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SimpleFOC DriveShield v1.2

License: MIT GitHub release (latest by date) GitHub Release Date

This is an open-source low-cost BLDC driver boards in the form of a Arduino shield. It is a part of the SimpleFOC project. The board is the big brother of the SimpleFOCShield and is designed to drive motors with higher current requirements, up to 30Amps. The board is created with the same philosophy as the SimpleFOCShield - to be simple to use, low-cost, and open-source and fully compatible with the SimpleFOClibrary.

Additionally the aim of the board is to serve as a template project for the community to build their own motor drivers.

  • The board is relatively simple and can be easily modified to fit different requirements.
  • The board is designed in EasyEDA and all the fabrication files are available for download

Components

  • DRV8320H gate driver
    • Hardware configuration
    • 3PWM
    • Protections: undervoltage lockout, charge pump fault, MOSFET overcurrent, MOSFET short circuit, gate driver fault and overtemperature
  • BSZ0904NSI mosfets
    • Standard 3mm x 3mm footprint (can be easily exchanged)
    • Max current 75A
    • Max voltage 30V
  • ACS712:
    • 30Amps bidirectional
    • In-line current sensing

Features

  • Boards absolute max ratings
    • Max current: 20A continuous (peak 30A - measured)
    • Max input voltage: 30V
  • Stackable: running 2 motors in the same time
  • Encoder/Hall sensors interface: Integrated 3.3kΩ pullups (configurable)
  • I2C interface: Integrated 4.7kΩ pullups (configurable)
  • Configurable pinout: Hardware configuration - soldering connections
  • Arduino headers: Arduino UNO, Arduino MEGA, STM32 Nucleo boards...
  • Open Source:
  • Low-cost: Estimated price of 25-40€ - Will be available in the SimpleFOC shop

Shield version comparison

Feature SimpleFOCShield v1.x SimpleFOCShield v2.x SimpleFOCShield v3.x SimpleFOC DriveShield v1.x
PWM Driver L6234 L6234 DRV8313 gate driver: DRV8320H
mosfets: BSZ0904NSI
Current Sense INA240 ACS712 (5A) ACS712 (30A)
Current measurement range (configurable) ±3.3/5Amps ±5Amps ±30Amps
Onboard LDO LM7808 LM7808
Stackable ✔️ ✔️ ✔️ ✔️
Max current 2Amps (5Amp peak) 2Amps (5Amp peak) 2Amps (3Amp peak) 20Amps (30Amp peak)
Max voltage 24V 35V 35V 30V
Protections Overtemperature Overtemperature Overtemperature, Overcurrent undervoltage lockout, charge pump fault, MOSFET overcurrent, MOSFET short circuit, gate driver fault, overtemperature
Footprint 68mm x 53 mm 68mm x 53 mm 56mm x 53mm 56mm x 53mm
Design tool Altium Designer 2019 Altium Designer 2019 EasyEDA EasyEDA

Board evolution timeline

To check the release timeline, click here

Version release Release date Comment
SimpleFOC DriveShield v1.0 v0.1 05/24 - Test version
- DRV8300 gate driver
- SE3082G dual mosfets
- ACS712 (range +-30Amps)
- 20V max voltage
SimpleFOC DriveShield v1.0 v1.0 06/24 - Transition to DRV8320H gate driver
- 30V max voltage
SimpleFOC DriveShield v1.1 v1.1 07/24 - Transition to 3x3mm BSZ09x mosfets instead of SE3082G
- 30V max voltage
SimpleFOC DriveShield v1.2 v1.2 08/24 Initial release
- Transition to 4 layer PCB
- Enabling stacking (soldering pads)
- Configurable pullups (I2C and encoder)

Size comparison with SimpleFOCShield v3

Temperature characteristics

This board can measure the phase currents up to 30Amps, so it is intended to be used in applications that require current draw up to around 20Amps continuous. For higher currents especially in the range of 15-30Amps the board can get quite hot. Depending on the copper thickness of the PCB chosen when ordering the board the temperature can vary, as well as the cooling conditions. The board can be fitted with a heatsink to improve the thermal performance.

So I've wanted to quantify the temperature characteristics of the board when a continuous current is applied to the motor. The measurements were done with a relatively constant ambient temperature of around 25°C. The board was powered with 24V. The motor was run at very low speed (0.1rad/s) in the open loop and the current (q component) was set to 10, 15 and 20 amps for prolonged periods of time. I've measured the temperature on the top of the board on the DRV8320H gate driver and the BSZ0904NSI mosfets. I've used the PICOLOG TC-08 thermocouple data logger to do the measuring.

Two copper thicknesses were tested

  1. Standard 4-layer:
    • 1oz (35um) copper thickness on top and bottom layers,
    • 0.5oz (17.5um) copper thickness on inner layers

  1. Thick 4-layer:
    • 2oz (70um) copper thickness on top and bottom layers,
    • 0.5oz (35um) copper thickness on inner layers

Experiment results

Here is the table of the results

Current [A] Standard 4-layer MOSFETS Thick 4-layer MOSFETS Standard 4-layer DRV8320 Thick 4-layer DRV8320
10 57°C 53°C 50°C 52°C
15 78°C 68°C 62°C 62°C
20 125°C 100°C 82°C 82°C

So the results seem to suggest that, as the BSZ0904NSI mosfets are rated for temperatures up to 150°C and the DRV8320H gate driver up to 125°C, the board can be used up to 20Amps without additional cooling.

However, I would definitely recommend using a heatsink or a thicker copper PCB (2oz top and bottom layers) for currents above 15Amps continuous.

Measured temperatures during the experiment