SPRAD58A September   2022  – February 2023 AM2631 , AM2631-Q1 , AM2632 , AM2632-Q1 , AM2634 , AM2634-Q1 , UCC14130-Q1 , UCC14131-Q1 , UCC14140-Q1 , UCC14141-Q1 , UCC14240-Q1 , UCC14241-Q1 , UCC14340-Q1 , UCC14341-Q1 , UCC15240-Q1 , UCC15241-Q1 , UCC5870-Q1 , UCC5871-Q1 , UCC5880-Q1

 

  1.   Abstract
  2. Introduction
  3. Architectures and Trends
  4. Key Technology to Enable Traction Inverters
  5. Microcontroller
    1. 4.1 Sitara Family
    2. 4.2 C2000 Family
  6. Isolated Gate Drivers
  7. Low-Voltage Bias Supplies
  8. High-Voltage Bias, Redundant Supply
  9. DC Link Active Discharge
  10. Motor Position Sensing
  11. 10Isolated Voltage and Current Sensing
  12. 11System Engineering and Reference Designs
  13. 12Conclusion
  14. 13References

8 DC Link Active Discharge

Every EV traction inverter requires a DC link active discharge as a safety-critical function. The discharge circuit is required to discharge the energy in the DC link capacitor under the following conditions and requirements:

  • In an emergency situation or during repairs, the voltage in the system must be safe to touch in less than 2 s
  • At vehicle key-off, the DC link capacitor must remain discharged
  • System-level safety requirement ASIL D
  • Shall be able to operate independently from the MCU, in case of MCU failure

TI has several active discharge designs targeted for different system-level requirements:

  • Power transistor on, off control using the TPSI3050-Q1. The TPSI3050-Q1 reinforced isolated switch driver has an integrated 10-V gate supply that can drive the discharge power switches with no need for a secondary bias supply.
  • Controlled PWM using the AFE539F1-Q1 device. The AFE539F1-Q1 smart AFE has built-in nonvolatile memory for PWM and custom waveform generators. The device has added programmability and logic which eliminates the need for software filling the gap between DAC-based circuits, MCU-based circuits, and entirely discrete circuits. #FIG_UKL_MCZ_N5B and #FIG_GCM_5CZ_N5B show a design block diagram and testing waveforms.



Figure 8-1 DC Link Active Discharge Based on the Smart AFE
CH1: AFE539F1-Q1 output
CH2: Gate driver (UCC27531-Q1) PWM output
CH3: DC link voltage after resistive divider
CH4: SiC FET drain-to-source current
Figure 8-2 Testing Waveforms
  • Discharge through the power stage by linear biasing or PWM-based pulsed-linear switching on the power module to constitute a short circuit. TI’s isolated gate driver with tri-state capability enables active discharge through a power module using discrete analog circuits. The discharge profile is mirrored to a current source reference across a capacitor, where a 100-µA constant current sink is representing 1-A constant discharge current. A gate voltage regulator regulates the gate-to-source voltage and drives the power module into the linear region.
  • Energy discharge through the motor winding. Dividing a winding-based discharge into multiple stages is possible. These stages include a rapid discharge stage or a bus voltage regulation stage. Generating large d-axis current quickly reduces the DC link energy, while the q-axis current must be at zero. Fast loop control from TI’s Sitara or C2000 MCU and safety isolated gate driver include Serial Peripheral Interface (SPI) programmability, Six ADC channels provides a reliable and smoothly controlled discharge.