EVSPIN32F02Q1S1

EVSPIN32F02Q1S1 Data brief 3-phase inverter based on STSPIN32F0251 Features • • Input voltage from 15 VAC (20 VDC) to 120 VAC (170 VDC) STD17NF25 MOS power stage featuring: – V(DS) = 250 V • Overcurrent threshold set to 16 Apeak • Dual footprint for IGBT/MOSFET package: – DPAK – PowerFlat 6x5 Single-shunt current sensing, suitable for: – Sensored or sensorless 6-step algorithm – Sensored or sensorless single-shunt vector (FOC) algorithm Smart shutdown overcurrent protection Digital Hall sensors and encoder input Bus voltage sensing 15 V VCC and 3.3 V VDD supplies Embedded ST-LINK/V2-1 Easy user interface with buttons and trimmer RoHS compliant – • • • • • • • • Product status link EVSPIN32F02Q1S1 RDS(on) max. = 0.165 Ω Applications • • • • Battery operated and 110 Vac supplied power and garden tools Industrial fans and pumps Home appliances Industrial and home automation Description The EVSPIN32F02Q1S1 board is a 3-phase complete inverter based on the STSPIN32F0251 controller, which embeds a 3‑phase 250 V gate driver and a Cortex®-M0 STM32 MCU. The power stage features STD17NF25 MOSFETS, but can be populated with any IGBT or Power MOSFET in DPAK or powerFLAT 6x5 package. The board has a single-shunt sensing topology, and both sensored and sensorless FOC and 6‑step control algorithms can be implemented. This allows driving permanent magnet synchronous motors (PMSMs) and brushless DC (BLDC) motors. The evaluation board is compatible with a wide range input voltage from 15 VAC (20 VDC) to 120 VAC (170 VDC), and includes a power supply stage with the VIPER013BLS in buck configuration to generate +15 V and +3.3 V supply voltage required by the application. Debug and configuration of FW can be performed with standard STM32 tools through the detachable ST-LINK‑debugger. SWD and UART TX‑RX connectors are also available. DB4379 - Rev 1 - December 2020 For further information contact your local STMicroelectronics sales office. www.st.com EVSPIN32F02Q1S1 Safety and operating instructions 1 Safety and operating instructions 1.1 General terms Warning: During assembly, testing, and operation, the evaluation board poses several inherent hazards, including bare wires, moving or rotating parts and hot surfaces. Danger: There is danger of serious personal injury, property damage or death due to electrical shock and burn hazards if the kit or components are improperly used or installed incorrectly. The kit is not electrically isolated from the high-voltage supply AC/DC input. The evaluation board is directly linked to the mains voltage. No insulation is ensured between the accessible parts and the high voltage. All measuring equipment must be isolated from the mains before powering the board. When using an oscilloscope with the demo, it must be isolated from the AC line. This prevents shock from occurring as a result of touching any single point in the circuit, but does NOT prevent shock when touching two or more points in the circuit. All operations involving transportation, installation and use, and maintenance must be performed by skilled technical personnel able to understand and implement national accident prevention regulations. For the purposes of these basic safety instructions, “skilled technical personnel” are suitably qualified people who are familiar with the installation, use and maintenance of power electronic systems. 1.2 Intended use of evaluation board The evaluation board is designed for demonstration purposes only, and must not be used for electrical installations or machinery. Technical data and information concerning the power supply conditions are detailed in the documentation and should be strictly observed. 1.3 Installing the evaluation board • • • • DB4379 - Rev 1 The installation and cooling of the evaluation board must be in accordance with the specifications and target application. The motor drive converters must be protected against excessive strain. In particular, components should not be bent or isolating distances altered during transportation or handling. No contact must be made with other electronic components and contacts. The board contains electrostatically-sensitive components that are prone to damage if used incorrectly. Do not mechanically damage or destroy the electrical components (potential health risks). page 2/20 EVSPIN32F02Q1S1 Operating the evaluation board 1.4 Operating the evaluation board To operate properly the board, follow these safety rules. 1. Work Area Safety: – The work area must be clean and tidy. – Do not work alone when boards are energized. – Protect against inadvertent access to the area where the board is energized using suitable barriers and signs. – A system architecture that supplies power to the evaluation board must be equipped with additional control and protective devices in accordance with the applicable safety requirements (i.e., compliance with technical equipment and accident prevention rules). – Use non-conductive and stable work surface. – Use adequately insulated clamps and wires to attach measurement probes and instruments. 2. Electrical Safety: – Remove power supply from the board and electrical loads before performing any electrical measurement. – Proceed with the arrangement of measurement setup, wiring or configuration paying attention to high voltage sections. – Once the setup is complete, energize the board. Danger: Do not touch the evaluation board when it is energized or immediately after it has been disconnected from the voltage supply as several parts and power terminals containing potentially energized capacitors need time to discharge. Do not touch the boards after disconnection from the voltage supply as several parts like heat sinks and transformers may still be very hot. The kit is not electrically isolated from the AC/DC input. The USB interface of the board does not insulate host computer from high voltage. When the board is supplied at a voltage outside the ELV range, a proper insulation method such as a USB isolator must be used to operate the board. 3. DB4379 - Rev 1 Personal Safety – Always wear suitable personal protective equipment such as, for example, insulating gloves and safety glasses. – Take adequate precautions and install the board in such a way to prevent accidental touch. Use protective shields such as, for example, insulating box with interlocks if necessary. page 3/20 EVSPIN32F02Q1S1 Schematic diagrams 2 Schematic diagrams Figure 1. EVSPIN32F02Q1S1 schematic – Driver output stages VDD VDD VDD VCC VDD J9 R1 27R TP 6 VDD 1 47 46 45 40 39 38 LVG2 2 N.M. S TD17NF25 2 C13 N.M. N.M. HV 5 2 Q4 D6 R27 TP 20 GL2 BAT54J 1 C17 R31 100k Q6 N.M. 6 7 8 Q4A N.M. 1 R19 100k GH24 TP 7 1 2 3 OUT2 OUT2 6 7 8 Q6A GL24 1 2 3 TP 24 HV S ENS E VCC C8 V+ R56 Curr_fdbk VDD V- TP 13 R52 CIN CIN 63.4k BAT54J 1 Q9 R57 100k R38 N.M. Q7A GH14 TP 14 100nF/250V 6 7 8 1 2 3 OUT1 5 Q9A GL14 6 7 8 OUT1 N.M. TP 22 GL1 5 2 Q7 100R R33 10k 1 2 3 C33 N.M. TP 23 S ENS E R58 9 0R R60 8 + 14 - R59 R36 R111 75m-2W-1% 1k C22 1nF/25V C32 N.M. CURRENT_REF D9 R34 - C25 N.M. 75m-2W-1% + 100R R49 1 R44 100k 10R C27 33pF/25V GH1 75m-2W-1% R41 LVG1 BAT54J TP 21 C9 N.M. HV S TD17NF25 10R C26 1uF/50V C24 4.7uF/10V D8 3 C18 47nF/25V R40 R42 C23 100nF/25V U2 TS V911ILT HV 2 D7 N.M. 2 VDD R35 27R R32 47k 3 OD S TD17NF25 VCC TP 12 VDD R55 3k GH2 BAT54J 100R 100R 1 47nF/25V VDD R104 N.M. 1 2 3 5 LVG1 C16 4.7nF/25V Temp_fdbk 3 PGND C80 3k TP 19 10R R18 C12 1uF/50V LVG3 LVG2 VBUS _fdbk S ENS E OUT3 TP 11 0R R39 N.M. 3 D5 R16 10R CURRENT_REF TP 25 HV D4 N.M. 1 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 TP 10 SPEED R26 0R R29 GND 2 TP 16 TP 8 Q3 S TD17NF25 53 52 51 U1 Curr_fdbk C7 N.M. Q3A GL34 S ENS E R30 R23 100k R14 100k 100R 2 EP AD BOOT1 HVG1 OUT1 1 6 7 8 N.M. P A0 P A1 P A2 C11 10pF/50V BOOT2 HVG2 OUT2 S TS P IN32F0251Q 1 2 3 5 3 NRS T VDD Q1A 2 X1 BOOT3 HVG3 OUT3 GL3 BAT54J 6 7 8 GH34 TP 4 S TD17NF25 EXP VDD RES 6 P B8 VS S VDD P C13 P C14 P C15 P F0 P F1 NRS T VS S A VDDA P A0 P A1 P A2 P A3 P A4 RES 7 TP 18 R15 27R BOOT0 P B7 P B6 P B5 P B4 P B3 P A15 P A14 P A13 P A12 RES 3 RES 2 RES 1 VCC RES 5 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 Q1 OUT3 D3 R10 R13 VCC 0R ZCR P C14 P C15 10pF/50V 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 TP 5 1 C4 N.M. R5 100k 100R 10R R103 GP IO_BEMF 8MHz LVG3 TP 1 VCC 2 JP1 3 CLOS ED 2-3 HV 5 S TD17NF25 TP 3 UART1_TX UART1_RX C2 220nF/25V C10 C3 1uF/50V TP 2 1 C1 100nF/25V CP OUT GH3 BAT54J R3 S WD_IO 4 3 2 1 VCC J1 P A5 P A6 P A7 P B0 P B1 VDD VS S OD CIN GND P GND LVG1 LVG2 LVG3 RES 4 VCC SPI1_NSS/PROC SPI1_MOSI/GPIO SPI1_MISO/GPIO SPI1_CLK/COMM TP 17 10R 1 S WD_CLK Boot from: CLOSED 2-3 Flash VDD CLOSED 1-2 System/SRAM HV D2 R2 3 D1 N.M. 3 C21 100nF/25V 2 C20 100nF/25V 1 2 3 4 C19 100nF/25V CP OUT 0R U3C 33k TS 3704IP T R61 10M C35 100nF/25V Figure 2. EVSPIN32F02Q1S1 schematic – Feedback network DB4379 - Rev 1 page 4/20 EVSPIN32F02Q1S1 Schematic diagrams VDD HALL PWR JP2 VDD OP EN VCC R63 10k A+/H1 B+/H2 Z+/H3 VDD GND J3 1 2 3 4 5 A+/H1_C R70 B+/H2_C R65 10k D11 BAT54J D12 BAT54J R68 P A0_Hall P A1_Hall R74 N.M. R75 N.M. C37 10pF/10V 0R C38 R76 N.M. 10pF/10V R121 8K2 +5V 1 C81 4.7uF/50V D16 DDZ9690T P A2_Hall 1.8k R73 Q11 2 3S TF1640 3 OP EN JP9 1.8k 1.8k R71 Z+/H3_C R64 10k D10 BAT54J C39 10pF/10V 2 J P 10 VDD VCC 1 VDD 3 VCC +5V C43 100nF/25V 4 5V VDD 5 2 P A1_B R112 V+ + VN 4 V- 7 P A0_B_VN 2 - VN 100R C77 100pF 12 U3A 1M 1M 3 P A0_B VDD R116 R115 C30 100nF/25V 1M 6 R113 + 1 - U3B 100R TS 3704IP T P A2_B 11 P A1_B_VN R114 + VN 10 C78 100pF 13 - U3D R8 P A2_B_VN R6 TS 3704IP T C79 100pF 56k R118 TS 3704IP T D23 1 1k D20 BAT30S W P A2_B 3 OUT3 39k 100R R110 10k 2 C6 4.7pF/50V VN R12 1.5k BAS 21J 1 R117 D26 GP IO_BEMF JP8 2 BEMF3 R22 R21 39k 56k P A1_B OUT2 P A0_B_VN 1 P A0_Hall 3 P A1_B_VN 1 HALL1 C34 3.3nF/25V CLOSED 2-4 P A1_Hall 3 P A2_B_VN 1 HALL2 CLOSED 2-4 P A2_Hall 3 R119 HALL3 CLOSED 2-4 D24 1 2 NRS T 100R 430483025816 VDD BAT54J P A2_B BEMF2 2 R54 1 2 JP7 2 R25 10k BAS 21J 1k C15 4.7pF/50V D21 BAT30S W 3 R28 1.5k 1 S W1 3 4 P A1_B BEMF1 4 P A0_B JP6 4 39k 4 R48 RESET 2 VDD VN VDD P A1 P A2 GP IO_BEMF R47 R45 OUT1 R120 YELLOW LD1 R62 1 D25 2 R51 10k BAS 21J 1k 120R D22 BAT30S W P A0_B 3 56k 39k VDD BAT54J R53 1.5k C29 4.7pF/50V VN USER2 S W2 1 P A0 2 D27 D28 3 4 R66 1 2 P C15 GP IO_BEMF HV 100R 430483025816 BAT54J C36 1nF/25V R67 470k VDD VDD R69 470k 1 D13 BAT54J VBUS _fdbk VDD R72 N.M. 10K C40 YELLOW LD2 N.M. 2 R77 120R Temp_fdbk USER1 S W3 3 4 R79 1 2 R78 27k P C14 R80 68k R81 4.7k 100R 430483025816 C41 100nF/25V R78: N.M. if HV = 48 VDC C42 1nF/25V Figure 3. EVSPIN32F02Q1S1 schematic – Power Supply F1A NTC1 1 + 2 5R D14 GBU802 2 C69 2 C69A 270uF/250V RV1 N.M. E3V3 4 1 N.M. - AC MAINS ~ 1 10A/277V s low 3 J4 HV N.M. F1 E3V3 VDD 3V3_STLINK R82 330R JP3 CLOS ED 1-2 Vcc_F Vcc_F JP4 VCC GND VDD 3V3_S TLINK VDD 1 2 3 D15 3V3 N.M. LD3 RED VCC 1 2 3 OUT1 + C45 CLOS ED 1-2 OUT2 OUT3 22uF/25V 3 OUT1 2 OUT2 1 OUT3 J2 D19 U8 5 C74 N.M. R109 2.7k C73 1nF/10V COMP HV R106 FB DIS 6 7 8 9 10 Drain Drain Drain Drain Drain VIP e r013 BAT41Z 100k 4 3 Vcc 2 GND 1 C72 220nF/25V R107 8.66k L1 C76 C70 Vcc_F 330uH R108 3 C71 1nF/50V 1uF/50V 100nF/50V D18 S TTH1R04 + C75 47uF/20V R105 15k DB4379 - Rev 1 D17 S TTH1R04 0R LD4 GREEN C47 100nF/25V U4 Vin LD1117S 33CTR Vout GND 1 2 E3V3 C48 10uF/10V R83 1.5k 1/4W page 5/20 EVSPIN32F02Q1S1 Schematic diagrams Figure 4. EVSPIN32F02Q1S1 schematic – STLINK debugger VUS B VUS B C53 100nF/25V VUS B 3V3_S TLINK R84 10k J5 S HELL S HELL S HELL S HELL DD+ U5 1 2 3 65100516121 TP 15 3 1 2 3 4 5 US B_VCC US BDM US BDP ID US B_GND I/O1#6 I/O1#1 GND VBUS I/O2#3 I/O2#4 6 US B_DM R85 1 5 2 6 7 8 9 R86 4 US B_DP 1 3 R87 36k 1.5k US BLC6-2S C6 US B_RENUM 100R Q10 BC847 3V3_S TLINK U6 C54 1uF/10V C55 4 100nF/25V VIN OUT 5 100nF/25V INHIBIT BYP AS S GND C56 2 C58 1uF/10V LD3985M33R C57 10nF/25V VDD VDD R88 4.7k U7 S WD_CLK T_J TCK R95 S WD_IO UART1_RX UART1_TX R92 4.7k 0R RX 3V3_S TLINK T_J TMS 0R R89 1 2 R91 0R S TLINK_TX S TLINK_RX R93 0R TX T_J TCK J6 J7 LED_S TLINK 1 2 3 4 FM_S WCLK US B_DM US B_DP FM_S WDIO US B_RENUM STLINK FW LOAD 1 2 J8 clos ed X2 3V3_S TLINK 8MHz R99 100k R100 100k C59 10pF/50V 44 7 C60 10pF/50V 3V3_S TLINK R102 100R DB4379 - Rev 1 3V3_S TLINK K2 A2 A1 K1 JP5 OP EN C61 100nF/50V 1 24 36 48 2 LED_S TLINK LD5 1 R101 100R 29 30 31 32 33 34 37 38 5 6 T_NRS T NRS T 10 11 12 13 14 15 16 17 C62 C63 C64 C65 9 P A0-WKUP P A1 P A2 P A3 P A4 P A5 P A6 P A7 P A8 P A9 P A10 P A11 P A12 P A13 P A14 P A15 OS CIN/P D0 OS COUT/P D1 P B0 P B1 P B2/BOOT1 P B3/J TDO P B4/J NTRS T P B5 P B6 P B7 P B8 P B9 P B10 P B11 P B12 P B13 P B14 P B15 P C13-TAMP ER-RTC P C14-OS C32_IN P C15-OS C32_OUT 18 19 20 39 40 41 42 43 R94 4.7k 45 46 21 22 25 26 27 28 2 3 4 R90 2.7k T_NRS T T_J TMS T_J TCK S WDIO R96 R97 100R 10k R98 N.M. BOOT0 NRS T VBAT VDD_1 VDD_2 VDD_3 VS S _1 VS S _2 VS S _3 VDDA VS S A 23 35 47 8 100nF/25V 100nF/25V 100nF/25V 100nF/25V S TM32F103CBT6 RED-GREEN page 6/20 EVSPIN32F02Q1S1 Bill of materials 3 Bill of materials Table 1. EVSPIN32F02Q1S1 Bill of Materials Components common to all device variants Reference Part Value C1, C19, C20, C21, C23, C30, C35, C41, C43, C47, C53, C55, C56, C62, C63, C64, C65 100nF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206071 C2, C72 220nF/25V SMT ceramic capacitor Size 0603 WURTH ELEKTRONIK 885012206073 1uF/50V SMT ceramic capacitor Size 0805 WURTH ELEKTRONIK 885012207103 N.M. SMT ceramic capacitor Size 0603 4.7pF/50V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012006049 4x13 mm, Pitch 10 mm WURTH ELEKTRONIK 890334023006 C3, C12, C26, C70 C4, C7, C13, C17, C25, C32, C33, C40, C74 C6, C15, C29 Description Manufacturer Part Number C8 N.M. C9 100nF/250V SMT Ceramic Capacitor Size 1210 TDK C10, C11, C59, C60 10pF/50V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012006051 C16 4.7nF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206063 C18, C80 47nF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206069 C22, C36, C42 1nF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206059 C24 4.7uF/10V SMT Ceramic Capacitor Size 0805 WURTH ELEKTRONIK 885012207025 C27 33pF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012006035 C34 3.3nF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206062 C37, C38, C39 10pF/10V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012006002 C45 22uF/25V SMT Aluminum Elect. Capacitor 5x5.4 mm WURTH ELEKTRONIK 865090442004 C48 10uF/10V SMT Ceramic Capacitor Size 1206 WURTH ELEKTRONIK 885012208018 C54, C58 1uF/10V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206026 C57 10nF/25V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206065 C61 100nF/50V SMT Ceramic Capacitor Size 0603 WURTH ELEKTRONIK 885012206095 C69A DB4379 - Rev 1 N.M. Film Capacitor Package THT Electrolytic Capacitor Radial p7.5 d18h25 Rubycon CGA6M3X7R2E104M200A E 450BXW68MEFC18X25 page 7/20 EVSPIN32F02Q1S1 Bill of materials Reference Part Value Description Package Manufacturer Part Number C69 270uF/250V THT Electrolytic Capacitor Radial p10 d22h27 Nichicon C71 100nF/50V SMT ceramic capacitor Size 0805 WURTH ELEKTRONIK 885012207098 C73 1nF/10V SMT ceramic capacitor Size 0603 WURTH ELEKTRONIK 885012206008 C75 47uF/20V Low ESR series of robust MnO2 solid electrolyte capacitors C76 1nF/50V SMT ceramic capacitor Size 0603 100pF SMT ceramic capacitor Size 0603 4.7uF/50V SMT Ceramic Capacitor Size 1206 C77, C78, C79 C81 D1, D4, D7 N.M. Turbo 2 Ultrafast High-Voltage Rectifier D/E WURTH ELEKTRONIK 885012206083 WURTH ELEKTRONIK 885012208094 STMicroelectronics STTH1L06A SOD-323 STMicroelectronics BAT54JFILM GBU Diodes Incorporated or Taiwan Semiconductor GBU802 or GBU803 BAT54J 40V, 300mA Small signal Schottky SMT Diode D14 GBU802 8A Glass passivated bridge rectifiers D15 3V3 N.M. ZENER SOD-123 D16 DDZ9690T SURFACE MOUNT ZENER DIODE SOD523 D17, D18 STTH1R04 Ultrafast recovery diode, 1A 400V BAT41Z DIODES Incorporated DDZ9690T-7 SMA STMicroelectronics STTH1R04A 100V, 200mA Low capacitance small signal Schottky diode SOD-123 STMicroelectronics BAT41ZFILM BAT30SWFILM D20, D21, D22 BAT30SW Small signal Schottky diodes SOT-323 STMicroelectronics D23, D24, D25 BAS21J Single high-speed switching diode SOD323F (SC-90) nexperia N.M. Time Lag radial lead Micro Fuse, 250Vac F1 10A/277V slow Suface Mount Fuse, Time-Lag T, 250Vac125Vdc JP1 CLOSED 2-3 SMT Jumper Soldering pad JP2 OPEN SMT Jumper Soldering pad F1A JP3, JP4 JP5 JP6, JP7, JP8 CLOSED 1-2 OPEN CLOSED 2-4 JP9 OPEN JP10 CLOSED 2-4 J1, J7, J9 J2 J3 DB4379 - Rev 1 STRIP 1x4 Strip connector 3 pos, 2.54 mm RST-BELFUSE belfuse UMT250SHURTER BAS21J 0697-xx Schurter 3403.0176.24 WURTH ELEKTRONIK 61300311121 1x4 pins WURTH ELEKTRONIK 61300411121 3 poles, Pitch 5.08 WURTH ELEKTRONIK 691213510003 1x5 pins WURTH ELEKTRONIK 61300511121 1x3 pins SMT Jumper Soldering pad Jumper to solder Soldering pads SMT jumper Jumper to solder Strip connector 4 pos, 2.54 mm MORSV-508-3 Connector terminal block T.H. 3 P_screw positions 5.08 mm STRIP 1x5 TPS Series SMA D2, D3, D5, D6, D8, D9, D10, D11, D12, D13, D26, D27, D28 D19 AVX LGN2E271MELZ25 Strip connector 5 pos, 2.54 mm Soldering pads page 8/20 EVSPIN32F02Q1S1 Bill of materials Reference Part Value Description J4 MORSV-508-2 Connector terminal block T.H. 2 P_screw positions 5.08 mm J5 65100516121 J6 STRIP 1x2 J8 closed LD1, LD2 YELLOW LD3 RED LD5 RED-GREEN LD4 GREEN L1 NTC1 330uH 5R Q1, Q3, Q4, Q6, Q7, Q9 STD17NF25 Q1A, Q3A, Q4A, Q6A, Q7A, Q9A N.M. Package Part Number 2 poles, Pitch 5.08 WURTH ELEKTRONIK 691213510002 Mini USB B WURTH ELEKTRONIK 65100516121 Strip connector 2 pos, 2.54 mm 1x2 pins WURTH ELEKTRONIK 61300211121 Strip connector 2 pos, 2.54 mm 1x2 pins WURTH ELEKTRONIK 61300211121 Yellow LED Size 0603 WURTH ELEKTRONIK 150060YS75000 Red LED Size 0603 WURTH ELEKTRONIK 150060RS75000 MINI USB 2.0 TYPE B SMD LED indicators, PLCC-4 Red/ Yellow Green Green LED PLCC 4 Size 0805 SMD Power inductors for Automotive/Industrial applications NTC Thermistors for inrush current limiting N-channel 250 V, 0.140 O typ., 17 A STripFET™ II Power MOSFETs Pitch 5.08 mm AVAGO HSMF-A201-A00J1 WURTH ELEKTRONIK 150080GS75000 TAIYO YUDEN EST1060T331MDGA TDK B57235S0509M000 DPAK STMicroelectronics PowerFLAT 6x5 STMicroelectronics GENERAL PURPOSE_45V_100mA_225mW SOT23 ON SEMICONDUCTOR BC847BL Low voltage high performance NPN power transistor SOT-89 STMicroelectronics 3STF1640 N-channel Power MOSFET Q10 BC847 Q11 3STF1640 RV1 N.M. Varistor R1, R15, R35 27R SMT resistor Size 0805 R2, R10, R16, R27, R40, R49 10R SMT Resistor Size 0805 R3, R13, R18, R30, R42, R56 100R SMT Resistor Size 0805 R5, R14, R19, R31, R44, R57, R99, R100, R106 100k SMT resistor Size 0603 R6, R21, R45 56k SMT Resistor Size 1206 R8, R22, R47 39k SMT Resistor Size 1206 R12, R28, R53, R68, R70, R71 1.8k SMT Resistor Size 0603 R23 100k Square trimpot trimming potentiometer R25, R51, R52, R63, R64, R65, R84, R97, R110 10k SMT Resistor Size 0603 R26, R29, R58, R59, R73, R89, R91, R93, R95 0R SMT Resistor Size 0603 R32 47k SMT Resistor Size 0603 DB4379 - Rev 1 Manufacturer STD17NF25 Pitch 2.3x7.5 mm 3386P BOURNS 3386P-1-104-LF page 9/20 EVSPIN32F02Q1S1 Bill of materials Reference R33 Part Value Description Package 63.4k SMT Resistor Size 0603 75m-2W-1% SMT Resistor Size 2512 1k SMT resistor Size 0603 N.M. SMT Resistor Size 0603 R41, R55 3k SMT Resistor Size 0603 R48 39k SMT Resistor Size 0603 100R SMT resistor Size 0603 R60 33k SMT Resistor Size 0603 R61 10M SMT Resistor Size 0603 R62, R77 120R SMT Resistor Size 0603 R67, R69 470k SMT Resistor Size 1206 R72 N.M. NTC Resistor Size 0805 R81, R88, R92, R94 4.7k SMT Resistor Size 0603 R78 27k SMT Resistor Size 0805 R80 68k SMT Resistor Size 0805 R82 330R SMT Resistor Size 0603 R83 1.5k SMT Resistor Size 1206 R86 1.5k SMT Resistor Size 0603 R87 36k SMT Resistor Size 0603 R90, R109 2.7k SMT resistor Size 0603 R103 0R SMT Resistor Size 0603 R105 15k SMT resistor Size 0603 R107 8.66k SMT resistor Size 0603 R108 0R SMT resistor Size 0805 R115, R116, R117 1M SMT resistor Size 0603 R121 8K2 SMT resistor Size 0603 R34, R36, R111 R38, R118, R119, R120 R39, R74, R75, R76, R98, R104 R54, R66, R79, R85, R96, R101, R102, R112, R113, R114 SW1, SW2, SW3 430483025816 TACTILE SWITCHES - 6x6 Jbend SMT WURTH ELEKTRONIK TP1 TPHIN1 Test Point - PCB 1mm DIAMETER Copper Pad TP2 TPHIN2 Test Point - PCB 1mm DIAMETER Copper Pad TP3 TPHIN3 Test Point - PCB 1mm DIAMETER Copper Pad TP4, TP7, TP14, TP17, TP18, TP19, TP20, TP21, TP22, TP23, TP24, TP25 N.M. TP for Probe Diam. 1.27, Hole 0.8mm TP5 PB8 Test Point - PCB 1mm DIAMETER Copper Pad DB4379 - Rev 1 Manufacturer Part Number 430483025816 page 10/20 EVSPIN32F02Q1S1 Bill of materials Reference TP6 TP8, TP12 Part Value PA4 Description Test Point - PCB 1mm DIAMETER Package TPTHTHT Ring Test Point ANELLO-1mm Keystone PA3 Test Point - PCB 1mm DIAMETER Copper Pad TP11 PA7 Test Point - PCB 1mm DIAMETER Copper Pad TP13 GPIO_ZCR Test Point - PCB 1mm DIAMETER Copper Pad TP15 NEEDLEPAD-1.7mm Test Point - PCB 1.7mm DIAMETER Copper Pad TP16 PGND Test Point - PCB 1mm DIAMETER Copper Pad STSPIN32F02 250V three-phase controller with 51Q ARM Cortex MCU Part Number Copper Pad TP10 U1 Manufacturer QFN72-10X10 STMicroelectronics 5003 STSPIN32F0251Q/TR U2 TSV911ILT Single Rail-to-Rail input/output 8 MHz operational amplifiers SOT23-5 STMicroelectronics TSV911ILT U3 TS3704IPT Micropower quad CMOS voltage comparators TSSOP14 STMicroelectronics TS3704IPT SOT-223 STMicroelectronics LD1117S33CTR U4 800mA, 3.3V Adjustable and LD1117S33CT Fixed low drop positive voltage R regulator U5 USBLC6-2SC6 Very low capacitance ESD protection SOT23-6L STMicroelectronics USBLC6-2SC6 / Y U6 LD3985M33R Ultra low drop and low noise BiCMOS voltage regulators SOT23-5L STMicroelectronics LD3985M33R U7 STM32F103C BT6 Medium-density performance line ARM®-based 32-bit MCU with 128 KB Flash, USB, CAN, 7 timers, 2 ADCs, 9 com. interfaces LQFP48 - 7x7 mm STMicroelectronics STM32F103CBT6 U8 VIPer013 SSOP10 STMicroelectronics VIPer013BLS/TR X1, X2 J8, JP3, JP4 8MHz Energy saving off-line high voltage converter CRYSTAL 8.0000MHZ 8PF SMD NDK Rubber feet Hammond Female Jumper Isolated, pitch 2.54mm ASSMANN WSW P.C.B. EVSPIN32F02Q1S1 Rev.1.0 DB4379 - Rev 1 2.5x3.2 mm 75.2x143 mm NX3225GD-8MHZ-STDCRA-3 1421T6CL AKSCT/Z BLACK STMicroelectronics page 11/20 EVSPIN32F02Q1S1 Layout and component placements 4 Layout and component placements Figure 5. EVSPIN32F02Q1S1 - functional blocks Warning The kit is not electrically isolated from the AC/DC input. The USB interface of the board does not insulate host computer from high voltage. When the board is supplied at a voltage outside the ELV range, a proper insulation method such as a USB isolator must be used to operate the board. DB4379 - Rev 1 page 12/20 EVSPIN32F02Q1S1 Layout and component placements Figure 6. EVSPIN32F02Q1S1 – Layout (component placement top view) DB4379 - Rev 1 page 13/20 EVSPIN32F02Q1S1 Layout and component placements Figure 7. EVSPIN32F02Q1S1 – Layout (top layer) DB4379 - Rev 1 page 14/20 EVSPIN32F02Q1S1 Layout and component placements Figure 8. EVSPIN32F02Q1S1 – Layout (bottom layer) DB4379 - Rev 1 page 15/20 EVSPIN32F02Q1S1 Revision history Table 2. Document revision history DB4379 - Rev 1 Date Version 14-Dec-2020 1 Changes Initial release. page 16/20 EVSPIN32F02Q1S1 Contents Contents 1 Safety and operating instructions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1.1 General terms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1.2 Intended use of evaluation board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1.3 Installing the evaluation board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1.4 Operating the evaluation board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2 Schematic diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4 3 Bill of materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7 4 Layout and component placements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16 Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17 List of tables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18 List of figures. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19 DB4379 - Rev 1 page 17/20 EVSPIN32F02Q1S1 List of tables List of tables Table 1. Table 2. EVSPIN32F02Q1S1 Bill of Materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 Document revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 DB4379 - Rev 1 page 18/20 EVSPIN32F02Q1S1 List of figures List of figures Figure 1. Figure 2. Figure 3. Figure 4. Figure 5. Figure 6. Figure 7. Figure 8. DB4379 - Rev 1 EVSPIN32F02Q1S1 schematic – Driver output stages. . . . . . . EVSPIN32F02Q1S1 schematic – Feedback network . . . . . . . . EVSPIN32F02Q1S1 schematic – Power Supply . . . . . . . . . . . EVSPIN32F02Q1S1 schematic – STLINK debugger . . . . . . . . EVSPIN32F02Q1S1 - functional blocks . . . . . . . . . . . . . . . . . EVSPIN32F02Q1S1 – Layout (component placement top view) EVSPIN32F02Q1S1 – Layout (top layer) . . . . . . . . . . . . . . . . EVSPIN32F02Q1S1 – Layout (bottom layer) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 . 4 . 5 . 6 12 13 14 15 page 19/20 EVSPIN32F02Q1S1 IMPORTANT NOTICE – PLEASE READ CAREFULLY STMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement. Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products. No license, express or implied, to any intellectual property right is granted by ST herein. Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product. ST and the ST logo are trademarks of ST. For additional information about ST trademarks, please refer to www.st.com/trademarks. All other product or service names are the property of their respective owners. Information in this document supersedes and replaces information previously supplied in any prior versions of this document. © 2020 STMicroelectronics – All rights reserved DB4379 - Rev 1 page 20/20