CRD-5FF0912P SiC MOSFET High-Frequency Evaluation Board for 7L D2PAK User's Manual CPWR-AN17, Rev - CREE Power Applications This document is prepared as a user reference guide to install and operate CREE evaluation hardware. All parts of this document are provided in English, and the Cautions are provided in English, Mandarin, and Japanese. If the end user of this board is not fluent in any of these languages, it is your responsibility to ensure that they understand the terms and conditions described in this document, including without limitation the hazards of and safe operating conditions for this board. "" CPWR-AN17, Rev -, 06-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. Note: This Cree-designed evaluation hardware for Cree components is meant to be used as an evaluation tool in a lab setting and to be handled and operated by highly qualified technicians or engineers. The hardware is not designed to meet any particular safety standards and the tool is not a production qualified assembly. CAUTION PLEASE CAREFULLY REVIEW THE FOLLOWING PAGE, AS IT CONTAINS IMPORTANT INFORMATION REGARDING THE HAZARDS AND SAFE OPERATING REQUIREMENTS RELATED TO THE HANDLING AND USE OF THIS BOARD. 2 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. CAUTION DO NOT TOUCH THE BOARD WHEN IT IS ENERGIZED AND ALLOW THE BULK CAPACITORS TO COMPLETELY DISCHARGE PRIOR TO HANDLING THE BOARD. THERE CAN BE VERY HIGH VOLTAGES PRESENT ON THIS EVALUATION BOARD WHEN CONNECTED TO AN ELECTRICAL SOURCE, AND SOME COMPONENTS ON THIS BOARD CAN REACH TEMPERATURES ABOVE 50 CELSIUS. FURTHER, THESE CONDITIONS WILL CONTINUE FOR A SHORT TIME AFTER THE ELECTRICAL SOURCE IS DISCONNECTED UNTIL THE BULK CAPACITORS ARE FULLY DISCHARGED. Please ensure that appropriate safety procedures are followed when operating this board, as any of the following can occur if you handle or use this board without following proper safety precautions: Death Serious injury Electrocution Electrical shock Electrical burns Severe heat burns You must read this document in its entirety before operating this board. It is not necessary for you to touch the board while it is energized. All test and measurement probes or attachments must be attached before the board is energized. You must never leave this board unattended or handle it when energized, and you must always ensure that all bulk capacitors have completely discharged prior to handling the board. Do not change the devices to be tested until the board is disconnected from the electrical source and the bulk capacitors have fully discharged. 50 3 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 50 : 4 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 1. Introduction The purpose of this evaluation board is to demonstrate the high-switching performance of Cree 3rd Generation Silicon Carbide (SiC) Metal Oxide Semiconductor Field-Effect Transistors (MOSFETs) in a 7L D2PAK package. The new surface-mount device (SMD), specifically designed for high voltage MOSFETs, has a small footprint with a wide creepage distance of 7mm between drain and source. The new package also includes a separate driver source connection, which reduces gate ringing and provides clean gate signals. This evaluation board (Figure 1) comes configured as a basic half bridge circuit with two C3M0120090J SiC MOSFETs installed. The board can easily be configured into common power conversion topologies such as synchronous boost, synchronous buck, Inverter, and other topologies. This board was designed to make it easy for the user to: Evaluate SiC MOSFET switching performance in a 7L D2PAK package to characterize EON and EOFF losses. Evaluate thermal performance. The integrated heatsink is predrilled with a blind hole on the backside for thermocouples so the heatsink surface temperature can be accurately estimated. Serve as a PC board layout example for driving Gen 3 SiC MOSFETs in the newly developed 7L D2PAK package. Easily evaluate the effects of different Rg values, Miller clamps, uni-polar versus bipolar gate drive, fault detection circuit, various thermal interface materials, and cooling methods. Figure 1. Evaluation Board (top and side view) 2. Features The evaluation board's physical dimensions are 127mm x 98mm x 58mm. The board comes preassembled with an isolated heatsink, cooling fan, and 2 SiC MOSFETS. The heatsink is attached to the board with five nonconductive screws (RENY hexagon socket low head cap bolt M5 6mm). 5 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. A block diagram of the evaluation board is shown in Figure 2. Besides the two Cree 900V, 120m (C3M0120090) SiC MOSFETs (Q1 and Q2), there are two onboard isolated gate driver circuits to drive both Q1 and Q2. There are four power connectors (CON1, CON2, CON3, and CON4) for connecting to the +DC link, -DC link, and midpoint. There is a 20 pin signal/supply voltage ribbon cable connector (J10) onboard which carries the logic power, status signals, fault signals, and gate drive control signals. CON1 Q2 J10 Gate Drive CON2 Q1 CON3, CON4 Figure 2. Block Diagram Each gate drive circuit consists of a 2A isolated gate driver chip and a generous 2W isolated DC/DC converter that can comfortably switch the SiC MOSFETs at up to 3MHz. The driver chip provides 1200V of isolation between the low voltage control side and the high voltage drive side. The DC/DC converters are sourced with +12V on their inputs. Through a series of jumpers, JM1-JM6 (Figure 4), the gate drivers can each be configured as a low cost uni-polar (+15V/0V) gate drive or as a high performance bi-polar gate drive (+15V/-3V). The DC/DC converters provide a maximum of 5.2kV of isolation for 60 seconds. The complete board assembly will withstand a 1.5kVAC.rms Hi-pot test for 60 seconds. 6 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. +12V +15V 12V COM 18V 3.3V -3.3V +15V VCC 100 3.3V DESAT J5 CLAMP 8 OUT GND 8 J4 COM VEE 5.1K 1nf 5.1K 1nf J3 -3.3V +12V +15V 12V COM 18V 3.3V -3.3V +15V VCC 100 3.3V DESAT J6 CLAMP 8 OUT GND 8 J2 VEE COM J1 -3.3V Figure 3. Gate Drive Circuit Table 1 shows how the jumpers should be configured depending on the desired gate drive output levels. JM1, JM3 JM2, JM4 JM5, JM6 Gate Drive Output +15V/-3V +15V/0V SHORT OPEN OPEN SHORT OPEN SHORT Table 1. Jumper Table There is a short circuit protection function for each gate drive circuit by means of Vds voltage monitoring. The drain of each MOSFET is monitored (Figure 4). When either of the MOSFETs is in the ON state, and the drain voltage exceeds approximately 5.7V, the gate driver reverts to the OFF state and the fault signal for the channel is toggled. 7 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. GATE DRIVER 100 3.3V DESAT J5/J6 CLAMP 8 OUT 8 5.1K 1nf Figure 4. Gate Drive shown with Miller Clamp and short circuit protection. In a half bridge configuration, turning on one device tends to induce a voltage on the opposing device gate node. If this voltage exceeds the threshold voltage it is possible to get an unintended shoot through event in certain devices. A negative gate bias (Bi-polar drive) is one common way to mitigate this issue. When using a uni-polar drive sometimes it is common to use a Miller clamp to ensure that the gate voltage of the opposing device is clamped below the threshold voltage. To activate the Miller clamp, a jumper (JM5=upper channel, JM6=lower channel) needs to be shorted. The Miller clamp should only be enabled when the gate driver is configured for +15V/0V output voltage. Although we provide this feature on the board for the user to evaluate the effects of the Miller clamp, it is not necessary to have a Miller clamp. The SiC MOSFET channel is not fully turned ON when the gate voltage exceeds the device threshold voltage. For Cree SiC MOSFETs, the gate voltage would have to exceed 9V to have a significant shoot through event. 2.1 Cooling CAUTION IT IS NOT NECESSARY FOR YOU TO TOUCH THE BOARD WHILE IT IS ENERGIZED. WHEN DEVICES ARE BEING ATTACHED FOR TESTING, THE BOARD MUST BE DISCONNECTED FROM THE ELECTRICAL SOURCE AND ALL BULK CAPACITORS MUST BE FULLY DISCHARGED. SOME COMPONENTS ON THE BOARD REACH TEMPERATURES ABOVE 50 CELSIUS. THESE 8 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. CONDITIONS WILL CONTINUE AFTER THE ELECTRICAL SOURCE IS DISCONNECTED UNTIL THE BULK CAPACITORS ARE FULLY DISCHARGED. DO NOT TOUCH THE BOARD WHEN IT IS ENERGIZED AND ALLOW THE BULK CAPACITORS TO COMPLETELY DISCHARGE PRIOR TO HANDLING THE BOARD. PLEASE ENSURE THAT APPROPRIATE SAFETY PROCEDURES ARE FOLLOWED WHEN OPERATING THIS BOARD AS SERIOUS INJURY, INCLUDING DEATH BY ELECTROCUTION OR SERIOUS INJURY BY ELECTRICAL SHOCK OR ELECTRICAL BURNS, CAN OCCUR IF YOU DO NOT FOLLOW PROPER SAFETY PRECAUTIONS. 50 50 The evaluation board has several integrated features designed for effective thermal management. The top and bottom side of the board uses heavy 8oz. copper to help dissipate heat better. It also has a 3mm diameter solid copper inlay directly under the SiC MOSEFTs (Q1 and Q2) to effectively transfer the heat to the bottom side of the board. The board is mechanically attached via 5 nonconductive screws to an extruded aluminum heatsink with an integrated 30mm fan. Since the 9 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. heatsink is common to both MOSFETs it needs to be isolated from the bottom copper on the board yet be thermally conductive. This is achieved via a high performance 0.01 inch thermal interface material, Sil-Pad 2000 manufactured by Bergquist (Mfg. P/N SP2000-0.010-00-1212). A thermal stack up of the assembly is shown below in Figure 5. Figure 5. Thermal management and assembly stack up. The measured values for the thermal resistance from the device junction (C3M0120090J) to the case (Rth.j-c), from the device case to the surface of the heatsink (Rth.c-s), and from the heatsink to ambient with the fan turned ON with a 12VDC source (Rth.s-a), is listed in Table 2 below. Table 2. Measured thermal resistance values 3. Example Topologies The half bridge circuit topology was chosen for its flexibility, as it forms the common switch node in many common topologies. Two example configurations are listed below, with the 10 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. components shown outside the dotted box to be provided by the user. There are other topologies that can be configured, like non-synchronous buck or boost topologies, with minor modifications to the board. In addition, the user could quickly prototype an H-bridge or 6-pak based topology with the addition of multiple evaluation boards. A. Synchronous Buck Converter CON1 J10 Gate Drive HV DC L Q2 Q1 CON2 VOUT COUT Step down voltage MOSFET is used instead of flyback diode Connect inductor to CON2 as output CON1 is input CON2 is output CON3,CON4 is ground CON3, CON4 Figure 6a. Evaluation Board setup as Synchronous Buck Converter B. Synchronous Boost Converter CON1 L Q2 J10 COUT RL Gate Drive CON2 CIN Q1 VIN Step up voltage MOSFET is used instead of flyback diode Connect inductor L to CON2 CON1 is output CON2 is input CON3,CON4 is ground CON3, CON4 Figure 6b. Evaluation Board setup as Synchronous Boost Converter 11 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 4. Connectors CAUTION ***HIGH VOLTAGE RISK*** THERE CAN BE VERY HIGH VOLTAGES PRESENT ON THIS BOARD WHEN CONNECTED TO AN ELECTRICAL SOURCE, AND SOME COMPONENTS ON THIS BOARD CAN REACH TEMPERATURES ABOVE 50 CELSIUS. FURTHER, THESE CONDITIONS WILL CONTINUE AFTER THE ELECTRCIAL SOURCE IS DISCONNECTED UNTIL THE BULK CAPACITORS ARE FULLY DISCHARGED. DO NOT TOUCH THE BOARD WHEN IT IS ENERGIZED AND ALLOW THE BULK CAPACITORS TO COMPLETELY DISCHARGE PRIOR TO HANDLING THE BOARD. The connectors on the board have very high voltage levels present when the board is connected to an electrical source, and thereafter until the bulk capacitors are fully discharged. Please ensure that appropriate safety procedures are followed when working with these connectors as serious injury, including death by electrocution or serious injury by electrical shock or electrical burns, can occur if you do not follow proper safety precautions. When devices are being attached for testing, the board must be disconnected from the electrical source and all bulk capacitors must be fully discharged. After use the board should immediately be disconnected from the electrical source. After disconnection any stored up charge in the bulk capacitors will continue to charge the connectors. Therefore, you must always ensure that all bulk capacitors have completely discharged prior to handling the board. ****** 50 12 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. ****** 50 1ED020I12 C3M0120090J CON1 CON2 CON3 CON4 Figure 7. Board Top View with Main Features labeled 13 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 4.1 Test Pad Locations Figure 8. Board Top View with test points labeled The test pads highlighted in Figure 8 allow various types of pin headers and solderable posts to be soldered on all the major nodes so oscilloscope probes can be attached. Figure 9 shows a pair of pin headers soldered onto test points 6&7 allowing an oscilloscope probe to monitor VDS for the lower MOSFET (Figure 10). Figure 9. Pin headers on test points Figure 10. Scope probe on pin headers Terminals CON1, CON2, CON3 and CON4 are the power terminals, and their definitions vary based on topology. The terminals are vertical through-hole connectors with a 1032 threaded hole and a screw provided. The terminals can accommodate a cable with a 14 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. ring or spade style connector with 1/4" width and a 10-32 screw. The control signals are all contained on connector J10. The definition of J10 for each pin is shown in Table 3. 1 2 PWR IN (+12V) 3 4 COMMON 5 6 HIGH SIDE POWER GOOD, 5V=POWER GOOD, OV=POWER BAD 7 8 HIGH SIDE FAULT, 5V=NO FAULT, 0V=DESAT FAULT 9 10 HIGH SIDE RESET, PULL DOWN TO COMMON TO RESET FAULT 12 HIGH SIDE PWM INPUT, 5V=SWITCH ON, 0V=SWITCH OFF 13 14 LOW SIDE POWER GOOD, 5V=POWER GOOD, OV=POWER BAD 15 16 LOW SIDE FAULT, 5V=NO FAULT, 0V=DESAT FAULT 17 18 LOW SIDE RESET, PULL DOWN TO COMMON TO RESET FAULT 19 20 LOW SIDE PWM INPUT, 5V=SWITCH ON, 0V=SWITCH OFF 11 COMMON Table 3. Pin definitions for connector J10 The heatsink fan is powered by 12VDC. The 12V fan can be powered from the same 12V power supply that is powering the evaluation board. 5. Switching loss measurement This board is ideal for making double pulsed clamped inductive load switching measurements. Figure 11 shows how the board should be connected to make the switching measurements. CON1 L Q2 J10 Gate Drive CBULK CON2 HV DC Q1 Current viewing resistor J9 CON3, CON4 Figure 11. Clamped Inductive Switching Measurement Circuit A precision current viewing resistor will be needed so that the current though Q1 can be measured. There are provisions (J9) on the board for installing a through-hole current viewing resistor. The board comes with a jumper in place. This jumper must be removed when adding a current viewing resistor. T&M Research makes a viewing resistor (part #SDN-414-01) (Figure 12) that can be used with this board. The resistor has a resistance of 10milliohms and therefore works with most 15 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. oscilloscopes with the probe attenuation set to x100. If the user selects a different resistor, the user should ensure that the resistor has minimal insertion inductance. Figure 12. SDN-414-01 (sold separately) Due to the fast switching speeds associated with Cree SiC MOSFETs, the following steps must be followed closely to yield the most accurate results possible: Scope probes measuring VDS and VGS must have minimal loop area between the signal and ground. The oscilloscope probes measuring VDS and IDS must be properly deskewed. Bulk capacitance may need to be added to the board to minimize DC link voltage sag during two-pulse measurements. The amount will vary based on desired current level and pulse width. Figure 14 shows a two-pulse setup. Figure 15 shows the waveforms measured with this twopulse setup. 16 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. Figure 14. Probes connected to evaluation board Figure 15. Waveforms measured with evaluation board 17 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. WARNING: HIGH VOLTAGE / SOME COMPONENTS WILL GET HOT. 6. Appendix 18 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 7. PCB Layout Drawings Top Traces 19 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. Top Silkscreen Inner Layer 1 Traces 20 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. Inner Layer 2 Traces 21 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. Bottom Traces Bottom Silkscreen 22 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 8. Bill of Materials Item Qty Per Reference Designator Description Manufacturer Name Manufacturer's P/N 1 4 CON1,CON2,CON3,C ON4 TERM PC SNAPIN VRT 1032 W/SCREW KEYSTONE 8174 2 6 C1,C3,C5,C23,C25,C2 7 Open UMK107AB7105KA-T 3 4 C2,C6,C24,C28 Open GMK316AB7106KL-TR 4 4 C4,C21,C22,C26 Open CL10A475KA8NQNC 5 1 C7 Epcos B32023A3154M 6 1 C8 Epcos B32774D1505K 7 2 C9,C13 CAP CER 1uf 50V 10% X7R 0603 CAP CER 10UF 35V X7R 1206 CAP CER 4.7UF 25V X5R 0603 CAP FILM 0.15UF 20% 1.5KVDC RAD CAP FILM 5UF 10% 1.3KVDC RADIAL CAP CER 4.7uf 50V 10% X7R 1206 Open UMK316AB7475KL-T 8 10 C10,C12,C14,C15,C17 ,C29,C31,C33,C40,C4 2 Open CL10B104KB8SFNC 9 4 C16,C18,C32,C34 Open C1608X7R2A103K080AA 10 2 C19,C35 Open CL31B102KBCNNNC 11 2 C20,C36 Open C1210C101KGRACTU 12 2 C37,C38 Open CL10B101KB8NNNC 13 2 C43,C44 Open CL10B152KB8NNNC 14 2 D1,D2 Diodes Inc. 1N5819HW-7-F 15 2 D3,D4 Diodes Inc. US1M-13-F 16 2 D5,D6 Diodes Inc. MMSZ5240B-7-F 17 2 D17,D19,D18,D20 Cree CLVBA-FKACAEDH8BBB7A363 18 2 JM1,JM3 Open ERJ-6GEY0R00V 19 1 J9 Keystone 5016 20 1 J10 CAP CER 10,000pf 50V 10% X7R 0603 CAP CER 1000PF 50V X7R 1206 100pf, X7R, 10%, 2kV ceramic capacitor CAP CER 100pf 50V 10% X7R 0603 CAP CER 1500PF 50V X7R 0603 DIODE SCHOTTKY 40V 1A SOD123 DIODE GEN PURP 1KV 1A SMA DIODE ZENER 10V 500MW SOD123 LED RGB DIFFUSED 4PLCC SMD RES 0 OHM jumper 1/8W 1% 0805 SMD PC TEST POINT COMPACT SMT 20Pin 2X10 vertical header FCI 71918-120LF 21 1 L1 common mode choke TDK ACM4520-142-2P-T000 22 2 Q1,Q2 Cree C3M0120090J 23 4 Q3,Q4,Q5,Q6 Diodes Inc. 2N7002K-7 24 4 R1,R2,R17,R18 Open RC0805JR-075R1L 25 6 R3,R4,R5,R6,R7,R9 MOSFET, D2PAK-7 MOSFET N-CH 60V 300MA SOT23-3 RES SMD 5.1 OHM 5% 1/8W 0805 RES SMD 1M OHM 1% 1/4W 1206 Open ERJ-8ENF1004V CAP CER 0.1uf 50V 10% X7R 0603 23 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. 26 2 R8,R20 27 2 R10,R19 28 8 R11,R12,R21,R22,R27 ,R28,R45,R48 29 4 R13,R15,R23,R25 30 2 R14,R24 31 2 R16,R26 32 2 R29,R30 33 4 R39,R40,R41,R42 34 4 R43,R44,R46,R47 35 2 U1,U2 36 2 U3,U4 37 2 U6,U9 38 1 U11 39 2 ZD1,ZD4 40 2 ZD2,ZD5 41 2 ZD3,ZD6 42 1 (mechanical) 43 5 (mechanical) 44 1 (mechanical) 45 1 (mechanical) 46 2 (mechanical) 47 4 (mechanical) 48 4 (mechanical) 49 2 (mechanical) RES SMD 100 OHM 1% 1/8W 0603 RES 10 OHM 1/16W 1% 0603 SMD RES SMD 10K OHM 1% 1/10W 0603 RES SMD 8.2 OHM 5% 1/3W 1206 RES SMD 10 OHM 1% 2W 2512 RES SMD 5.1K OHM 1% 1/4W 1206 RES SMD 2K OHM 1% 1/4W 1206 RES SMD 1K OHM 1% 1/8W 0805 RES 10 OHM 1/16W 1% 0603 SMD IC IGBT DVR 1200V 2A DSO16 DC/DC CONV 5.2KV ISO SIP7 TH 2W IC SINGLE INVERTERGATE SOT-23-5 5V, 1A regulator DIODE ZENER 20V 500MW SOD123 DIODE ZENER 3.3V 500MW SOD123 DIODE ZENER 2.7V 500MW SOD123 Heat Sink (Aavid Thermalloy custom) RENY Hexagon socket low head cap bolt M5 6mm FAN AXIAL 30X10MM 12VDC WIRE FINGER GUARD 30MM METAL Zinc-Plated Steel Pan Head Phillips Machine Screw, Internal Washer, 4-40 Thread, 5/8" Length Nylon 6/6 Male-Female Threaded Hex Standoff, 1/4" Hex, 1-1/2" Length, 6-32 Screw Size Nylon 6/6 Hex Nut, 6-32 Thread Size, 5/16" Wide, 1/8" High Thermal Interface, 1"x1" Open MCT06030C1000FP500 Open ERJ-3EKF10R0V Open ERJ-3EKF1002V Open ESR18EZPJ8R2 Open CRM2512-FX-10R0ELF Open ERJ-8ENF5101V Open ERJ-8ENF2001V Open ERJ-6ENF1001V Open ERJ-3EKF10R0V Infineon 1ED020I12F2XUMA1 Murata MEJ2D1209SC TI SN74LVC1G04DBVR On Semiconductor On Semiconductor MC7805CD2TR4G MMSZ20T1G Diodes Inc. MMSZ5226B On Semiconductor MMSZ2V7T1G Cree 111115-01 SolidSpot RENYLC506 Sunon MC30101V1-000U-A99 Qualtek 8346 McMaster-Carr 90403A112 McMaster-Carr 92745A348 McMaster-Carr 94812A300 Bergquist SP2000-0.010-00-1212 24 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. IMPORTANT NOTES Purposes and Use Cree, Inc. (on behalf of itself and its affiliates, "Cree") reserves the right in its sole discretion to make corrections, enhancements, improvements, or other changes to the board or to discontinue the board. THE BOARD DESCRIBED IS AN ENGINEERING TOOL INTENDED SOLELY FOR LABORATORY USE BY HIGHLY QUALIFIED AND EXPERIENCED ELECTRICAL ENGINEERS TO EVALUATE THE PERFORMANCE OF CREE POWER SWITCHING DEVICES. THE BOARD SHOULD NOT BE USED AS ALL OR PART OF A FINISHED END PRODUCT. THIS BOARD IS NOT SUITABLE FOR SALE TO OR USE BY CONSUMERS AND CAN BE HIGHLY DANGEROUS IF NOT USED PROPERLY. THIS BOARD IS NOT DESIGNED OR INTENDED TO BE INCORPORATED INTO ANY OTHER PRODUCT FOR RESALE. THE USER SHOULD CAREFULLY REVIEW THE DOCUMENT TO WHICH THESE NOTIFICATIONS ARE ATTACHED AND OTHER WRITTEN USER DOCUMENTATION THAT MAY BE PROVIDED BY CREE (TOGETHER, THE "DOCUMENTATION") PRIOR TO USE. USE OF THIS BOARD IS AT THE USER'S SOLE RISK. Operation of Board It is important to operate the board within Cree's recommended specifications and environmental considerations as described in the Documentation. Exceeding specified ratings (such as input and output voltage, current, power, or environmental ranges) may cause property damage. If you have questions about these ratings, please contact Cree at sic_power@cree.com prior to connecting interface electronics (including input power and intended loads). Any loads applied outside of a specified output range may result in adverse consequences, including unintended or inaccurate evaluations or possible permanent damage to the board or its interfaced electronics. Please consult the Documentation prior to connecting any load to the board. If you have any questions about load specifications for the board, please contact Cree at sic_power@cree.com for assistance. Users should ensure that appropriate safety procedures are followed when working with the board as serious injury, including death by electrocution or serious injury by electrical shock or electrical burns can occur if you do not follow proper safety precautions. It is not necessary in proper operation for the user to touch the board while it is energized. When devices are being 25 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. attached to the board for testing, the board must be disconnected from the electrical source and any bulk capacitors must be fully discharged. When the board is connected to an electrical source and for a short time thereafter until board components are fully discharged, some board components will be electrically charged and/or have temperatures greater than 50 Celsius. These components may include bulk capacitors, connectors, linear regulators, switching transistors, heatsinks, resistors and SiC diodes that can be identified using a board schematic. Users should contact Cree at sic_powr@cree.com for assistance if a board schematic is not included in the Documentation or if users have questions about a board's components. When operating the board, users should be aware that these components will be hot and could electrocute or electrically shock the user. As with all electronic evaluation tools, only qualified personnel knowledgeable in handling electronic performance evaluation, measurement, and diagnostic tools should use the board. User Responsibility for Safe Handling and Compliance with Laws Users should read the Documentation and, specifically, the various hazard descriptions and warnings contained in the Documentation, prior to handling the board. The Documentation contains important safety information about voltages and temperatures. Users assume all responsibility and liability for the proper and safe handling of the board. Users are responsible for complying with all safety laws, rules, and regulations related to the use of the board. Users are responsible for (1) establishing protections and safeguards to ensure that a user's use of the board will not result in any property damage, injury, or death, even if the board should fail to perform as described, intended, or expected, and (2) ensuring the safety of any activities to be conducted by the user or the user's employees, affiliates, contractors, representatives, agents, or designees in the use of the board. User questions regarding the safe usage of the board should be directed to Cree at sic_power@cree.com. In addition, users are responsible for: compliance with all international, national, state, and local laws, rules, and regulations that apply to the handling or use of the board by a user or the user's employees, affiliates, contractors, representatives, agents, or designees. taking necessary measures, at the user's expense, to correct radio interference in the event that operation of the board causes interference with radio communications. The board may generate, use, and/or radiate radio frequency energy, but it has not been tested for compliance within the limits of computing devices pursuant to Federal Communications 26 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc. Commission or Industry Canada rules, which are designed to provide protection against radio frequency interference. compliance with applicable regulatory or safety compliance or certification standards that may normally be associated with other products, such as those established by EU Directive 2011/65/EU of the European Parliament and of the Council on 8 June 2011 about the Restriction of Use of Hazardous Substances (or the RoHS 2 Directive) and EU Directive 2002/96/EC on Waste Electrical and Electronic Equipment (or WEEE). The board is not a finished end product and therefore may not meet such standards. Users are also responsible for properly disposing of a board's components and materials. No Warranty THE BOARD IS PROVIDED "AS IS" WITHOUT WARRANTY OF ANY KIND, INCLUDING BUT NOT LIMITED TO ANY WARRANTY OF NON-INFRINGEMENT, WHETHER EXPRESS OR IMPLIED. THERE IS NO REPRESENTATION THAT OPERATION OF THIS BOARD WILL BE UNINTERRUPTED OR ERROR FREE. Limitation of Liability IN NO EVENT SHALL CREE BE LIABLE FOR ANY DAMAGES OF ANY KIND ARISING FROM USE OF THE BOARD. CREE'S AGGREGATE LIABILITY IN DAMAGES OR OTHERWISE SHALL IN NO EVENT EXCEED THE AMOUNT, IF ANY, RECEIVED BY CREE IN EXCHANGE FOR THE BOARD. IN NO EVENT SHALL CREE BE LIABLE FOR INCIDENTAL, CONSEQUENTIAL, OR SPECIAL LOSS OR DAMAGES OF ANY KIND, HOWEVER CAUSED, OR ANY PUNITIVE, EXEMPLARY, OR OTHER DAMAGES. NO ACTION, REGARDLESS OF FORM, ARISING OUT OF OR IN ANY WAY CONNECTED WITH ANY BOARD FURNISHED BY CREE MAY BE BROUGHT AGAINST CREE MORE THAN ONE (1) YEAR AFTER THE CAUSE OF ACTION ACCRUED. Indemnification The board is not a standard consumer or commercial product. As a result, any indemnification obligations imposed upon Cree by contract with respect to product safety, product liability, or intellectual property infringement do not apply to the board. 27 CPWR-AN17, Rev -, 05-2016 Copyright (c) 2016 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree, the Cree logo, and Zero Recovery are registered trademarks of Cree, Inc.