotor, 158 Stator, 158 Terminal box 1XB1621, 162 Terminal box 1XB1631, 164 Spare parts ordering, 155 Spares on Web, 156 Speed, 42 Speed-torque characteristic, 43 Standard flange, 74, 75 Stator winding Temperature monitoring, 102 Stoppages, 122, 123 Roller bearings, 124 Storage, 50 Storage location, 50 Strain relief, 93 Supplementary devices, 31 Support foot, 42 Switching on, 110, 122 System resonances, 43 Temperature monitoring Stator winding, 102 Terminal box, 30, 80, 90, 102 Closing, 100 Maintaining, 144 rotating, 84 Terminal box 1XB1631, 164 Terminal box 1XB7750, 168 Terminal designation, 88 Terminal diagram, 101 Test run, 110 Thermal motor protection, 41 Threadlocker, 146 Tightening torques, 79 Bolted connection, 179 Cable lug, 90 Ground terminals, 90 Torsional loadings, 44 Transporting, 68 Turning the machine on to its side, 65 Type of balancing, 66 Type of protection, 156 Type of protection Ex ec, 23 V V ring, 147, 150 Vibration values, 43, 111 Voltage fluctuations, 43 Voltage via the converter, 107 W Wall faces, 64 Wall mounting, 64 Water drip loop, 80 Winding temperature Monitoring, 110 Set values, 110 Wire end ferrules, 96, 98 T Tandem operation, 57 Technical Support, 177 Temperature class, 41, 123 Temperature limits, 51 186 SIMOTICS FD 1MH1 Operating Instructions 02/2019 Further Information www.siemens.com/drives Siemens AG Process Industries and Drives Postfach 48 48 90026 NURNBERG GERMANY