sivacon
Planning Manual
03/ 2006
SIVACON 8PV
Contents
The Basis for Optimal Power Distribution 2
Selection Criteria SIVACON 8PV – SIVACON 8PT 4
1 SIVACON 8PV 1_6
The Variable Low-Voltage Switchboard
Basics 1_7
• Standards & regulations 1_7
• Technical data 1_7
Cubicle Structure & Busbar Systems 1_8
Mounting Designs 1_9
• Overview 1_9
2 8PV Space Requirements 2_12
Circuit-Breaker Design 2_12
• Cubicle widths for incoming feeder/outgoing
feeder with 3WL circuit-breakers/non-automatic
circuit breakers (ACB) 2_12
• Cubicle widths for longitudinal/transverse
coupling with 3WL circuit-breakers/non-automatic
circuit breakers (ACB) 2_13
• Type-tested busbar connection for 3WL circuit-
breakers / non-automatic circuit-breakers (ACB) 2_13
• Cable connection for 3WL circuit-breakers/
non-automatic circuit-breakers (ACB) 2_13
• Universal mounting design selection table 2_15
Withdrawable Design 2_16
• Rated currents for the vertical distribution busbar 2_16
• Withdrawable design selection table 2_18
Plug-In Design 2_22
• Cubicle structure and equipping 2_22
• Plug-in busbar system 2_23
• Plug-in design selection tables 2_24
In-Line Design 2_26
• Cubicle structure and equipping 2_26
• In-line design selection tables 2_27
Fixed-Mounted Design 2_28
• Cubicle structure and equipping 2_28
• Fixed-mounted design selection tables 2_29
Reactive Power Compensation 2_31
• Cubicle structure and equipping 2_31
• Reactive power compensation selection tables 2_31
3 Planning Notes 3_32
Mounting Options 3_32
• Combination options with double-front boards 3_33
• Floor openings 3_35
• Mounting on raised floors/tolerance data 3_35
• Inlet and connection to the SIVACON 8PS
busbar trunking system 3_37
• Operating and maintenance gangways 3_38
Communication in Switchboards 3_39
Resistance to Internal Arcs 3_41
Checklist for Planners 3_42
Types of Internal Separation (Type 1 to 4) 3_43
TTA – PTTA 3_44
Checklist for Low-Voltage Switchgear Combinations 3_45
Environmental Conditions/Degrees of Protection 3_48
Network Systems 3_50
Example of an Electromagnetically Compatible
TN-S system 3_51
Rated Values/Definitions 3_52
Rated Currents and Initial Symmetrical Short-Circuit
Currents of Three-Phase Distribution Transformers
from 50 to 3150 kVA 3_56
Weights/Power Losses 3_57
Reactive Power Compensation 3_58
Certificates/Approvals 3_60
Your Siemens Contact Partners 62
The development of a power distribution concept
which includes the dimensioning of systems and
plant components necessitates a coordination of the
requirements and feasibilities of both the end user
and the manufacturer. We have therefore prepared
this planning manual for the SIVACON® 8PV low-volt-
age switchboard to support you with this task.
sivacon
2
SIVACON 8PV
Everything. Perfect. SIVACON.
The Basis for Optimal Power Distribution
Safety – integrated
Economic efficiency – right from the start
Flexibility – thanks to modularity
All components of the SIVACON range are
bound by these three principles. Consequently,
all products of the range are optimally matched
to each other.
8PV
8PT
8PT
8PV
LX LD
LX
BD2
LR
BD2
BD01
BD2
CD-K
3
SIVACON 8PV – for the process industry
The type-tested SIVACON 8PV switchgear and controlgear
assembly is, for example, employed in the power, chemi-
cal and mineral oil as well as in the capital goods indus-
tries. This assembly is characterized by a high degree of
availability combined with a high level of personnel and
plant safety and can be used for all applications up to
6,300 A.
SIVACON 8PS – for power distribution
With the SIVACON 8PS busbar trunking system, all load re-
quirements can be reliably and safely satisfied – from
transformers to main distribution boards and small loads –
by a total of six available type-tested systems. These bus-
bar trunking systems are characterized by their high short-
circuit strength and minimum combustive energy and can
be used for all applications up to 6,300 A.
SIVACON 8PT – for the infrastructure
The type-tested SIVACON 8PT switchgear and controlgear
assembly is not only employed for the infrastructural sup-
ply in industrial and building applications (administration,
functional as well as industrial and commercial buildings),
but is also used in the process industry. Matched to the
global market requirements, SIVACON both meets the de-
mand for standard solutions from a single source, as well
as that for local production. This assembly can be used for
all applications up to 7,400 A.
4
SIVACON 8PV
Selection Criteria
SIVACON 8PV – SIVACON 8PT
Selection criteria SIVACON 8PV
Busbar position Top Rear
Rated busbar currents up to 2,500 A 6,300 A
Rated currents ingoing feeder up to 2,500 A 6,300 A
Short-circuit strength Icw (1s) 50 kA 100 kA
Busbars up to Ipk 110 kA 220 kA (250 kA)
Mounting designs
Circuit-breaker design 
(fixed-mounted / withdrawable) (1 breaker per cubicle) (1 breaker per cubicle)
Fixed-mounted design 
In-line design LV HRC in-line design LV HRC in-line design
Plug-in design Motor & power feeders Motor & power feeders
(fuseless) (fuseless)
Withdrawable design 
Mounting options Stand-alone/wall mounting/ Stand-alone/wall mounting/
back-to-back back-to-back
double front
Application Motor control centers Motor control centers
Power distribution boards Power distribution boards
Production Siemens Siemens
Safety characteristics
Safety proof for each TTA-tested standard modules in acc. with IEC 60439-1
specifically developed system
Cubicle-to-cubicle safety Solid-wall design
Safety with test and disconnected The systems’ degree of protection is maintained up to IP54:
position Increased protection of the operating personnel
Avoidance of harmful deposits in the system
Uniform operation of withdrawable units Uniform user interface for small and standard withdrawable units, with integr. operator error protection:
Avoidance of maloperations
Reduction of instruction times
Resistance to internal arcs Stepped concept with additive modules for the active and passive limitation of arcing faults:
(IEC 61641) 690 V, 65 kA, 300 ms
Insulated busbars as additive
Seismic withstand capability Acceleration on the system's mounting level:
(IEC 60068-3-3, IEC 60068-2-57, Function during earthquakes 0.6 g
IEC 60980, KTA 2201.4) Function after earthquakes 0.9 g
And of course Switchgear and controlgear made by Siemens:
No premature failures
Minimum downtimes
Short delivery periods
Available
5
SIVACON 8PT
Top Rear
7,400 A 3,200 A
6,300 A 3,200 A
150 kA 85 kA
375 kA 187 kA

(1, 2 or 3 breakers per cubicle) (1 breaker per cubicle)

LV HRC in-line design LV HRC in-line design
Motor & power feeders
(fuseless/fused)
Stand-alone/wall mounting/ Stand-alone/wall mounting/
back-to-back back-to-back
––
Motor control centers
Power distribution boards Power distribution boards
Siemens/SIVACON technology partners Siemens/SIVACON technology partners
TTA-tested standard modules in acc. with IEC 60439-1
Additive partition walls
The systems’ degree of protection is maintained up to IP54 with circuit-breaker design and up to IP30 with withdrawable design:
Increased protection of the operating personnel
Avoidance of harmful deposits in the system
Uniform user interface for all withdrawable units:
Avoidance of maloperations
Reduction of instruction times
Stepped concept with additive modules for the active and passive limitation of arcing faults:
690 V, 50 kA, 300 ms 440 V, 50 kA, 300 ms
Insulated busbars as additive
1_6
SIVACON 8PV
SIVACON 8PV
The Variable Low-Voltage Switchboard
Introduction
Economical, demand-oriented and type-tested (TTA) –
those are the characteristics of the low-voltage switch-
board made by Siemens. SIVACON 8PV is applicable on all
performance levels: From 6,300 A power centers to main
and sub-distribution boards, down to motor control cen-
ters – both in fixed-mounted and plug-in, as well as in
withdrawable design. Thanks to the central Siemens-inter-
nal production, this type-tested switchgear and control-
gear assembly offers the excellent quality and short deliv-
ery periods of a mature series product.
Modular design
Every SIVACON 8PV switchboard is exclusively manufac-
tured from demand-oriented and series-produced mod-
ules, all of which are type-tested and of high quality. Due
to the modules’ vast combination options, each and every
requirement can be met.
Adaptations to new performance requirements can be eas-
ily and rapidly implemented by the replacement or supple-
mentation of modules. The advantages offered by this
modular concept are obvious:
Safety and quality proof for all switchboards
thanks to type test
Compliance with any requirement profile with the high
quality of series production
Easy placement of repeat orders and short delivery
periods
The advantages offered by SIVACON set new
standards:
Safety and quality proof for all switchboards thanks to type test
Compliance with any requirement profile with the high quality
of series production
Easy placement of repeat orders and short delivery periods
3- and 4-pole busbar system up to 6,300 A
Short-circuit strength Icw (1s) up to 100 kA; Ipk up to 250 kA
Type-tested standard modules (TTA)
Space-saving mounting surface from 400 x 400 mm
Maximum packing density with up to 40 feeders per cubicle
Test and disconnected position with closed door and maintenance
of the degree of protection (up to IP54)
Visible isolating distances and contact points
Uniform user interface for all withdrawable units
Solid-wall design for safe cubicle-to-cubicle separation
Variable busbar positions at the top or rear
Cable/busbar connection from the top or bottom
Application areas
Chemical &
mineral oil industry
Motor control centers
Power distribution from the power center down to main and sub-distribution
Power industry:
Power plants and
auxiliaries systems
Capital goods industry:
Production-related systems
Infrastructure:
Building complexes
Technical data
Mounting conditions Indoor mounting
Ambient temperature 24-h average + 35°C (-5°C to +40°C)
Degree of protection In acc. with IEC 60529, EN 60529 IP20, IP21, IP40, IP41, IP54
Internal separation IEC 60439-1, Section 7.7,
VDE 0660 Part 500, 7.7 Type 1 to type 4
Rated insulation voltage (Ui) Main circuit 1000 V
Main circuit (Ue) Main circuit Up to 690 V
Creepage distances and clearances Rated impulse withstand voltage Uimp 8 kV
Overvoltage category III
Pollution degree 3
Main busbars horizontal (3- and 4-pole), busbar position top
Rated operational current (ventilated) [A] 660 860 1,070 1,280 1,590 1,990 2,250
Rated operational current (non-ventilated) [A] 590 770 950 1,150 1,300 1,630 1,965
Rated peak withstand current Ipk [kA] 60 85 110 110 110 110 110
Rated short-time withstand current Icw (1s) [kA] 29 40 50 50 50 50 50
Main busbars horizontal (3- and 4-pole), busbar position rear
Rated operational current (ventilated) [A] 1,255 1,645 1,990 2,380 2,665 3,300 3,500/3,700 4,000 6,300
Rated operational current (non-ventilated) [A] 1,165 1,525 1,840 2,200 2,470 3,050 3,250 3,250 4,850
Rated peak withstand current Ipk [kA] 110 165 220 220 220 220 250 220 220
Rated short-time withstand current Icw (1s) [kA] 50 75 100 100 100 100 100 100 100
Busbars vertical for circuit-breaker design (3- and 4-pole)
Nominal current Refer to main busbars horizontal
Rated peak withstand current Ipk Refer to main busbars horizontal
Rated short-time withstand current Icw (1s) Refer to main busbars horizontal
Busbars vertical For fixed-mounted design, For withdrawable design
(3- and 4-pole) in-line design & plug-in design
Rated operational current [A] Up to 2,000 Up to 1,000
Rated peak withstand current Ipk [kA] Up to 110 Up to 110
Rated short-time withstand current Icw (1s) [kA] Up to 50* Up to 65*
Surface treatment
Rack components Sendzimir-galvanized
Casing Sendzimir-galvanized/powder-coated
Doors Powder-coated
Color of powder-coated components RAL 7035, light gray (in acc. with DIN 43656)
(layer thickness 100 ± 25 µm)
* Rated conditional short-circuit current Icc up to 100 kA
1_7
11
Standards & regulations
Type-tested low-voltage controlgear and IEC 60439-1
switchgear assembly (TTA) DIN EN 60439-1 (VDE 0660 Part 500)
Testing of response to internal faults IEC 61641, VDE 0660 Part 500, Supplement 2
(internal arcs) (Uebis 690 V, Icw (1s) bis 65 kA, t bis 300 ms)
Induced vibrations IEC 60068-2-57, IEC 60068-3-3, IEC 60980
Basics
Mounting Busbar system Cubicle structure
1_8
SIVACON 8PV
Cubicle Structure & Busbar Systems
Single-front
Wall assembly,
Stand-alone assembly,
back-to-back assembly
Single-front
Wall assembly,
stand-alone assembly,
back-to-back assembly
Double-front
Stand-alone as-
sembly
Power center
Stand-alone assembly
Cable compartment
Busbar compartment
Device/function compartment
Cross-wiring compartment
Operating panelsSocket compartment
Busbar position: top
Rated current: Up to 2,500 A
Cable/busbar entry: From the bottom
Busbar system: 3-/ 4-pole
Busbar position: Rear
top,
Bottom,
Top & bottom
Rated current: Up to 4,000 A
Cable/busbar entry: From the bottom
From the top
Busbar system: 3-/ 4-pole
Busbar position: Center
top,
Bottom,
Top & bottom
Rated current: Up to 4,000 A
Cable/busbar entry: From the bottom
From the top
Busbar system: 3-/ 4-pole
Busbar position: Center top
Rated current: Up to 6,300 A
Cable/busbar entry: From the bottom
From the top
Busbar system: 3-/ 4-pole
2200
225225 10 x 175
L1 L2 L3
400
N
PE/PEN
2200
225225 10 x 175
400 200
L1
L2
L3
400 200 400
225225 10 x 175
L1
L2
L3
N
PE/PEN
2200
L1
L2
L3
PE/PEN
N
400 400
400
L1
L2
L3
N
PE/PEN
2200
225225 10 x 175
s
M
L
K
J
H
G
F
E
D
C
B
A
0
200
400
600
800
1000
1200
1400
1600
1800
2000
2200
SIVACON
M
L
K
J
H
G
F
E
D
C
B
A
0
200
400
600
800
1000
1200
1400
1600
1800
2000
2200 s
SIVACON
Refer to page 12 Refer to page 16
1_9
11
Mounting Designs
Overview
Withdrawable design up to 630 A
Outgoing motor feeders up to 355 kW (400 V) and
500 kW (690 V)
Outgoing cable feeders up to 630 A
Incoming feeders up to 630 A
Maximum packing density with up to 40 withdrawable
units per cubicle
Test and disconnected position with closed door and
maintenance of degree of protection
Visible isolating distances on the incoming and outgoing
side
Uniform user interface for all withdrawable units
Large cable compartment with a width of 400 mm
Connections for the power and control unit in the cable
compartment
Replacement of withdrawable units while energized
Change of cubicle panel sizes possible during operation
Plug-in busbar system
Embedded with resistance to internal arcs
Test-finger proof (IP20B)
Phase separation
3- and 4-pole
Pick-off openings in a modular grid of 175 mm
Circuit-breaker design from 630 A to 6,300 A
Incoming feeders
Couplings (longitudinal and tranverse coupling)
Outgoing feeder bays
Circuit-breakers in fixed-mounted design;
or
Circuit-breakers in withdrawable design
Cubicle width matched to breaker sizes
(e.g. cubicle width of 400 mm with In= 1,600 A)
Clearly separated function compartments
Test and disconnected position with closed door
Type-tested connection with cable or LD/LX
busbar trunking system
Large cable/busbar compartment
High degree of safety for the mounting personnel
thanks to double-sides cubicle separation
Separate auxiliary device compartment for each circuit-
breaker
Space for comprehensive controls and interlockings
Withdrawable auxiliary device module which can be
separated from the power unit
s
SIVACON
0
200
400
600
800
1000
1200
1400
1600
1800
2000
2200
L
K
J
H
G
F
E
D
C
B
A
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
s
SIVACON
0
200
400
600
800
1000
1200
1400
1600
1800
2000
2200
L
K
J
H
G
F
E
D
C
B
A
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
4
3
2
1
Refer to page 22 Refer to page 26
2_10
SIVACON 8PVSIVACON 8PVSIVACON 8PV
Plug-in design up to 100 A
Outgoing motor feeders in fuseless design up to 45 kW
Outgoing cable feeders in fuseless design up to 100 A
Combinable with in-line design for fused outgoing cable
feeders up to 630 A
High packing density with up to 35 withdrawable units
per cubicle
Plug-in contacts on the supply line side
Individual equipping with devices or device
combinations
Free combination of modules within the cubicle
Lateral guide for a safe plug connection
Instrument panel for measuring and command devices
directly at the plug-in unit
Large cable compartment with a width of 400 mm or
600 mm
Connections for the power and control unit in the cable
compartment
Replacement without system shutdown
Plug-in busbar system
Integrated touch guard
Test-finger proof (IP20B)
3- and 4-pole
Pick-off openings in a modular grid of 50 mm
In-line design up to 630 A
Fuse switch-disconnector with single-break
Fuse switch-disconnector with double-break
High packing density with up to 35 in-line units per
cubicle
In-line units with/without auxiliary switch
In-line units with/without fuse monitoring as group or
individual fault message
Plug-in contact on the supply line side
Dead-state fuse replacement
Large cable compartment with a width of 400 mm or
600 mm
Connections for the power and control unit in the cable
compartment
Good accessibility
Replacement without system shutdown
Plug-in busbar system
Integrated touch guard
Test-finger proof (IP20B)
3- and 4-pole
Pick-off openings in a modular grid of 50 mm
s
SIVACON
M
L
K
J
H
G
F
E
D
C
B
A
0
200
400
600
800
1000
1200
1400
1600
1800
2000
2200 s
SIVACON
M
L
K
J
H
G
F
E
D
C
B
A
0
200
400
600
800
1000
1200
1400
1600
1800
2000
2200
Refer to page 28 Refer to page 31
2_11
11
Fixed-mounted design for reactive
power compensation
500 kvar per cubicle non-throttled
250 kvar per cubicle throttled (5.67% oder 7%)
Capacitor modules up to 100 kvar with
Fuse switch-disconnector
Capacitor contactor
MKK capacitors
Discharge devices
Optional filter reactors (throttled)
Controller assembly with electronic reactive power
controller for door installation
Self-adaptation of the C/k value
Adjustable setpoint cos phi from 0.7 ind to 0.9 cap
Manual control
Integrated fan assembly with higher ambient
temperatures
Optional application of switch-disconnector and/or
audio-frequency parallel trap circuit (AF trap)
Available as basic unit with controller assembly or
as expansion unit without controller assembly
The reactive power compensation cubicles can be
integrated in the switchboard’s system and busbar
assemblies as a standard
Fixed-mounted design up to 1,250 A
Incoming feeders, outgoing feeders & couplings with
MCCB circuit-breakers up to 1,250 A
Universal installation of low-voltage switchgear and
controlgear
Switch-disconnectors
Fuse switch-disconnectors
Fuse switch-disconnectors in in-line design
Automation devices (SIMATIC)
Outgoing installation feeders
Free combination of the equipped modular installation
sheets within the cubicle
Five different module sizes
Attachment system for “one-man mounting”
Horizontal partition of de-
vice compartment possible
Cubicle-high or individual
doors
Cable compartment availa-
ble with a width of 200 mm and 400 mm
Good accessibility
Universal vertical busbar
Fast conversion thanks to connections accessible from
the front
Device connection without boring or punching
Connections visible and checkable from the front
s
SIVACON
s
SIVACON
s
SIVACON
Application area
For incoming feeders,
couplings (longitudinal and tranverse coupling),
outgoing feeders
Degrees of protection (in acc. with IEC 60529,
EN 60529)
IP20 ventilated
IP21 ventilated, IP21 non-ventilated
IP40 ventilated, IP40 non-ventilated
IP41 ventilated, IP41 non-ventilated
IP54 non-ventilated
* Abbreviations: TopBBpos – Top busbar position
RearBBpos – Rear busbar position
DF – Double-front
PC – Power center
The cubicle depths and structures depend on the busbar position, refer to page 8.
Cubicle widths for incoming/outgoing feeder with 3WL circuit-breakers/non-automatic circuit-breakers (ACB)
Rated Min. cubicle width 3-pole Min. cubicle width 4-pole Cubicle depth* Short-circuit
breaker- 400 600 1000 1200 breaking capacity
current
TopBBpos RearBBpos
DF PC Icu
[A] [mm] [mm] [mm] [mm] [mm] [mm] [kA]
630 – 1600 400 ––– 65
6301) – 2500 600 100
630 – 1600 400 600  65
6301) – 3200 600 800  100
4,000 800 1,000  100
5,000 – 6,300 1,000 100
1) 630 A with rated current module (rating plug)
2_12
SIVACON 8PV
8PV Space Requirements
Circuit-Breaker Design
Circuit-breaker 630 A to 6,300 A,
fixed-mounted and withdrawable design
Cubicle dimensions
Height: 2,200 mm
Width: According to table
Depth: 400, 600, 1,000, 1,200 mm
Type of internal separation
Type 1 (cubicle-high door)
Type 2b, 4a (cubicle-high door)
Type 2a, 3a/3b, 4b (3-partitions door)
Design options
Air circuit-breaker (ACB)
Molded-case circuit-breaker (MCCB)
Fuse switch-disconnector
Switch disconnector
Cable / busbar connection direction
Busbar position top
Cubicle depth 400 mm: Bottom cable/busbar
compartment
Busbar position rear
Cubicle depth 600/1,000/ Optional top or bottom
1,200 mm: cable/busbar
compartment
Cubicle widths for longitudinal/tranverse couplings with 3WL circuit-breakers/non-automatic circuit-breakers (ACB)
Rated Min. cubicle width 3-pole Min. cubicle width 4-pole Cubicle depth* Short-circuit
breaker Longitudinal Transverse Longitudinal Transverse 400 600 1,000 1,200 breaking capacity
current coupling coupling coupling coupling
TopBBpos
RearBBpos
DF PC Icu
[A] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [mm] [kA]
630 – 1,600 600 65
6301) – 2,500 800 100
630 – 1,600 500 400 600  65
6301) – 2,500 600 600 800  100
3,200 800 600 800  100
4,000 1,000 800 1,000  100
5,000 1,000 + 500 100
1) 630 A with rated current module (rating plug)
The cubicle widths for fuse switch-disconnectors and molded-case circuit-breakers (MCCB) are available upon request.
Type-tested busbar connection for 3WL circuit-breakers / non-automatic circuit-breakers (ACB)
Rated Circuit-breaker Connectable SIVACON 8PS Min. cubicle width
breaker size busbar trunking system 3-pole
current
[A] [mm]
1,600 Size I LD/ LX 400
2,000 Size II LD/ LX 600
2,500 Size II LD/ LX 600
3,200 Size II LD/ LX 600
4,000 Size III LD /LX 800
Cubicle widths for fuse switch-disconnectors and molded-case circuit breakers (MCCB)
are available upon request.
Cable connection for 3WL circuit-breakers/non-automatic circuit-breakers (ACB)
Rated Circuit-breaker Connectable cables per connection rail for
breaker size L1; L2; L3 PE; PEN; N
current (N with 4-pole version)
[A] [mm2][mm
2]
630 – 1,000 Size I 4 x 240 4 x 240
1,250 – 1,600 Size I 6 x 240 6 x 240
2,000 – 2,500 Size II 9 x 300 9 x 300
3,200 Size II 11 x 300 11 x 300
4,000 Size III 14 x 300 14 x 300
5,000 Size III Realization with busbar connection
6,300 Size III
2_13
22
2_14
SIVACON 8PV
Derating factors circuit-breaker design
Derating factors Ie/Inwith incoming or outgoing feeder function at an average ambient temperature of 35°C
Rated Circuit-breaker Cubicle depth
breaker size 400 mm 600 /1,000 mm 1,200 mm
current Top busbar position Rear busbar position/ Power center
double-front
[A] Non-ventilated Ventilated Non-ventilated Ventilated Non-ventilated Ventilated
(e.g. IP54) (e.g. IP20) (e.g. IP54) (e.g. IP20) (e.g. IP54) (e.g. IP20)
630 – 800 Size I 1 1 1.00 1.00 1.00 1.00
1,000 Size I 0.94 1 1.00 1.00 1.00 1.00
1,250 Size I 1 1 0.95 1.00 0.95 1.00
1,600 Size I 0.91 0.99 0.85 0.93 0.85 0.93
2,000 Size II 0.86 0.95 0.95 1.00 0.95 1.00
2,500 Size II 0.75 0.84 0.81 0.95 0.81 0.95
3,200 Size II 0.77 0.86 0.77 0.86
4,000 Size III 0.72 0.87 0.72 0.87
5,000 Size III ––––0.82 1.00
6,300 Size III ––––0.65 0.84
Derating factors Ie/Inwith longitudinal coupling function at an average ambient temperature of 35°C
Rated Circuit-breaker Cubicle depth
breaker size 400 mm 600/1,000 mm 1,200 mm
current Top busbar position Rear busbar position/ Power center
double-front
[A] Non-ventilated Ventilated Non-ventilated Ventilated Non-ventilated Ventilated
(e.g. IP54) (e.g. IP20) (e.g. IP54) (e.g. IP20) (e.g. IP54) (e.g. IP20)
630 – 800 Size I 1111––
1000 Size I 0.9 111––
1250 Size I 0.96 111––
1600 Size I 0.87 1 0.96 1
2000 Size II 0.8 0.94 0.96 1
2500 Size II 0.7 0.83 0.82 0.94
3200 Size II 0.72 0.85
4000 Size III 0.77 0.94
5000 Size III ––––0.84 1.00
6300 Size III ––––0.66 0.86
Derating factors Ie/Inwith transverse coupling function at an average ambient temperature of 35°C
Rated Circuit-breaker Cubicle depth
breaker size 600/1,000 mm
current Rear busbar position/double-front
[A] Non-ventilated Ventilated
(e.g. IP54) (e.g. IP20)
630 – 1,250 Size I 1 1
1,600 Size I 0.91 1
2,000 Size II 0.94 1
2,500 Size II 0.84 1
3,200 Size II 0.87 0.97
4,000 Size III 0.73 0.92
The derating factors are rounded values,
which serve as a basis for rough planning.
The exact rated currents for the circuit-
breaker design cubicles as well as factors
for deviating ambient temperatures have
to be requested.
Cross-wiring compartment
Auxiliary device compartment
Device compartment *
Cable compartment
* Optionally with MCCB circuit-breaker, DUMECO
switch disconnector or
EFEN LV HRC switch disconnector size 4a
2_15
22
The circuit-breaker cubicle’s layout in universal mounting
design is analog to that of circuit-breaker cubicles with
ACB breakers, i.e. it is divided into a cross-wiring, an
auxiliary device, a device and a cable compartment.
Layout
Universal mounting design selection table
Devices Rated Derating factors Ie/InCubicle width
breaker current Ambient temperature of 35°C
[A] [mm]
Non-ventilated Ventilated
EFEN LV HRC switch-disconnector size 4a 1,250 0.84 0.89 500
DUMECO switch-disconnector 800 1.00 1.00 400
DUMECO switch-disconnector 1,250 0.85 0.95 500
DUMECO switch-disconnector 1,600 0.75 0.90 500
Circuit-breaker (MCCB) 630 0.81 0.94 400
Circuit-breaker (MCCB) 800 0.79 0.83 400
Circuit-breaker (MCCB) 1,250 0.78 0.80 400
Circuit-breaker (MCCB) 1,600 0.61 0.63 400
2_16
SIVACON 8PV
Withdrawable Design
Withdrawable units up to 630 A
Rated currents for the vertical distribution busbar
400 mm cubicle depth 600/1,000 /1,200 mm cubicle depth
Top busbar position Rear busbar position/double-front/power center
Ventilated 35°C (e.g. IP20) Non-ventilated 35°C (e.g. IP54) Ventilated 35°C (e.g. IP20) Non-ventilated 35°C (e.g. IP54)
680 A 560 A 980 A 1) 770 A 2)
With rear busbar positions, the current division can be used in an 8M to 2M relation.
1) 980 A = 680 A + 300 A
2) 770 A = 560 A + 210 A
Application area
Motive power loads
Outgoing cable feeders
Incoming feeders
Degrees of protection (in acc. with IEC 60529,
EN 60529)
IP20 ventilated
IP21 ventilated, IP21 non-ventilated
IP40 ventilated, IP40 non-ventilated
IP41 ventilated, IP41 non-ventilated
IP54 non-ventilated
Cubicle dimensions
Height: 2,200 mm
Width: 1,000 mm
1,200 mm upon request
Depth: 400, 600, 1000, 1200 mm
Type of internal separation
Type 3b, 4b
Size 1 M Size 1/2 M Size 1/4 M
Cable connection
Busbar position top
Cubicle depth 400 mm: Bottom cable connection
Busbar position rear
Cubicle depth 600/1000 /1,200 mm: Optional top or
bottom connection
Summation current of all feeders: Refer to table.
Individual feeder utilization
Motor starters: I≤ 0,8
Cable feeders: I≤ 0,8
Design options
Fuseless load feeders
Fused load feeders
Outgoing motor feeders with and without overload relay
Withdrawable units with and without communication
connection
Cubicle structure:
Height device compartment: 1,750 mm
(10 modules á 175 mm)
Width device compartment: 600 mm
Width cable compartment: 400 mm
(600 mm upon request)
Cubicle structure (1 M = 1 module = 175 mm)
Withdrawable unit size: 4 x 1/4M = module
2 x 1/2M = 1 module
1 x 1 M = 1 module
1 x 2 M = 2 module up to
1 x 8 M = 8 module
s
SIVACON
s
SIVACON
340 A
340 A
300 A
2 Module
8 Module
490 A
490 A
8 Module
2 Module
AZNV
Test
AZNV/Test
-Q1
-X19
-S21
21
22
Einschub Fach
-Q1
-X19
-S21
21
22
-X19
-S21
21
22
COM
-Q1
-S20
ANZV
Test
X19 = Auxiliary isolating contact
S20 = Signaling switch in withdrawable unit*
S21 = Signaling switch in compartment*
*Operated via main isolating contact
2 modules
2 modules
8 modules8 modules
Withdrawable unit Cubicle panel
2 modules
2 modules2 modules
2_17
22
Examples of current division
Circuit principle and position of the main and auxiliary contacts
Main Auxiliary In with- In
isolating isolating drawable unit compartment
contact contact - S 20 - S 21
1 NO contact 1 NC contact
Operation
Disconnec-
tion *
Test
*No message as auxiliary isolating contact is open
Display and signaling
The position at which a withdrawable unit is located is
clearly indicated by a display on the instrument panel.
Furthermore, messages such as “Feeder not available”
(AZNV), “Test” and “AZNV and test” can be received via
additional signaling switches.
The signaling switch in the compartment (S21) is an end
switch designed as an NC contact and that in the withdraw-
able unit (S20) is an end switch designed as an NO contact.
Both switches are operated via the withdrawable unit’s main
isolating contacts.
Outgoing cable feeders
(3-pole)
2_18
SIVACON 8PV
Withdrawable design selection table
Outgoing cable feeders
(3-pole)
Rated currents and withdrawable unit sizes of fused outgoing cable feeders
Rated Derating factors Ie/InWithdrawable unit
breaker current at an ambient temperature of 35°C size
[A]
Non-ventilated Ventilated
35 0.91 0.91 1/4/ 1/2M
63 0.72 0.8 1 M
125 0.76 0.88 1 M
160 0.78 0.88 2 M
250 0.78 0.94 2 M
400 0.69 0.82 2 M
630 0.70 0.81 3 M
Rated currents and withdrawable unit sizes of fuseless outgoing cable feeders
Rated Derating factors Ie/InWithdrawable unit
breaker current at an ambient temperature of 35°C size
[A]
Non-ventilated Ventilated
12 1.00 1.00 1/4/ 1/2M
25 0.72 0.8 1/4/ 1/2/ 1 M
32/50 0.81/0.78 0.94/0.86 1/2/ 1 M
100 0.77 0.86 1 M
125 0.74 0.81 1 M
160 0.72 0.76 1 M
250 0.75 0.77 2 M
400 0.79 0.85 2 M
630 0.64 0.70 4 M
Rated currents and withdrawable unit sizes of fused outgoing cable feeders
(N-conductor circuit)
Rated Derating factors Ie/InWithdrawable unit
breaker current at an ambient temperature of 35°C size
[A]
Non-ventilated Ventilated
35 0.91 0.91 1/4/ 1/2M
125 0.76 0.88 1 M
250 0.78 0.94 2 M
400 0.69 0.82 2 M
630 0.70 0.81 3 M
Rated currents and withdrawable unit sizes of fuseless outgoing cable feeders
(with and without overload and short-circuit releases in the 4th pole (N))
Rated Derating factors Ie/InWithdrawable unit
breaker current at an ambient temperature of 35°C size
[A]
Non-ventilated Ventilated
32 0.81 0.94 1/2M
125 0.74 0.81 2 M
160 0.72 0.76 2 M
250 0.75 0.77 2 M
400 0.79 0.85 2 M
630 0.64 0.70 4 M
Outgoing cable feeders
(4-pole)
Outgoing cable feeders
(4-pole)
3
I >
3
4
I >
4
2_19
22
Fused outgoing motor feeders 400 V
Rated data (AC-2/AC-3) Withdrawable unit size
Pn[kW] Ie[A]
5.5 12 1/4 M
11 21 1/4 M
18.5 36 1/2 M
11 21 1 M
22 43 1 M
37 68 1 M
45 83 2 M
75 133 2 M
90 157 3 M
132 233 3 M
160 280 3 M
200 340 4 M
250 420 4 M
48,8
1/4M
7.5 15 1/4M
15 28 1/2M
7.5 15 1 M
11 21 1 M
22 43 1 M
37 68 2 M
55 99 2 M
90 157 3 M
132 233 3 M
160 280 3 M
5.5 12 1/4M
11 21 1/4M
18.5 36 1/2M
11 21 1 M
22 43 1 M
45 83 2 M
90 157 3 M
132 233 4 M
160 280 4 M
200 340 4 M
250 420 4 M
15 28 1 M
30 57 1 M
37 68 2 M
55 99 2 M
75 133 2 M
90 157 3 M
132 233 3 M
160 280 3 M
250 420 6 M
355 610 8 M
Direct contactor normal
start-up
Direct contactor heavy-duty start-up Class 30
Reversing circuit
Star-delta circuit
2_20
SIVACON 8PV
Fuseless outgoing motor feeders 400 V, type 2 with 50 kA overload protection CB without SIMOCODE
Rated data (AC-2/AC-3) Withdrawable unit size
Pn[kW] Ie[A]
0.55 1.5 1/4M
7.5 15 1/4M
18.5 36 1/2M
7.5 15 1 M
22 43 1 M
45 83 2 M
55 99 2 M
75 133 2 M
90 157 3 M
110 195 3 M
160 280 3 M
250 420 4 M
0.55 1.5 1/4M
7.5 15 1/4M
18.5 36 1/2M
7.5 15 1 M
22 43 1 M
45 83 2 M
55 99 2 M
75 133 2 M
90 157 3 M
110 195 3 M
160 280 3 M
250 420 4 M
7.5 15 1 M
22 43 1 M
45 83 2 M
55 99 2 M
75 133 3M
90 157 3 M
110 195 3 M
160 280 4 M
250 420 5 M
Direct contactor normal start-up,
type 2 (comfortable solution)
Reversing circuit, type 2 (comfortable solution)
Star-delta circuit
I >
I >
I >
In case of a short-circuit, the employed short-circuit protection device must
safely and successfully disconnect the applied overcurrent. Persons as well
as system components must not be subjected to any risks.
Coordination type 2 (for motor starters): The overload relay or other parts
must not be damaged, with the exception of contactor contact welding, if
the contacts can be easily separated
Previously used term: Type of protection “Class C”
(IEC 60292-1, replaced by IEC 60947-4)
2_21
22
Fuseless outgoing motor feeders 400 V, type 2 with 50 kA overload protection CB with SIMOCODE pro
Rated data (AC-2/AC-3) Withdrawable unit size
Pn[kW] Ie[A]
0.75 1.9 1/4M
5.5 12 1/4M
11 21 1/2M
18.5 36 1/2M
22 43 1 M
37 68 1 M
45 83 2 M
75 133 2 M
90 157 3 M
110 195 3 M
160 280 3 M
250 420 4 M
0.75 1.9 1/2M
5.5 12 1/2M
11 21 1 M
22 43 1 M
37 68 2 M
45 83 2 M
75 133 2 M
90 157 3 M
110 195 3 M
160 280 3 M
250 420 4 M
0.75 1.9 1/2M
5.5 12 1/2M
11 21 1 M
22 43 1 M
37 68 2 M
45 83 2 M
75 133 3 M
90 157 3 M
110 195 3 M
160 280 4 M
250 420 5 M
Direct contactor normal start-up,
type 2 (with SIMOCODE pro C)
Reversing circuit, type 2 (with SIMOCODE pro C)
Star-delta circuit, type 2 (with SIMOCODE pro C)
I >
I >
I >
Motor feeders for 500 V and 690 V are available upon request
Further outgoing motor feeders with the SIMOCODE pro motor management system are available upon request
2_22
SIVACON 8PV
Plug-In Design
Cubicle structure and equipping Type of internal separation
Type 2b
Design options
Fuseless load feeders
Fuseless outgoing motor feeders
Overload protection with CB, overload relays or the
SIMOCODE-DP/SIMOCODE pro C motor management
system
Cubicle structure
Height device compartment: 1,750 mm
Width device compartment: 600 mm
Max. number of modules per cubicle (also refer to table):
Module height 50 mm = 35 items
Module height 100 mm = 17 items
Installation plates for special installations:
100 mm to 450 mm height in a 50 mm grid
Cable connection
Busbar position top
Cubicle depth 400 mm: Bottom cable
connection
Busbar position rear
Cubicle depth 600/1,000/1,200 mm: Optional top or
bottom connection
Connections for the power unit directly at the switch-
gear or controlgear
Control unit connected via plug connector in the cable
compartment
Instrument panel for measuring and command devices
directly at the plug-in unit
Fuseless outgoing motor feeders up to 45 kW with
motor protection switch
Fuseless outgoing cable feeders up to 100 A with
circuit-breaker
Combinable with in-line design
Application area
Price-favorable alternative to the comfortable in-line
design for outgoing cable and motor feeders
Degrees of protection (in acc. with IEC 60529,
EN 60529)
IP20/IP21 ventilated
IP40 ventilated
IP41 ventilated
Cubicle dimensions
Height: 2,200 mm
Width: 1,000 mm (1,200 mm auf Anfr.)
Depth: 400, 600, 1,000, 1,200 mm
2_23
22
Plug-in busbar system
(Separation possible in 1,000 mm + 750 mm ratio)
Rated operational current Short-circuit strength
ventilated 35°C Icw/Ipk
1,000 A 50 kA/110 kA
Summation current of all feeders: ≤ 1000 A
Individual feeder utilization:
Motor starters: I≤ 0,8 In Motor
Cable feeders: I≤ 0,7 In Circuit-breaker
Distance rule:
Above and below each motor starter with devices of size 3
(30 to 45 kW), one module (50 mm) distance to the next
plug-in module.
When adhering to the above rules, the cubicle can be
equipped arbitrarily. All feeders may be operated simulta-
neously.
Equipping of ventilated cubicles
1
2
s
SIVACON
s
SIVACON
1) The topmost module cannot be equipped with an instrument panel.
2) Between in-line units and in-line module, a distance of
1 M = 50 mm must be provided for.
1,000 mm 1,000 mm
with door cutout without door cutout
for instrument panel for instrument panel
2_24
SIVACON 8PV
Fuseless outgoing cable feeders (3-pole)
Rated Derating factors Ie/InModule height
device current ventilated, 35°C
[A] [mm]
12 0.71 50*
25 0.70 50*
50 0.70 100
100 0.70 100
* With 1-phase current measuring = 100 mm module height
I >
Fuseless outgoing motor feeders 400 V, type 1
Rated data With SIMOCODE Module height
Pn[kW] Ie[A] [mm]
5.5 12 50*
11 21 50*
22 43 100
45 83 100
5.5 12 -DP 100
11 21 -DP 100
22 43 -DP 100
45 83 -DP 100
0.75 1.9 pro C 50
5.5 12 pro C 50
11 21 pro C 100
22 43 pro C 100
37 68 pro C 100
45 83 pro C 100
I >
Plug-in design selection table
Direct contactor normal start-
up (Class 10), type 1, 50 kA
Rated data With SIMOCODE Module height
Pn[kW] Ie[A] [mm]
5.5 12 100
11 21 100
22 43 150
45 83 200
5.5 12 -DP 100
11 21 -DP 100
22 43 -DP 150
45 83 -DP 200
0.75 1.9 pro C 100
5.5 12 pro C 100
11 21 pro C 150
22 43 pro C 150
37 68 pro C 200
45 83 pro C 200
I >
Reversing circuit
type 1, 50 kA
* With 1-phase current measuring
= 100 mm module height
2_25
22
Fuseless outgoing motor feeders 400 V, type 2
Rated data With SIMOCODE Module height
Pn[kW] Ie[A] [mm]
0.55 1.5 50 *
7.5 15 50 *
22 43 100
45 83 100
0.55 1.5 -DP 100
7.5 15 -DP 100
22 43 -DP 100
45 83 -DP 100
0.75 1.9 pro C 50
5.5 12 pro C 50
11 21 pro C 100
22 43 pro C 100
37 68 pro C 100
45 83 pro C 100
I >
Direct contactor normal start-
up (Class 10), type 2, 50 kA
Rated data With SIMOCODE Module height
Pn[kW] Ie[A] [mm]
0.55 1.5 100
7.5 15 100
22 43 150
45 83 200
0.55 1.5 -DP 100
7.5 15 -DP 100
22 43 -DP 150
45 83 -DP 200
0.75 1.9 pro C 100
5.5 12 pro C 100
11 21 pro C 150
22 43 pro C 150
37 68 pro C 200
45 83 pro C 200
I >
Reversing circuit
type 2, 50 kA
* With 1-phase current measuring
= 100 mm module height
Terms Explanation Previously used terms
The following applies to both types of coordination:
In case of a short-circuit, the employed short-circuit protection device must safely and successfully disconnect the applied overcurrent. Persons as well as
system components must not be subjected to any risks.
Coordination type 1 After a short-circuit disconnection, the starter may be Type of protection “Class a”
(for motor starters) inoperative as a damage to the contactor and the (IEC 60292-1, replaced by IEC 60947-4)
overload relay is permissible.
Coordination type 2 The overload relay or other parts must not be damaged, Type of protection “Class c”
(for motor starters) with the exception of contactor contact welding, if the (IEC 60292-1, replaced by IEC 60947-4)
contacts can be easily separated.
2_26
SIVACON 8PV
In-Line Design
Cubicle structure and equipping
Outgoing cable feeders up to 630 A with
pluggable in-line fuse switch-disconnectors
Design options
In-line units for outgoing cable feeders up to 630 A
alternatively as
Fuse switch-disconnectors with single break
Fuse switch-disconnectors with double break
In both of the above cases with or without electronic
fuse monitoring
Cubicle dimensions
Height: 2,200 mm
Width: 1,000 mm (1,200 mm on request)
Depth: 400, 600, 1,000, 1,200 mm
Application area
Price-favorable alternative to the withdrawable design for
outgoing cable feeders.
Easy and fast conversion or replacement under operating
conditions.
Degrees of protection (in acc. with IEC 60529,
EN 60529)
IP20/IP21 ventilated
IP40 ventilated
IP41 ventilated
Type of internal separation
Typ 3b
Typ 4b
Cubicle structure
Height device compartment: 1750 mm
Width device compartment: 600 mm
Max. number of modules per cubicle (also refer to table):
Module height 50 mm = 35 items
Module height 100 mm = 17 items
Module height 200 mm = 8 items
Device compartment for auxiliary devices and instruments
with a height between 100 mm and 400 mm, consisting
of:
Door with and without instrument panel
Mounting plate
With and without connection module 100 A at the plug-
in busbar system
Cable connection
Busbar position top
Cubicle depth 400 mm: Bottom cable
connection
Busbar position rear
Cubicle depth 600/1,000/1,200 mm: Optional top or
bottom connection
Size Nominal Max. number and cross-sections
current of the cables to be connected
[A] [mm2]
00 160 1 x 95
1 250 1 x 240
2 400 2 x 240
3 630 2 x 240
2_27
22
Installation data of ventilated cubicles with 3-pole in-line units (4-pole in-line units upon request)
Installation data of in-line units, 3-pole
Rated Size Derating factors Max. number of Height requirement
Current Ie/Initems per cubicle of in-line units
ventilated 35°C
[A] [mm]
160 00 0.78 35 50
250 1 0.80 17 100
400 2 0.80 8 200
630 3 0.79 8 200
Further installations
Designation Height requirement
[mm]
Blanking covers for empty compartments / connection module 50
Device compartment 100 *
Device compartment 200 *
Device compartment 300 *
Device compartment 400 *
Connection module 400 A for device compartment + 50
Group fault indicator 1 – 10 in-line units
Group fault indicator 1 – 100 in-line units
*) Max. utilizable device installation depth 185 mm
In-line design selection table
Equipping rules for ventilated cubicles with 3-pole
in-line units (4-pole in-line units upon request)
1. Equipping in the cubicle from bottom to top,
decreasing from size 3 to size 00
2. Recommended maximum equipping, including reserve,
per cubicle 1,250 mm (approx. 2/3)
3. Distribution of in-line units of sizes 2 and 3 to different
cubicles if possible
4. Summation operational current per cubicle
max. 2,000 A
5. Rated currents of the device sizes = 0.8 x INof the
largest fuse link
6. Rated currents of smaller fuse links of one size = 0.8 x IN
of the fuse link
Plug-in busbar system
(Separation possible in 1,000 mm + 750 mm ratio)
Rated operational current Short-circuit strength
ventilated 35°C Icw/Ipk
[A] [kA]
2010 50/110
2_28
SIVACON 8PV
Fixed-Mounted Design
Cubicle structure and equipping
Fuseless outgoing cable feeders up to 630 A
Fused outgoing cable feeders up to 630 A
Outgoing motor feeders up to 250 kW
Application area
Realization of outgoing cable and motor feeders
Degrees of protection (in acc. with IEC 60529,
EN 60529)
IP20 ventilated
IP21 ventilated, IP21 non-ventilated
IP40 ventilated, IP40 non-ventilated
IP41 ventilated, IP41 non-ventilated
IP54 non-ventilated
Cubicle structure
Height device compartment: 1,750 mm
(10 modules à 175 mm)
Width device compartment: 600 mm
Width cable compartment: 200 mm, 400 mm
Cubicle dimensions
Width: 800, 1,000 mm
Height: 2,200 mm
Depth: 400, 600, 1,000, 1,200 mm
Type of internal separation
Typ 2b, 4a
Design options
Molded-case circuit-breakers
Fuse switch-disconnectors
Switch-disconnectors with fuses
In-line fuse switch-disconnectors
Illustration of door variants
Cable connection
Busbar position top
Cubicle depth 400 mm: Bottom cable
connection
Busbar position rear
Cubicle depth 600/1,000/1,200 mm: Optional top or
bottom cable
connection
s
SIVACON
s
SIVACON
s
SIVACON
Cubicle-high
door
Cubicle-high door
divided for separate
cable compartment
Plain doors
in front of
module plates
2_29
22
Ventilated (e.g. IP20) Non-ventilated (e.g.. IP54)
Rated operational current at 35°C In: 1,360 A 1,060 A
Rated short-time current Icw: 50 kA 50 kA
Rated peak withstand current Ipk: 110 kA 110 kA
Circuit-breaker coupling In: 983 A 841 A
Vertical busbar system
Separation possible in 4:6 or 5:5 ratio with or without
coupling switch
Fixed-mounted design selection table
Outgoing cable feeders, 3-pole
Type Outgoing feeder Rated values Derating factors Ie/In2) Height Module height
requirement 1)
Circuit diagram Ventilated Non-ventilated [Modul] [mm]
Fuse NH00/160 A 0.94 0.72 1 M 175
switch-disconnector NH1/250 A 0.98 0.72 2 M 350
NH2/400 A 0.99 0.78 2 M 350
NH3/630 A 0.93 0.78 2 M 350
Switch-disconnector NH00 /125 A 0.84 0.76 1 M 175
with fuses NH00/160 A 0.84 0.72 2 M 350
NH1/250 A 0.94 0.72 2 M 350
NH2/400 A 0.79 0.63 2 M 350
NH3/630 A 0.88 0.70 3 M 525
Circuit-breaker 160 A 0.76 0.72 1 M 175
250 A 0.77 0.74 1 M 175
400 A 0.77 0.74 1 M 175
630 A 0.70 0.64 2 M 350
1) 1 M = 1 module height = 175 mm
2) At an ambient temperature of 35°C
6 M 1050
mm
4 M 700
mm 6 M 1050
mm
4 M 700
mm
Vertical busbar separation
5 M
3VL7
3 M
4 M
5 M
2 M
3VL6
3NP54
3VL6
3NP54
Vertical busbar coupling
2_30
SIVACON 8PV
Outgoing motor feeders
Nominal motor power [kW]
Fused design Fuseless design Height
Coordination type 2 Coordination type 1 Coordination type 2 requirement 1)
Fuse Switch-disconnector
switch-disconnector with fuse
Direct Revers- Star- Direct Revers- Star- Direct Revers- Star- Direct Revers- Star- Module Height
ing delta ing delta ing delta ing delta [mm]
45 11 18.5 37 11 18.5 45 11 18.5 18.5 15 11 1M 175
75 45 75 90 37 55 110 45 110 110 2M 350
250 90 132 160 160 132 250 132 250 132 110 3M 525
250 200 200 200 160 4M 700
160 250 250 250 250 250 5M 875
1 M = 1 module height = 175 mm
Type Space Max. number Height requ. 1)[Module] Derating factors
Ie/In2) Cable connection
requirement per module plate Installation
[mm] Top Bottom Ventilated Non-ventilated
NH00/160 A 50 8 3 M 4 M 0.68 0.56 Top/bottom
NH1/250 A 100 4 4 M 5 M 0.68 0.56 Bottom
NH2/400 A 100 4 4 M 5 M 0.72 0.61 Bottom
NH3/630 A 100 4 4 M 5 M 0.64 0.63 Bottom
1) 1 M = 1 module height = 175 mm
2) At an ambient temperature of 35°C
Fused in-line design
The installation of LV HRC in-line fuse switch-disconnec-
tors in vertical mounting position is realized on modular
plates. Per cubicle, two assemblies of LV HRC in-line fuse
switch-disconnectors are possible.
3 M module plate with
max. 8 in-line units
Size 00
4 M module plate with
max. 4 LV HRC in-line units
Size 1 – 3
2_31
22
Reactive power compensation selection tables
Selection table for direct connection to the main busbar
Reactive power per Throttling Steps Audio-frequency trap or breaker
cubicle [kvar] [kvar]
100 4 x 25
125 5 x 25
150 6 x 25
175 7 x 25
200 4 x 50
250 5 x 50
300 6 x 50
400 8 x 50
500 10 x 50
Further step variants available upon request
Selection table for back-up fuse and connection cable with external installation
Reactive power per Throttling Back-up fuse (with external installation) Cable cross-section (with external
cubicle [kvar] [A] installation) [mm2]
100 250 120
125 300 150
150 355 2 x 70
175 400 2 x 95
200 500 2 x 120
250 630 2 x 150
300 2 x 355 2 x 185
400 2 x 500 4 x 120
500 2 x 630 4 x 150
Application area
Controlled reactive power compensation system with con-
nection to the main busbar or external installation up to
500 kvar
Reactive Power Compensation
Cubicle structure and equipping Degrees of protection (in acc. with IEC 60529,
EN 60529)
IP20 ventilated
IP21 ventilated, IP21 non-ventilated
IP40 ventilated, IP40 non-ventilated
IP41 ventilated, IP41 non-ventilated
Cubicle dimensions
Height: 2,200 mm
Width: 800 mm
Dept: 400, 600, 1,000, 1,200 mm
Design options
Throttled/non-throttled: 5.67%, 7%, 8%,
With/without audio-frequency trap circuit
With/without upstream circuit-breaker as disconnector
between main and distribution busbar
3_32
SIVACON 8PV
Planning Notes
Mounting Options
Cubicle depth 400 mm and 600 mm: Wall or stand-alone
mounting
Cubicle depth 1,000 and 1,200 mm: Stand-alone
Mounting
The following minimum distances from the switchboard to
the obstacles must be maintained:
Mounting heights higher than 2,000 m above sea level
Reduction factors for mounting heights of cubicles
higher than 2,000 m above sea level
Altitude of the Reduction factor
mounting site [m] for the load
Up to 2,200 0.88
2,400 0.87
2,500 0.86
2,700 0.85
2,900 0.84
Up to 3,000 0.83
3,300 0.82
3,500 0.81
Up to 4,000 0.78
4,500 0.76
Up to 5,000 0.74
100 mm 100 mm
75 mm
Switchboard
The dimensions refer to the rack dimensions. Above the cubicles,
a min. space of 400 mm to obstacles must be kept.
3_33
33
Combination options with double-front
switchboards
1. General
Identical cubicle widths for front cubicle and rear
cubicle, longitudinal couplings only combinable with
empty cubicle as rear cubicle.
2. Combination options of mounting designs
Combinations are not restricted by the cubicles’
installation as front or rear cubicle.
Mounting design Reactive power Fixed-mounted Withdrawable Plug-in design Neutral/special
compensation design design cubicles
Mounting design Cubicle width 600 800 800 1,000 800 1,000 800 1,000
[mm] (cubicle +
cubicle expansion)
3WL Size 1 400
500
600
500 + 300 
500 + 500 
600 + 200 
600 + 400 
3WL Size 2 600 2)
800 3) 3)
600 + 200 2) 2) 2) 2) 2)
600 + 400 2) 2) 2) 2)
800 + 200 
4) 2)
3WL Size 3 800 
Reactive power 600 
compensation 800 
Fixed-mounted design 800 
1,000 
Withdrawable design 800 
1,000 
Plug-in design 800 
1,000    
Neutral/special cubicle    
Combination possible
1) Only combinable with empty cubicles
2) Not combinable with 3WL1232 with the main busbar at the rear top
and external connection from the top or the main busbar at the rear
bottom and external connection from the bottom
3) Not combinable with main busbar at the rear top and external
connection from the top or the busbar at the rear bottom and
external connection from the bottom
4) Not combinable with main busbar at the rear top and external
connection from the top and main busbar at the rear bottom
3_34
SIVACON 8PV
3. Combination options of the circuit-breaker design
Busbar position rear (bottom), customer connection from the top
Busbar position rear (top), customer connection from the bottom
4. Combination options of the double-front switchboards
Busbar positions rear (bottom), customer connection from the top
Busbar positions rear (top), customer connection from the bottom
Installation rear side
3WL Size 1 3WL Size 2 3WL Size 3 1)
Cubicle width [mm] Cubicle width [mm] Cubicle width [mm]
Installation Cubicle width 400 500 600 500 600 600 600 800 600 600 800 800 1,000
front side [mm] Cubicle + + 300 + 200 + 400 + 200 + 400 + 200
cubicle extension
3WL Size 1 400
500
600 
500 + 300 
600 + 200 
600 + 400 
3WL Size 2 600 
800 
600 + 200 
2)
600 + 400 
800 + 200 
3WL Size 3 1) 800
Installation rear side
3WL Size 1 3WL Size 2 3WL Size 3 1)
Cubicle width [mm] Cubicle width [mm] Cubicle width [mm]
Installation Cubicle width 400 500 600 500 600 600 600 800 600 600 800 800 1,000
front side [mm] Cubicle + +300 +200 +400 +200 +400 +200
cubicle extension
3WL Size 1 400
500
600 
2)
500 + 300 
600 + 200
600 + 400 
3)
3WL Size 2 600 2) 5)
800
600 + 200 4) 6)
600 + 400 3) 3)
800 + 200
3WL Size 3 1) 800
Combination possible
1) Only combinable with empty cubicles
2) Not combinable with 3WL1220, 3WL1225, 3WL1232
Combination possible
1) Only combinable with empty cubicles
2) Not combinable with 3WL1220, 3WL1225, 3WL1232
3) Not combinable with 3WL1232
4) Not combinable with 3WL1208, 3WL1210, 3WL1212, 3WL1216,
3WL1232
5) Combinable 3WL1210 – 3WL1216 with 3WL1210 – 3WL1216
Combinable 3WL1220 – 3WL1225 with 3WL1220 – 3WL1225
Not combinable with 3WL1232
6) Combinable 3WL1210 – 3WL1216 with 3WL1210 – 3WL1225
Not combinable 3WL1220 – 3WL1225 with 3WL1220 – 3WL1225
Not combinable with 3WL1232
38.5
323
Cubicle depth – 100
Cubicle depth
400
25
215
75
Diameter 14.1
25
Approx. 700
38.5
323
Cubicle depth – 100
Cubicle depth
600
523
250
75
25
Diameter 14.1
25
Approx. 700
Free spaces for cable and busbar glands
Free spaces for cable entry in cubicles with cubicle
compartment at the right
38,5
Cubicle depth – 100
1,000
or
1,200
250
250
75
75
Cubicle
depth -77
Diameter 14.1
Approx. 700
Approx. 700
Cubicle depth
25 25
38.5
Cubicle depth – 100
Cubicle depth
1000
250
250
75
75
Cubicle
depth -77
25
Diameter 14.1
25
323
323
Approx. 700
Approx. 700
Floor openings
Cubicle depth 400 mm, 600 mm
38.5
400 600
Earthquake-resistant mounting
1,000
1,200 1,000
1 mm/m
1 mm/m
Mounting on raised floors / tolerance data
The foundation generally consists of concrete and a break-
through for cables.
The switch panels are mounted onto a foundation frame,
which is made of steel girders.
The dimensions refer to the rack dimensions.
Permissible deviations of the mounting surface
It must be assured that:
The foundation is accurately adjusted
The joints of several foundations are smooth
The surface of the frame lies on one level with the sur-
face of the completed floor
3_35
33
Cubicle depth 1,000 mm 1,200 m (standard version)
Cubicle depth 1,000 mm (earthquake-resistant version)
M10
Support, adjustable
Concrete floor
Box girder of
the foundation
Switchboard
Floor plate,
inserted
Contact washer
Tightening torque: approx. 60 Nm
Rack parts
Foundation frame
Hexagon nut
Hexagon nut M10
M10
1 Rack floor
2 Shim plate 4 mm thick (steel)
3 Floor edging 40 x 10 mm (steel)
4 Clamping washer DIN 6796-12-FST-MECH ZN
5 Cylinder-head screw M12x…-12.9-A3L
(… = length depending on the construction
of the foundation frame)
1
2
3
4
5
Screw
Screed Foundation frame
e.g. U-profile
DIN 1026
Heavy-duty
dowel
Washer
DIN 434
Concrete
floor
Shims
for adjustment
Washer
DIN 434
38 mm
The fixation with M10 on U-steels in accordance with DIN 1026 is
realized by means of washers in accordance with DIN 434. For these
U-steels, a minimum leg width of w = 38 mm is recommended for the
foundation frame. For sections with equal legs, a support width for
washers DIN 125 of 22 mm is sufficient.
3_36
SIVACON 8PV
Installation examples
Installation on false floors
(not permissible for earthquake-resistant version)
Fixation of the switchboard to the foundation
Earthquake-resistant installationFoundation frame fixation on concrete
w
d
Distribution board front
3_37
33
Inlet and connection to the SIVACON 8PS busbar-
trunking system
Busbar trunking connection for Siemens power distribu-
tion boards
Connection to the Siemens SIVACON 8PV power dis-
tribution board system as a type-tested low-voltage
switchgear and controlgear assembly (TTA)
in accordance with IEC / EN 60439-1 and -2
The connection of SIVACON 8PV and SIVACON 8PS busbar
trunking systems of the LD and LX series is realized via an
installed busbar trunking connector for rated currents up
to 5,000 A.
The busbar connection can both be routed from the top
as well as from the bottom and facilitates flexible wiring
options.
The factory-fitted copper plating between the point-to-
point and line trunking system guarantees a high short-
circuit strengths which is assured by means of a type test
and offers an enormous degree of safety for power trans-
mission.
Connection options
The connection system of the SIVACON 8PV is completely
accommodated in the distribution board.
For connection, special distribution terminal boxes with a
circumferential sheet collar of type LD/LX…-VEU-… are re-
quired.
Straight, angular and offset distribution terminal boxes are
available.
The connection system is flat-mounted in the
distribution board, seen from the distribution board’s
front.
SIVACON distribution board, top view
(The exact dimensions depend on the used busbar trunking system and
circuit-breakers are available upon request; for contact partners, please
consult the back of this manual)
Busbar trunking system
Connecting bolt
Busbar trunking connector
600
600
2000
1)
700700700700
Free minimum
passage 500 mm 1)
Escape direction
Minimum aisle width
700 or 600 mm
2)
3_38
SIVACON 8PV
Operating and maintenance gangways
(In accordance with DIN VDE 0100 Part 729)
Door width Reduction of aisle width
[mm] [mm]
400 350
500 440
600 520
800 700
1,000 870
With SIVACON, a reduction of the aisle width is not re-
quired if all doors can be arranged in a manner which as-
sures that they close towards the escape direction.
Maximum door widths depending on design
[mm]
Circuit-breaker design 1,000
Withdrawable design 600
Fixed-mounted design 1,000
Plug-in design 600
Transport units/transport packings
The maximum length of a transport unit amounts to:
2,400 mm for cubicles with top or rear busbar position
1,500 mm for power centers in general and 3WL as
longitudinal coupling
1,000 mm for power centers with 3WL as incoming
(or outgoing) feeder
The transport unit length + 200 mm (230 mm*)
amounts to the transport packing length
(at least 1,400 mm (1,430 mm*)).
The transport height amounts to 190 mm (350 mm).
The transport packing depth amounts to the following
With cubicle depth Transport packing depth
[mm] [mm]
400 900 (930*)
600 1,050 (1,060*)
1,000 1,460 (1,490*)
1,200 1,660 (1,690*)
* Bracket values = seaworthy packing
1) Minimum passage height beneath covers or casings
1) With opposing switchboard fronts, constriction by open doors
(i.e. doors which do not close towards the escape direction) is
only accounted for on one side
2) Door widths must be observed, i.e. a minimum door opening
angle of 90° is required
Door opening angle = 120°
Caution!
When using an elevating truck for the installation of cir-
cuit-breakers, the minimum aisle widths must be matched
to the elevating truck!
Manufacturer: e.g. Kaiser+Kraft
Elevating truck dimensions: Height 2,000 mm
Width 680 mm
Depth 920 mm
Minimum aisle width: Approx. 1,500 mm
Reduced aisle widths in the area of open doors
Management level
Field level
Actuator-
sensor level
Control level
PROFIBUS-DP
Actuator-sensor interface
1 2 3 4 … 31
30
32
12 3 4 … 31
30
32
12 3 4 … 31
30
32
12 3 4 … 31
30
32
123
2
122
R R R R
3_39
33
Modules for the application of SIVACON
SIMOCODE pro motor management
SENTRON 3WL and 3VL circuit-breakers
MICRO, MIDI and MASTER drives
ET 200 modules
PROFIMESS universal measuring device
AS-Interface components
Number of stations
PROFIBUS-DP Up to 127 addressable bus slaves
(5 of which are reserved)
SIMOCODE pro 30 stations per segment
AS-i Max. 31 slaves with maximally
4 inputs/4 outputs
Continuously increasing requirements placed upon
switchgear and controlgear in state-of-the-art,
high-performance automation concepts:
More sensors and actuators
Improved functionality within the switchgear and con-
trolgear
High degree of information demand
Minimum response times
Parameter settings – E.g. for remote
parameterization
Signaling information – ON, OFF, FAULT ...
Power management – Demand rate minimization
– Operating data recording
– Fault data evaluation
Cost reductions thanks to distributed plant
structures
Planning – Clear project structures
– Reduced space requirements
Configuration – Fewer clamping points
– Device-integrated functions
Mounting – Reduced wiring
– No terminal blocks
Commissioning – Pre-commissioning
“Change wiring” via software
– Fewer fault sources
Maintenance/service – Clear plant structure
– Faster fault diagnostics
Visualization – Illustration of operating states
Communication in Switchboards
Note:
One bus segment may contain up to 32 stations. Repeaters and bus
termination modules are not addressable, are, however, counted as
stations of the bus segment in accordance with the illustration.
R RR R
RS 485 repeater
Optical link module
Bus termination module
3_40
SIVACON 8PV
Possible variants of the PROFIBUS routing in SIVACON
PROFIBUS – Baud rate limitation (500 kBaud)
The total length of the stub lines in the communication
network (all bus stub lines inside the withdrawable units)
influences the transmission rate for the PROFIBUS commu-
nication. The permissible total length of such stub lines is
exceeded with a maximum segment utilization (30 sta-
tions) and can thus lead to communication faults.
The maximum transmission rate for the PROFIBUS commu-
nication is thus limited to 500 kBaud.
The application of 1.5 Mbaud is permissible in exceptional
cases only when complying with the following conditions:
Restriction of the slave number per segment to 10–15
stations (depending on withdrawable unit size)
No employment of devices with segment monitoring
functions (special OLMs and diagnostics repeaters)
Coordination of the bus and the communication struc-
ture with Siemens A&D CD DM TPM in Leipzig
New – Active stub line modules for connection of
MCC in withdrawable design to PROFIBUS-DP with
high speed up to 12 Mbit/s – New
High-speed communication
Low-disturbance connection of the functional units in
withdrawable design
Transmission rate up to 12 Mbit/s
Application of active stub lines ASLM-4 and ASLM-6
Module
The module is available in 2 variants:
ASLM-4 for the connection of 4 functional units
ASLM-6 for the connection of 6 functional units
Advantages
Transmission rates up to 12 Mbit/s
Increased bus quality and reliability
Retrofitting of functional units without bus interruption
Easy change of the slaves’ bus assignments by means of
re-plugging
High degree of cubicle assignment flexibility thanks to
the modules’ combination
3_41
33
Resistance to Internal Arcs
The testing of low-voltage switchboards under internal arc
conditions is considered a special test in accordance with
IEC 61641 and VDE 0660 Part 500, Supplement 2.
With this test, the danger to which persons may be sub-
jected in cases of internal arcs are assessed.
Thanks to its testing under internal arc conditions,
SIVACON offers the proof of operator safety with the be-
low-stated assessment criteria as a standard.
Assessment criteria
1. Properly secured doors, covers, etc., must not open.
2. Parts which may pose risks must not fly off.
3. No holes must form in the freely accessible outer parts
of the enclosure (casing).
4. No vertically attached indicators must inflame.
5. The protective conductor circuit for touchable parts of
the enclosure must remain functioning.
Grading for fault limitation
The top priority is the attempt to prevent the formation of
internal arcs completely. All quality assurance measures
serve this attempt. These measures start with the develop-
ment of the system components, which is accompanied by
numerous type tests, and furthermore comprise the switch-
boards’ correct configuration following order placement as
well as routine tests in our production units. A clearly de-
fined module structure and DP-supported configuration, or-
dering and handling procedures form the basis for configu-
ration.
For SIVACON, a graded concept was developed by
Siemens. Step 1 starts with a very high degree of operator
safety without an extensive limitation of the internal arc
effects within the system. Step 2 furthermore limits the
damage to the system’s cubicle. In the third and fourth
step, the effects on the function compartment or the in-
ternal arc's point of origin are limited, for example, to the
busbar compartment, device compartment, withdrawable
unit or connection compartment.
This facilitates the system's flexible and cost-effective ad-
justment to the actual requirements of the operator.
Load profile of SIVACON
Rated operational voltage Up to 690 V + 5%
Impulse current 110 kA/143 kA
Symmetrical short-circuit current 50 kA/ 65 kA
Permissible arcing time bis 300 ms
SIVACON internal arc concept
Step 1 (standard)
Operator safety without an extensive limitation of the in-
ternal arc's effects within the system
Molded-plastic covers in the termination walls
Pressure-relief flaps in the roof sheeting with non-venti-
lated systems
Spring-loaded locking device
50 kA/300 ms; 65 kA/300 ms with additional measures
Step 2
Operator safety with limitation of the internal arc’s effects
on a cubicle
Molded-plastic covers in the termination walls
Pressure-relief flaps in the roof sheeting with non-venti-
lated systems
Spring-loaded locking device
Light barriers (2 items/cubicle)
50 kA / 300 ms; 65 kA/300 ms with additional measures
Step 3 (fixed-mounted and withdrawable design)
Operator safety with limitation of the internal arc’s effects
on the function compartment
Molded-plastic covers in the termination walls
Pressure-relief flaps in the roof sheeting with non-venti-
lated systems
Spring-loaded locking device
Light barriers (2 items/cubicle)
Light barriers between the device compartment and the
busbar compartment
50 kA/300 ms; 65 kA/300 ms with additional measures
Step 4 (withdrawable design)
Operator safety with limitation of the internal arc’s effects
on the point of origin
Molded-plastic covers in the termination walls
Pressure-relief flaps in the roof sheeting with non-venti-
lated systems
Spring-loaded locking device
Light barriers (2 items / cubicle)
Light barriers between the device compartment and the
busbar compartment
Plug-in busbar covers
Withdrawable contact covers (only NFM withdrawable
unit)
With the additional measures, an inflammation of the inter-
nal arc upstream the protective organ is practically excluded.
Insulated main busbar
Busbars wrapped with protective tape, additionally ap-
plicable with all above-stated steps
Project name:
Client:
Planner:
Mounting location/altitude: m (above seal level NN)
Mounting type: Single-front Double-front
Ambient temperature: °C
Degree of protection: IP Internal separation: Type
Maximum possible distribution board dimensions: B x H x T mm Room height: mm
Maximum transport dimensions: B x H x T mm
Network type: TN-S TN-C TN-C-S TT IT
Cross-section PEN/N: IEC Half Full
Number of transformers: Items
Transformer power (per transformer): kVA
Rated infeed current: A
Frequency: Hz
Rated operational voltage: V
Rated short-time withstand current Icw (1 sec)
of the main busbar kAeff
Connection with: Conductor bars Cables
Inlet of bars/cables: Top Bottom Top/bottom
Internal arc protection (refer to page 36): Step 1 Step 2 Step 3 Step 4
Mounting designs: Incoming feeders: Fixed-mounted design Withdrawable design
Outgoing feeders ≥ 630 A: Fixed-mounted design Withdrawable design
Couplings: Fixed-mounted design Withdrawable design
Outgoing feeders < 630 A: Fixed-mounted design Plug-in design Withdrawable design
Outgoing feeder design < 630 A: Fuseless Fused
Further information:
3_42
SIVACON 8PV
Checklist for Planners
Symbol definition:
Functional unit(s),
including connection points for
the connection of external
conductors
Enclosure
Busbars,
including distribution busbars
Internal separation
Type 2a
No separation
between connections
and busbars
Type 2b
Separation
between connections
and busbars
Type 3a
No separation
between connections
and busbars
Form 4a
Connections in the same
separation as the connected
functional unit
Type 3b
Separation
between connections
and busbars
Form 4b
Connections not in the same
separation as the connected
functional unit
3_43
33
Depending on the respective requirements, the function compartments can be categorized in accordance with the following table:
Type 1 Type 2a Type 2b Type 3a Type 3b Type 4a Type 4b
Circuit-breaker design ACB 
MCCB 
DUMECO 
EFEN 
Fixed-mounted design Modular 
Compensation
Plug-in design In-line 
Plug-In
Withdrawable design 
Types of Internal Separation
(Types 1 to 4)
Protection objectives according to VDE 0660
Part 500, 7.7:
Protection against contact with hazardous parts in adjacent func-
tional units. The degree of protection must be at least IPXXB.
Protection against the intrusion of solid alien bodies
from one functional unit of the switchgear and control-
gear assembly to an adjacent one. The degree of protec-
tion must be at least IP2X
Type 1
No internal separation
Type 3
Separation between the busbars and the functional units +
separation between the functional units themselves +
separation between connections and the functional units
Form 4
Separation between the busbars and the functional units +
separation between the functional units themselves +
separation between connections of functional units
Type 2
Separation between busbars and functional units
3_44
SIVACON 8PV
TTA – PTTA
The application of other switchgear and controlgear and pro-
tective devices is only permissible if their technical data are
at least identical or better (conclusion by analogy).
Partially type-tested assembly (PTTA)
These assemblies contain both type-tested as well as non-
type-tested components. Non-type-tested components
must be derived from type-tested components.
With type-tested assemblies, all proofs must be
established by means of tests.
With partially type-tested assemblies, two exceptions are
permissible (refer to the table):
1. Proof of compliance with the limit overtemperatures.
With switchboards with a supply current strength up to
max. 3,150 A, the proof can also be provided by means
of extrapolation.
2. The short-circuit strength proof is not required for
switchboards which are protected by a current-limiting
protective organ whose let-through current amounts to
≤ 15 kA.
If an extrapolation or calculation in accordance with DIN
VDE 0660 Part 500, is required, this must always be based
on a derivation of type-tested systems.
Only if all required proofs could be clearly established,
may switchgear and controlgear assemblies be desig-
nated as type-tested switchgear and controlgear as-
semblies (TTA) or partially type-tested switchgear and
controlgear assemblies (PTTA). These combinations
thus comply with the applicable safety regulations.
The safety standard for low-voltage switchgear
and controlgear assemblies
The requirements placed upon low-voltage switchboards
with regard to heat dissipation, high packing density,
short-circuit current capacity and insulation resistance
have increased over the past years.
The safe operation of a low-voltage switchboard can only
be assured if the manufacturer complies with the stan-
dards applicable to the respective switchgear and control-
gear assembly and is able to prove such compliance.
Only switchboards which correspond to the currently appli-
cable standards comply with the present safety regulations.
Applicable standards are:
IEC/EN 60439-1, VDE 0660 Part 500
Low-voltage switchgear and controlgear assemblies
Type-tested and partially type-tested assemblies
These standards have identical contents. They show
two possibilities in accordance to which low-voltage
switchboards may be manufactured:
Type-tested switchgear and controlgear assembly (TTA)
Partially type-tested switchgear and controlgear assem-
bly (PTTA)
Type-tested assembly (TTA)
In these assemblies, all components have been type-tested
both individually as well as in the assembled form, includ-
ing all electrical and mechanical connections.
Required proofs for compliance with the standards
Requirements TTA proof PTTA proof
established by established by
1. Limit overtemperature Test Test or
extrapolation
2. Insulation resistance Test Test
3. Short-circuit strength Test Test or
extrapolation
4. PE conductor effectiveness Test Test
5. Creepage distances and clearances Test Test
6. Mechanical function Test Test
7. IP degree of protection Test Test
3_45
33
Checklist for Low-Voltage Switchgear
and Controlgear Assemblies
Checklist for TTA
For low-voltage switchgear and controlgear assemblies,
IEC/EN 60439-1, IEC/EN 60439-2 and IEC/EN 60439-3,
DIN VDE 0660, Parts 500, 502 and 504
Legend:
S = Visual inspection for compliance with requirements
P = Inspection – manually or with electronic or mechanical measuring devices
V = Comparison with production documents
Special application conditions in accordance
with ..................................................
Routine tests
Seq. Test Test VDE 0660 Result Inspector
No. type Part 500
Section
1 Type test 8.2.1 – Passed
8.2.7
2P Mechanical function test 8.3.1
(actuating elements, interlockings, etc.)
3S Device installation according to regulations
4S Impeccable line routing
5S/P Degree of protection of enclosure
6S/P Creepage distances, clearances and other distances
7P Connection of construction parts as well as conductors
among each other and with devices (random test of
tightening torques)
8.1 P/V Compliance of the wiring with the circuit
documents
8.2 V Compliance of
identification, inscriptions,
completeness of the AWAs, etc.,
with the circuit documents and other documents
9P Insulation test 8.3.2
10 S/P Protective measures and consistent 8.3.3
protective conductor connection
11 P Electrical function test 8.3.1
(if explicitly specified)
Routine tests
3_46
SIVACON 8PV
Checklist for PTTA
For low-voltage switchgear and controlgear assemblies,
IEC/EN 60439-1, IEC/EN 60439-2 and IEC 60890 (HD528
S1), DIN VDE 0660, Parts 500, 502 and 507
Special application conditions in accordance
with ..................................................
Proofs/tests
Seq. Requirement VDE 0660 Proof Result Inspector
No. Part 500
Section
1Limit overtemperature 8.2.1 Proof of compliance with the
limit overtemperature by
means of test, extrapolation of
TTA or determination in acc.
with VDE 0660 Part 507
2Insulation resistance 8.2.2 Refer to seq. No. 10
3Short-circuit strength 8.2.3 Proof of the short-circuit
strength by means of test or
extrapolation of similar type-
tested arrangements
4Effectiveness of the PE 8.2.4
conductor circuit
Impeccable connection between 8.2.4.1
elements of the switchgear and
controlgear assembly and the PE
conductor circuit 8.2.4.1
Short-circuit strength of 8.2.4.2 Proof of the PE conductor’s
the PE conductor circuit short-circuit strength by means
of test or respective design and
arrangement of the PE
conductor (refer to Section
7.4.3.1.1 of VDE 0660 Part
500)
5Creepage distances and clearances 8.2.5 Proof of the creepage
distances and clearances
6Mechanical function 8.2.6 Proof of the mechanical
function
7IP degrees of protection 8.2.7
Proof of the IP degree of protection
8EMC 8.3.8 Proof of the EMC compatibility
by compliance with
requirements 7.10.2 a)
and b)
Proof
Proof of the impeccable
connection between elements
of the switchgear and control-
gear assembly and the PE con-
ductor
3_47
33
Test list for PTTA (continued)
Seq. Test Test VDE 0660 Result Inspector
No. type Part 500
Section
9.1 P Mechanical function test 8.3.1
(actuating elements, interlockings, etc.)
9.2 S Device installation according to regulations
9.3 S Impeccable line routing
9.4 S/P Degree of protection of enclosure
9.5 S/P Creepage distances, clearances and other distances
9.6 P Connection of construction parts as well as conductors among
each other and with devices
(random test of tightening torques)
9.7 P/V Compliance of the wiring with the circuit
documents
9.8 V Compliance of
identification, inscriptions,
completeness of the AWAs, etc.,
with the circuit documents and other documents
9.9 P Electronic function test
(if explicitly specified)
(agreements user/manufacturer, FO322)
10 P Insulation test 8.3.2
or 8.3.4
proof of the insulation resistance’s insulation strength
11 S/P Protective measures and consistent 8.3.3
protective conductor connection
Routine tests
Legend:
V = Visual inspection for compliance with requirements
I = Inspection – manually or with electronic or mechanical measuring devices
C = Comparison with production documents
Environmental conditions in switchboard rooms Switchboard measures
Room climate in Ambient Condensation Natural foreign Heat- Degree of Degree of Contact treatment
acc. with temperature matters, ing protection protection
IEC 60721-3-3 chemical to the to the cable Screw Movable
with direct Relative harmful operating gallery connec- contacts
influence on the air humidity substances, room tions
switchboard small animals
Environmental +5 to +40°C None None IP20/40
class IR1 [3K3] 5% to 85%
24-h average
max. 35°C
Environmental –25 to +55°C Occasionally, None IP20/40
class IR2 [3K6] 10% to 98% approx. once
24-h average per month for Airborne sand IP54
max. 50°C 2 hours
Small animals IP40 IP40
Environmental –25 to +55°C Frequently, None IP20/40
class IR3 [3K6] 10% to 98% approx. once
24-h average per day for Airborne sand IP54
max. 50°C 2 hours
Dripping water IP41
in acc. with
IEC 60529
Airborne sand, IP54
dust and splash
water in acc
with IEC 60529
Small animals IP40 IP40
3_48
SIVACON 8PV
Environmental class IR 2 (indoor room 2):
Indoor rooms in buildings with minor heat insulation or a
low heat capacity, heated or cooled, without temperature
monitoring. The heating or cooling may fail for several
days, e.g. unattended relay, amplifying and transformer
stations, stables, motor vehicle repair shops, fabrication
rooms for unfinished goods, hangars.
Environmental class IR 3 (indoor room 3):
Indoor rooms in buildings without noteworthy heat insula-
tion and a low heat capacity, neither heated nor cooled,
also in warm and humid areas, e.g. workshops, telephone
booths, building entrances, barns, attics, unheated stor-
age rooms, sheds, garages, network stations.
Environmental conditions for switchboards
The outside climate and the external environmental condi-
tions (natural foreign matters, chemical active harmful
substances, small animals) may have varyingly strong in-
fluences on switchboards. The influence depends on the
air-conditioning equipment of the switchboard room.
Necessary additional protective measures for the switch-
board therefore depend on the resulting indoor room cli-
mates, which are divided into three environmental classes:
Environmental class IR 1 (indoor room 1):
Indoor rooms in buildings with a sound heat insulation
or a high heat capacity, heated or cooled, normally only
subjected to temperature monitoring, e.g. normal residen-
tial rooms, offices, shops, transmission and switching cen-
ters, storage rooms for sensitive goods.
Environmental Conditions/
Degrees of Protection
3_49
33
Areas with chemical emission
Permanently permissible concentration Measures in cases of higher concentrations:
Sulfur dioxide < 2 ppm
(SO2)
Hydrogen sulfide < 1 ppm
(H2S)
Hydrogen chloride < 3 ppm
(HCl)
Amonia < 15 ppm
(NH3)
Nitrogen oxides < 2 ppm
(NO2)
Chloride exposure C1 < 2 mg / dm2
(salt fog)
With higher concentrations, measures to reduce the content of
harmful substances must be taken, e.g.
Suction of the air for the operating from a point with low expo-
sure
Application of slight overpressure to the operating room
(e.g. supply of clean air to the switchboard)
Switchroom climatization (temperature reduction, relative air
humidity < 60%, if required, application of filters for harmful
substances)
Reduction of temperature rise (overdimensioning of switchgear
and controlgear or components such as busbars and distribution
busbars)
3_50
SIVACON 8PV
TN-S system
The neutral conductor and protective
conductor function are consistently
separated in the system.
TN-C system
The neutral conductor and protective
conductor function go together
throughout the entire system.
TN-C-S system
Combination between the neutral and
the protective conductor function. In
one part of the system, they are com-
posite in one conductor, while they
are separated in another part.
1 Body
2 Impedance
Distribution systems (network types)
in accordance with 60364-3 (DIN VDE 0100-300)
Determination of protective measures and selection of the
electrical operating equipment according to the distribu-
tion system.
TN Systems
Network Systems
TT system
In the TT system, one point is directly
grounded; the elements of the electri-
cal system are connected to ground
electrodes which are separated from
the signal ground. The TT system cor-
responds to the system in which today
the protective grounding, current-ope-
rated ground fault circuit interrupter
system, voltage-operated ground fault
circuit interrupter system and protec-
tive measures are applied.
IT system
The IT system features no direct
connection between active conductors
and grounded parts; the elements of
the electrical system are grounded.
The IT system corresponds to the sy-
stem in which today the protective
conductor system protective measure
is applied.
L1
N
L2
L3
PE
1
L1
L2
L3
PEN
1
L1
N
L2
L3
1
PE
L1
L2
L3
1
PE
2
L1
PEN
L2
L3
1
PEN
N
First letter = grounding condition of the supplying current
source
T = Direct grounding of one point
I = Either insulation of all active parts of the ground or
connection of one point to the ground via an impedance
Second letter = grounding condition of the elements of the
electrical system
T = Elements are directly grounded, irrespective of a possible
grounding of one point of the current supply
N= Elements are directly connected to the signal ground; in
AC current networks, the grounded point is generally the
star point
Further letters = Arrangement of the neutral and the protective
conductor
S = Neutral and protective conductor function by means of
separated conductors
C = Neutral and protective conductor function combined in
one conductor (PEN)
L1
L2
L3
PEN
PE
L1
L2
PEN
PE
L3
L1
L2
PEN
PE
L3
L1
L2
L3
PEN
PE
Haupterdungsschiene Zentrale Erdver-
bindungsstelle
des Systems
Schutzerdung
Der PEN-Leiter muss in seinem gesamten
Verlauf isoliert verlegt werden, auch in den
Schaltgerätekombinationen!
150 Hz
Drossel
L1
L2
L3
L1
L2
L3
The PEN conductor must be routed in an insu-
lated manner throughout its entire length, also
in the switchgear and controlgear assembly!
Protective grounding
Central ground
connection
point of the
system
Main grounding bar
150 Hz
Throttle
3_51
33
Example of an electronically compatible TN-S system
3_52
SIVACON 8PV
Rated impulse withstand voltage (Uimp)
IEC/ EN 60947-1; 4.3.1.3
Parameter for the resistance of clearances inside
switchgear and controlgear to impulse overvoltages. The
application of suitable switchgear and controlgear pre-
vents disconnected system parts from transmitting over-
voltages from the network in which they are applied.
Rated current (In) (of circuit-breakers)
IEC/ EN 60947-2; 4.3.2.3
Current which, for circuit-breakers, corresponds to the
rated continuous current and the conventional thermal
current.
Rated continuous current
Rated control voltage (Uc)
IEC/ EN 60947-1; 4.5.1
Voltage applied to the actuating NO contact of a control
circuit. It may deviate from the rated control supply volt-
age if transformers or resistors are connected to the con-
trol circuit.
Rated ultimate short-circuit breaking capacity (Icu)
IEC/ EN 60947-2; 4.3.5.2.1
Maximum short-circuit current which can be interrupted
by a circuit-breaker (test O – CO). After a short-circuit re-
lease, the circuit-breaker is able to trip with increased tol-
erances in the case of overload.
Rated service short-circuit breaking capacity (Ics)
IEC/ EN 60947-2; 4.3.5.2.2
The short-circuit current depending on the rated opera-
tional voltage which can be repeatedly interrupted by a
circuit-breaker (test O – CO – CO).
After the short-circuit breaking, the circuit-breaker is able
to continue to carry the rated current in the case of in-
creased self-heating or overload.
Rated continuous current
Rated operational voltage
Rated Values / Definitions
Rated values
In accordance with IEC/EN 60439-1, the manufacturers of
low-voltage switchgear and controlgear assemblies state
rated values. These rated values apply to the specified op-
erating conditions and characterize the usability of
switchgear and controlgear assemblies. The coordination
of the operating equipment or the configuration of the
switchgear and controlgear assemblies must be based on
these rated values.
Rated short-time withstand current (Icw)
IEC/ EN 60439-1; 4.3
As the effective short-circuit current value, the rated short-
time withstand current characterizes the thermal strength
of switchgear and controlgear assembly circuits during a
short-time load. The rated short-time withstand current is
normally determined for the duration of 1 s; deviating
time values must be stated.
The rated short-time withstand current is stated for the
distribution and/or main busbars of switchgear and con-
trolgear assemblies.
Rated peak withstand current (Ipk)
IEC/ EN 60439-1; 4.4
As peak value of the peak current, the rated peak with-
stand current characterizes the dynamic strength of
switchgear and controlgear assembly circuits. The rated
peak withstand current is normally stated for the distribu-
tion and/or main busbars of switchgear and controlgear
assemblies.
Rated conditional short-circuit current (Icc)
IEC/ EN 60439-1; 4.5
The rated conditional short-circuit current corresponds to
the uninfluenced short-circuit current which switchgear
and controlgear assembly circuits that are protected by
short-circuit protective devices may carry without damage
(for a limited time). The rated conditional short-circuit cur-
rent is therefore stated for outgoing and/or incoming feed-
ers, e.g. with circuit-breakers.
3_53
33
Rated operating capacity
IEC/ EN 60947-1; 4.3.2.3
Capacity which can be switched by switchgear and con-
trolgear with the assigned rated operational voltage in ac-
cordance with the utilization category, e.g. power contac-
tor of utilization category AC-3: 37 kW at 400 V.
Rated operational voltage (Ue)
IEC/ EN 60947-1; 4.3.1.1
Voltage to which the characteristic values of switchgear
and controlgear are referred to. The maximum rated oper-
ational voltage must, in no case, exceed the rated insula-
tion voltage.
Rated insulation voltage
Rated operational current (Ie)
IEC/ EN 60947-1; 4.3.2.3
Current which can be carried by switchgear and control-
gear in consideration of the rated operational voltage, the
operating time, the utilization category and the ambient
temperature.
Rated operational voltage
Rated continuous current (Iu)
IEC/ EN 60947-1; 4.3.2.4
Current which can be carried by switchgear and control-
gear in continuous operation (for weeks, months or
years).
Rated making capacity
IEC/ EN 60947-1; 4.3.5.2
Current which can be switched on by switchgear and con-
trolgear with the respective rated operational voltage in
accordance with the utilization category.
Rated operational voltage
Rated frequency
IEC/ EN 60947-1; 4.3.3
Frequency for which switchgear and controlgear is dimen-
sioned and to which the other characteristic data refer.
Rated operational voltage
Rated continuous current
Rated insulation voltage (Ui)
IEC/ EN 60947-1; 4.3.1.2
Voltage to which the insulation tests and creepage dis-
tances refer. The maximum rated operational voltage
must, in no case, exceed the rated insulation voltage.
Rated operational voltage
Rated short-circuit breaking capacity (Icn)
IEC/ EN 60947-1; 4.3.6.3
Maximum current which can be switched off by
switchgear and controlgear with the rated operational
voltage and frequency without causing damage. The value
is stated as effective value.
Rated operational voltage
Rated short-circuit making capacity (Icm)
IEC/ EN 60947-1; 4.3.6.2
Maximum current which can be switched on by switchgear
and controlgear with the rated operational voltage and
frequency without causing damage. Deviating from the
other characteristic data, the value is stated as peak value.
Rated operational voltage
Rated short-circuit current, conditional
IEC/ EN 60947-1; 2.5.29
Rated conditional short-circuit current (Iq)
Operating position
Position of a removable part or withdrawable unit in which
such part or unit is fully connected for the intended func-
tion.
Test position
Position of a withdrawable unit in which the respective
main circuits are open on the supply side, while the re-
quirements placed upon an isolating distance need not be
met, and in which the auxiliary circuits are connected in a
way which assures that the withdrawable unit undergoes
a function test while it remains mechanically connected to
the switchgear and controlgear assembly.
Note: The opening may also be established by operating a
suitable device without the withdrawable unit being me-
chanically moved.
Disconnected position
Position of a withdrawable unit in which the isolating dis-
tances in the main and auxiliary circuits are open while it
remains mechanically connected to the switchgear and
controlgear assembly.
Note: The isolating distance may also be established by
operating a suitable device without the withdrawable unit
being mechanically moved.
Removed position
Position of a removable part or withdrawable unit which
has been removed from the switchgear and controlgear
assembly and is mechanically and electrically disconnected
from the assembly.
Rack
Component of a switchgear and controlgear assembly
which serves the carrying of various components of a
switchgear and controlgear assembly or of an enclosure.
Enclosure
Part which protects the operating equipment against ex-
ternal influences and offers protection against direct con-
tact from every direction with a minimum degree of pro-
tection of IP2X.
3_54
SIVACON 8PV
Definitions
The terms defined below are used in the present catalog in
accordance with VDE 0660 Part 500 and IEC 60439-1.
Low-voltage switchgear and controlgear assembly
Assembly of one or more switchgear and controlgear units
combined with corresponding operating equipment for
control, measuring and signaling tasks and with protective
and control devices, etc. The individual devices are com-
pletely assembled by the manufacturer, including all inter-
nal electrical and mechanical connections and construc-
tion components.
Type-tested low-voltage switchgear and controlgear
assembly (TTA)
Low-voltage switchgear and controlgear assembly which
complies with the original type or system of the type-
tested switchgear and controlgear assembly type-tested in
accordance with this standard without significant devia-
tions.
Functional unit
Part of a switchgear and controlgear assembly with all
electrical and mechanical components which contribute to
the execution of the same function.
Removable part
Part which may be removed in whole from the switchgear
and controlgear assembly for replacement, even when the
connected circuit is energized.
Withdrawable unit
Removable part which can be installed in a position in
which an isolating distance is open while it remains me-
chanically connected to the switchgear and controlgear
assembly.
Note: This isolating distance must lie in the main circuits
only or in the main and auxiliary circuits.
Non-drawout assembly
Assembly of operating equipment which is assembled and
wired on a joint supporting structure for permanent instal-
lation.
3_55
33
Cubicle
Component of a switchgear and controlgear assembly po-
sitioned between two successive vertical limiting levels.
Cubicle panel
Component of a switchgear and controlgear assembly po-
sitioned between two superimposed horizontal limiting
levels inside a cubicle.
Compartment
Cubicle or cubicle panel which is encased with the excep-
tion of openings required for connection, control or venti-
lation.
Transport unit
Part of a switchgear and controlgear assembly or complete
switchgear and controlgear assembly which is not disas-
sembled for transportation.
Rated diversity factor
The rated diversity factor of a switchgear and controlgear
assembly or of a component of a switchgear and control-
gear assembly (e.g. cubicle, cubicle panel) which com-
prises several main circuits is the ratio of the largest sum
of all currents which are to be expected in the respective
main circuits at any given time to the sum of the rated cur-
rents of all main circuits of the switchgear and controlgear
assembly or of the affected part of the switchgear and
controlgear assembly. If the manufacturer states a rated
diversity factor, this value must be taken as a basis for the
temperature-rise test.
Number of main Rated diversity
circuits factor
2 and 3 0.9
4 and 5 0.8
6 up to and including 9 0.7
10 and more 0.6
3_56
SIVACON 8PV
Rated Currents and Initial Symmetrical Short-Circuit Currents of
Three-Phase Distribution Transformers from 50 to 3,150 kVA
Rated 400/230 V, 50 Hz 525 V, 50 Hz 690/400 V, 50 Hz
voltage UrT
Rated value of 4% 1) 6% 2) 4% 1) 6% 2) 4% 1) 6% 2)
the short-circuit
voltage ukr
Rated power Rated Initial symmetrical Rated Initial symmetrical Rated Initial symmetrical
current short-circuit current Ik 3) current short-circuit current Ik 3) current
short-circuit current
Ik 3)
IrIrIr
[kVA] [A] [A] [A] [A] [A] [A] [A] [A] [A]
50 72 1,933 1,306 55 1,473 995 42 1,116 754
100 144 3,871 2,612 110 2,950 1,990 84 2,235 1,508
160 230 6,209 4,192 176 4,731 3,194 133 3,585 2,420
200 288 7,749 5,239 220 5,904 3,992 167 4,474 3,025
250 360 9,716 6,552 275 7,402 4,992 209 5,609 3,783
315 455 12,247 8,259 346 9,331 6,292 262 7,071 4,768
400 578 15,506 10,492 440 11,814 7,994 335 8,953 6,058
500 722 19,438 12,020 550 14,810 9,158 418 11,223 6,939
630 910 24,503 16,193 693 18,669 12,338 525 14,147 9,349
800 1,154 20,992 880 15,994 670 12,120
1,000 1,444 26,224 1,100 19,980 836 15,140
1,250 1,805 32,791 1,375 24,984 1,046 18,932
1,600 2,310 39,818 1,760 30,338 1,330 22,989
2,000 2,887 52,511 2,200 40,008 1,674 30,317
2,500 3,608 65,547 2,749 49,941 2,090 37,844
3,150 4,550 82,656 3,470 62,976 2,640 47,722
1) ukr = 4%, standardized in accordance with DIN 42503 for SrT = 50 ... 630 kVA
2) ukr = 6%, standardized in accordance with DIN 42511 for SrT = 100 ... 1600 kVA
3) IkUninfluenced initial symmetrical transformer short-circuit current when connected to a network with unlimited short-circuit
power in consideration of the voltage and correction factor of the transformer impedance in accordance with
DIN EN 60909/DIN VDE 0102 (July 2002)
Approximation formula
Rated transformer current Transformer short-circuit symmetrical current
IN[A] = k x SNT [kVA] I"k= IN/ukx 100 [A] 400 V: k = 1.45
690 V: k = 0.84
Power losses
The power loss data stated below are approximate values for
a cubicle with the main circuit of functional units for the de-
termination of the power loss to be dissipated from the
switchroom. Power losses of possibly installed additional
auxiliary devices must also be taken into consideration.
Circuit-breaker design with Approx. Pv[W] at % of
3WL (withdrawable unit) rated current
[A] At 100% At 80%
630 BG. I 270 180
800 BG. I 440 280
1,000 BG. I 690 440
1,250 BG. I 740 470
1,600 BG. I 830 530
2,000 BG. II 1,080 690
2,500 BG. II 1,700 1,090
3,200 BG. II 2,650 1,690
4,000 BG. III 3,100 1,980
5,000 BG. III 4,630 2,960
6,300 BG. III 7,280 4,660
Power loss per cubicle
[V]
Withdrawable design Approx. Pv= 600
Fixed-mounted design Approx. Pv= 600
Plug-in design Approx. Pv= 600
In-line design Approx. Pv = 1500
Compensation 500 kvar Approx. Pv= 600
non-throttled
Compensation 250 kvar Approx. Pv= 1350
throttled
Average cubicle weight
including busbar (without cable)
Cubicle dimensions
Height Width Depth Remarks Nominal Weight
[mm] [mm] [mm] current [A] approx. kg
Circuit-breaker cubicles
2,200 400 400 630 – 1,600 287
500 630 – 1,600 297
600 2,000 – 2,500 405
400 600 630 – 1,600 305
500 630 – 1,600 325
600 630 – 1,600 335
800 630 – 1,600 365
600 2,000 – 2,500 440
800 2,000 – 2,500 475
800 3,200 540
1,000 4,000 700
1,000 1,200 5,000, 6,300 1,200
Fixed-mounted cubicles
2,200 800 400 Universal fixed- 300
1,000 mounted design 320
800 600 Universal fixed- 360
1,000 mounted design 380
800 1,000 Universal fixed- 520
1,000 mounted design 550
Withdrawable unit cubicles/plug-in design
2,200 1,000 400 420
600 480
1,000 690
Compensation cubicles
2200 800 600 500 kvar 320
non-throttled
2200 800 600 250 kvar 440
throttled
3_57
33
Weights / Power Losses
3_58
SIVACON 8PV
Reactive Power Compensation
Calculative determination and specification of the
required capacitor power
1. The electricity bill of the power supply company shows
the consumption of active power in kWh and of reac-
tive power in kvarh; the power supply company de-
mands a cos ϕof 0.9 ... 0.95; the reactive power de-
mand should be compensated to a value approximat-
ing cos ϕ= 1 for cost optimization.
Determination of tan ϕ1= Reactive power = kvarh
Active power kWh
2. The table shows conversion factor “F”, which must be
multiplied with the average power consumption Pm.
With tan ϕ1cos ϕ1shows the power factor prior to
compensation, while cos ϕ2shows the desired power
factor for compensation with factor “F”.
3. The required compensation power is stated in kvar.
Example:
Reactive power Wr= 19,000 kvar/month
Active power Wa= 16,660 kWh/month
Average power consumption
Active power =16,660 kWh = 92.6 kW
Operating time 180 h
tan ϕ1= Active power = 19,000 kWh = 1.14
Operating time 16,660 kWh
Power factor cos ϕ1= 0.66 (with tan ϕ1= 1.14)
Power factor cos ϕ2= 0.95 (desired)
Conversion factor “F” = 0.81 (from tan ϕ1and cos ϕ2)
Compensation power = Average power x factor “F”
= 92.6 kW x 0.81
Required compensation power: 75 kvar
Table for the determination of the required compensation power
Actual value (to) Conversion factor “F”
tan ϕ1cos ϕ1cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2cos ϕ2
= 0.70 = 0.75 = 0.80 = 0.82 = 0.85 = 0.87 = 0.90 = 0.92 = 0.95 = 0.97 = 1.00
4.90 0.20 3.88 4.02 4.15 4.20 4.28 4.33 4.41 4.47 4.57 4.65 4.90
3.87 0.25 2.85 2.99 3.12 3.17 3.25 3.31 3.39 3.45 3.54 3.62 3.87
3.18 0.30 2.16 2.30 2.43 2.48 2.56 2.61 2.70 2.75 2.85 2.93 3.18
2.68 0.35 1.66 1.79 1.93 1.98 2.06 2.11 2.19 2.25 2.35 2.43 2.68
2.29 0.40 1.27 1.41 1.54 1.59 1.67 1.72 1.81 1.87 1.96 2.04 2.29
2.16 0.42 1.14 1.28 1.41 1.46 1.54 1.59 1.68 1.74 1.83 1.91 2.16
2.04 0.44 1.02 1.16 1.29 1.34 1.42 1.47 1.56 1.62 1.71 1.79 2.04
1.93 0.46 0.91 1.05 1.18 1.23 1.31 1.36 1.45 1.50 1.60 1.68 1.93
1.83 0.48 0.81 0.95 1.08 1.13 1.21 1.26 1.34 1.40 1.50 1.58 1.83
1.73 0.50 0.71 0.85 0.98 1.03 1.11 1.17 1.25 1.31 1.40 1.48 1.73
1.64 0.52 0.62 0.76 0.89 0.94 1.02 1.08 1.16 1.22 1.31 1.39 1.64
1.56 0.54 0.54 0.68 0.81 0.86 0.94 0.99 1.07 1.13 1.23 1.31 1.56
1.48 0.56 0.46 0.60 0.73 0.78 0.86 0.91 1.00 1.05 1.15 1.23 1.48
1.40 0.58 0.38 0.52 0.65 0.71 0.78 0.84 0.92 0.98 1.08 1.15 1.40
1.33 0.60 0.31 0.45 0.58 0.64 0.71 0.77 0.85 0.91 1.00 1.08 1.33
1.27 0.62 0.25 0.38 0.52 0.57 0.65 0.70 0.78 0.84 0.94 1.01 1.27
1.20 0.64 0.18 0.32 0.45 0.50 0.58 0.63 0.72 0.77 0.87 0.95 1.20
1.14 0.66 0.12 0.26 0.39 0.44 0.52 0.57 0.65 0.71 0.81 0.89 1.14
1.08 0.68 0.06 0.20 0.33 0.38 0.46 0.51 0.59 0.65 0.75 0.83 1.08
1.02 0.70 0.14 0.27 0.32 0.40 0.45 0.54 0.59 0.69 0.77 1.02
0.96 0.72 0.08 0.21 0.27 0.34 0.40 0.48 0.54 0.63 0.71 0.96
0.91 0.74 0.03 0.16 0.21 0.29 0.34 0.42 0.48 0.58 0.66 0.91
0.86 0.76 0.11 0.16 0.24 0.29 0.37 0.43 0.53 0.60 0.86
0.80 0.78 0.05 0.10 0.18 0.24 0.32 0.38 0.47 0.55 0.80
0.75 0.80 0.05 0.13 0.18 0.27 0.32 0.42 0.50 0.75
0.70 0.82 0.08 0.13 0.21 0.27 0.37 0.45 0.70
0.65 0.84 0.03 0.08 0.16 0.22 0.32 0.40 0.65
0.59 0.86 0.03 0.11 0.17 0.26 0.34 0.59
0.54 0.88 0.06 0.11 0.21 0.29 0.54
0.48 0.90 0.06 0.16 0.23 0.48
0.43 0.92 0.10 0.18 0.43
0.36 0.94 0.03 0.11 0.36
0.29 0.96 0.01 0.29
0.20 0.98 0.20
3_59
33
3_60
SIVACON 8PV
Certificates/Approvals
3_61
33
Subject to change without prior notice 03/06 | Order No.: E20001-A270-P309-X-7600 | Dispostelle 27606 | 21C9376 EVPX.52.6.02 PA 03061.5 | Printed in Germany | © Siemens AG 2006
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Low-Voltage Controls and Distribution
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www.siemens.com/lowvoltage/technical-assistance
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description or performance characteristics which may not always comply
with the described form in all application cases or which may change due
to an advancement of our products. The desired performance characteris-
tics are only binding if they are expressly specified upon contract conclu-
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