AU
B121A09

DTC B121A09 indicates a functional failure of the No — Seal 6 EV

Thermal Management System

DTC B121A09 indicates a functional failure of the No. 1 IGBT (Insulated Gate Bipolar Transistor) driver chip in the PTC (Positive Temperature Coefficient) heater controller.

In BYD new energy vehicle thermal management systems, the PTC heater functions as a high-voltage electric heating component for cabin heating and power battery preheating.

The IGBT module regulates heater power via PWM (Pulse Width Modulation) control.

The driver chip serves as the key interface between the controller MCU and the power IGBT.

It converts low-voltage logic signals into isolated high-voltage pulses (typically ±15V or 0-15V) to drive the IGBT gate.

Fundamentally, this fault indicates the driver chip cannot generate or transmit the gate drive signal.

Possible causes include internal chip damage, abnormal driver power supply, IGBT module fault feedback, or communication interruption.

This fault prevents the PTC heater from starting (no warm air) or causes power control loss.

In extreme cases, it may cause IGBT breakdown and short circuits, triggering high-voltage system protection and posing safety risks.

Therefore, the system classifies it as a severe fault (Level 3).

5
Cases Logged
5
Causes
Likely Causes — Seal 6 EV
  • 1Physical damage to the IGBT driver chip: Internal short circuit in the PTC heater, insulation failure, or high-voltage surge causes overcurrent or overvoltage, burning out the driver chip.
  • 2Drive circuit power supply abnormal: 15V or 12V drive power module (DC-DC converter) failure, filter capacitor failure, or Zener diode breakdown, causing drive chip operating voltage loss or fluctuation.
  • 3Internal IGBT power module fault: IGBT gate breakdown, collector-emitter short circuit, or open circuit causes the driver chip to detect overcurrent or an abnormal saturation voltage drop, triggering protection mode or causing secondary damage.
  • 4Thermal management failure: A loose PTC controller heat sink, dried thermal grease, or a cooling system failure causes the driver chip to operate in a high-temperature environment (>125℃) for an extended period, resulting in thermal failure.
  • 5Wiring connector fault: Oxidation, backed-out pins, poor connections, or moisture corrosion in the low-voltage signal connector (especially the gate drive signal and fault feedback wires) interrupts drive signal transmission.
What To Do
  • 1
    Fault confirmation and software check: Use the VDS1000 or a dedicated BYD diagnostic tool to read all DTCs; check for accompanying fault codes such as B121809 (IGBT assembly function failure) and B121C09 (PTC overtemperature fault); record freeze frame data (PTC voltage, current, temperature, IGBT duty cycle); check the PTC controller software version and flash the latest software update first if available.
  • 2
    High-voltage safety and visual inspection: Wear insulated gloves, disconnect the high-voltage service disconnect (HVIL), and wait 5 minutes to allow the high-voltage bus voltage to discharge to <60V; visually inspect the PTC heater high-voltage cable insulation for damage, and measure the insulation resistance from the high-voltage positive and negative terminals to ground (standard value >500MΩ); inspect the PTC controller low-voltage 12V connector and high-voltage connector for oxidation, backed-out pins, or signs of water ingress.
  • 3
    Low-voltage power supply and signal measurement: Restore the low-voltage connection (do not restore high voltage). Switch power to ON. Measure the PTC controller low-voltage supply (constant B+, ignition IG, and ground GND) to verify the voltage is 11-14V. Verify the drive board 15V power output is stable. Use an oscilloscope to measure the MCU PWM control signal output and the driver chip gate drive waveform output, and verify the waveform amplitude and frequency.
  • 4
    IGBT module and driver board removal and inspection: Disconnect all connections and remove the PTC controller housing; visually inspect the IGBT module and driver chip for burn marks, cracking, or a burnt smell; use a multimeter in diode mode to measure the resistance between the IGBT gate (G) and emitter (E) (normal: 10-100Ω; short circuit or infinite resistance is abnormal), and measure for a short circuit between the collector (C) and emitter (E).
  • 5
    Component-level repair or assembly replacement: If only the driver chip (e.g., IR21xx series, ACPL-xxx optocoupler isolated driver) fails and repair resources permit, replace the driver chip with an identical model, along with the surrounding current-limiting resistors and clamping diodes. If the IGBT module shorts or the driver board shows extensive burning, replace the entire PTC controller assembly (PCU). If the PTC heater insulation fails (heater-to-housing resistance measures <20MΩ), replace the PTC heater simultaneously.
  • 6
    Function verification and vehicle handover: After reassembly, restore the high-voltage connection and clear the fault codes. Turn on the A/C heating mode and read the data stream to monitor: PTC requested duty cycle, actual duty cycle, PTC outlet temperature, and high-voltage current (normally 0-12A, varying with the selected level). Perform a 10-minute continuous heating test, confirm no fault codes return, and verify the controller temperature is normal before handing over the vehicle.
Real-World Cases
BYD DTC AI AnalysisFrom Chinese market (translated)

Qin EV300 No Heat in Winter - Drive Power Supply Module Failure

Model: 2017 Qin EV300, 80,000 km. Symptoms: After switching on the heater in winter, the vents kept blowing cold air. The dashboard showed "Thermal Management System Fault" and the warning lamp came on. Diagnosis: VDS scan retrieved DTC B121A09 (No.1 IGBT driver chip functional failure). No other fault codes stored. Measured PTC controller high-voltage input: 320 V, normal. 12 V low-voltage supply also normal. Disassembled the controller and probed the driver board: the 15 V driver power module output only 3.2 V, too low to drive the IGBT gate. Further inspection found the power module filter capacitor bulging and leaking electrolyte. Repair: The driver power supply is integrated into the control board, so replaced the complete PTC controller assembly (PN: BYD-PTC-XXXX). Programmed and matched the new controller, then road-tested. Heater operation returned to normal. Data stream confirmed the PTC duty cycle adjusting correctly with temperature setting.
BYD DTC AI AnalysisFrom Chinese market (translated)

Qin Pro DM: Poor cooling caused IGBT driver chip thermal protection

Model: 2018 Qin Pro DM, 120,000 km. Symptoms: While driving, after switching on the heater, the heating suddenly stopped and the instrument cluster displayed a fault. The system recovered after stopping and restarting, but the fault recurred more frequently with progressively shorter intervals. Diagnosis: Scanned code B121A09 — status 'Current/History'. Inspection found the PTC controller mounting bracket loose, a gap between the heatsink and controller housing, and the thermal grease dried and powdered. Infrared thermometer showed the IGBT module surface temperature reached 105°C (normal <80°C). IGBT characteristics were normal, but the driver chip temperature exceeded 125°C, triggering internal thermal protection. Repair: Re-tightened the PTC controller mounting bolts, cleaned off the old thermal grease, and applied fresh high-conductivity thermal grease (thermal conductivity >3.0 W/m·K), ensuring the heatsink made tight contact. Road tested for 30 minutes; temperature stabilised at 65°C. Fault resolved.
BYD DTC AI AnalysisFrom Chinese market (translated)

PTC short circuit after accident repair burned out the driver chip

Vehicle: 2019 BYD Qin Pro DM, repaired after a front-end collision. Fault Symptoms: After repairs, turning on the heater immediately triggered a thermal management system fault, with no heat output. Diagnosis: Retrieved DTCs B121A09 and B121809 (IGBT component functional failure). Measured PTC controller high-voltage input: normal. But the high-voltage positive-to-chassis insulation resistance was only 2 MΩ (normal >500 MΩ). Removed the PTC heater and found the internal ceramic PTC elements cracked from accident impact, causing a high-voltage short to chassis. Further inspection revealed the PTC controller driver chip had burned out from overcurrent, with visible charring on the surface. Solution: Replaced the PTC heater assembly (cracked beyond repair) and the PTC controller (driver chip damaged, IGBT breakdown). Replaced the high-voltage cable seals. Retested insulation resistance: >1000 MΩ. Fault completely resolved.
BYD DTC AI AnalysisFrom Chinese market (translated)

Driver IC pins corroded and open-circuited after wading

Model: Qin EV300, after wading through water. Symptoms: No cabin heat the next day, instrument cluster showing fault codes. Diagnosis: Retrieved DTC B121A09. Disassembled the PTC controller and found clear water ingress: mud residue on the PCB, green copper corrosion between pins 7 (Vo output) and 8 (Vcc) on the No.1 IGBT driver chip (HCPL-3120). Measured infinite resistance across the pins (should read a resistance value). Water seeped in through the wiring connector during wading, corroding the driver chip output stage and creating an open circuit. Repair: Cleaned the PCB thoroughly with electronic contact cleaner, then dried it. Replaced the optocoupler isolated driver chip with the same model and resoldered. Sealed the connector with RTV silicone. Road test OK; advised owner to avoid deep water.
BYD DTC AI AnalysisFrom Chinese market (translated)

Open circuit in gate drive resistor caused IGBT loss of control.

Vehicle: Qin Pro DM 2019. Symptoms: Heater output significantly insufficient; even set to 28°C with high fan speed, vents deliver only lukewarm air. DTC B121A09 stored. Diagnosis: Measured PTC high-voltage current at only 2A (normal high setting: 8–10A). Duty cycle displayed 95% but current did not follow. Oscilloscope showed normal MCU PWM output waveform, but no drive voltage waveform at IGBT gate. Inspected driver board – found surface crack on gate resistor (22Ω, 5W) in series with No.1 IGBT gate. Multimeter read open circuit (infinite resistance), blocking drive signal to IGBT gate. IGBT remained off, producing minimal heat from leakage current only. Resolution: Replaced gate resistor with a non-inductive type of the same power rating. IGBT gate waveform returned to normal (15V square wave). Road test confirmed heater output normal; fault resolved.
Other Seal 6 EV Fault Codes
B1108For the BYD Song MAX (2017–2019), DTC B1108 indicates a short circuit in the PM2.5 air quality detection module (dust sensor) or its wiring harness. The sensor uses laser scattering to detect in-cabin and outside PM2.5 concentrations and transmits data to the HVAC ECU via the LIN bus or an analog signal. Short circuit conditions include: 1) Sensor power supply wire (+5V/+12V) shorted to ground 2) Signal wire shorted to power or ground 3) Short circuit in the sensor's internal photoelectric detection circuit This fault prevents the automatic climate control from switching between fresh air and recirculation based on air quality. The system enters fail-safe mode (typically forced recirculation). Severe short-circuit current can destroy the HVAC ECU sampling circuit. The system classifies this as a Level 3 severe fault and restricts vehicle operation to prevent electrical fires or controller damage. For other BYD models (such as the Qin EV, E5, and Song DM), B1108 indicates a driver-side sunload sensor fault, reflecting differences in DTC definitions across models.B110811This DTC indicates a short circuit in the air conditioning system PM2.5 air quality sensor (rapid detector). Specifically, abnormal continuity exists between the sensor power supply circuit or signal output circuit and body ground or battery positive. This causes the control module (ACU/air conditioning controller) to detect abnormal current or a voltage signal outside the valid range (typically 0V or supply voltage). The PM2.5 sensor monitors internal and external particulate concentrations, providing the data the automatic air conditioning system uses to switch between fresh air and recirculation modes. A short circuit disables the air quality monitoring function. This fault may force the air conditioning system into recirculation protection mode and trigger related thermal management system faults, as the air conditioning system acts as a key actuator in vehicle thermal management. In severe cases, the short circuit current can damage the internal sampling circuit of the air conditioning controller or overheat the wiring harness.B1109DTC B1109 indicates an open circuit in the communication line between the air conditioning system PM2.5 air quality sensor (dust concentration sensor) and the air conditioning control unit (AC ECU), or an open circuit within the sensor internal circuitry. Typically located in the air conditioning intake duct, this sensor monitors real-time PM2.5 particle concentration inside and outside the vehicle. It provides data to the automatic air conditioning system for intelligent switching between fresh air and recirculation modes and for controlling the air purification device. During an open circuit fault, the AC ECU cannot receive the air quality signal, triggering the system fail-safe mode. Symptoms typically include failure of the automatic recirculation function, abnormal air purification indicator light operation, or abnormal air quality data displayed on the air conditioning panel. Severe cases may compromise the cabin environment control strategy, but do not directly affect vehicle driving safety.B110913DTC B110913 indicates an open signal circuit for the PM2.5 rapid detector (in-cabin air quality sensor). This sensor typically mounts inside the air conditioning system intake duct. It monitors in-cabin PM2.5 concentration in real time and provides data to the automatic air conditioning system for intelligent control of the air purification function. The BYD diagnostic protocol uses sub-code '13' to specifically indicate an open signal circuit. Although this fault theoretically affects a comfort feature, BYD Qin series vehicles classify it as a Level 3 (severe) fault. This classification occurs because the air conditioning system interacts with the battery thermal management system (e.g., monitoring battery cooling intake air quality). The fault can disable the automatic air conditioning mode and prevent the air purification function from operating. In extreme cases, it affects the battery compartment intake air quality assessment, triggering the 'repair immediately' strategy.B110AThis DTC indicates interrupted CAN bus communication or abnormal data between the air conditioning control unit (ACU) and the PM2.5 air quality sensor. The PM2.5 sensor monitors particulate concentration inside and outside the vehicle and provides the basis for purification control in the automatic air conditioning system. The ACU triggers this fault if it fails to receive a valid CAN message from the sensor within the specified period (usually 100-500 ms), if message verification fails, or if the signal frame times out. Although this fault does not affect vehicle driving safety, it disables the automatic air purification function. The air conditioning system cannot automatically switch between recirculation and fresh air modes or activate the air purification mode based on air quality. A persistent fault may restrict the thermal management strategy.
Data confidence: Official This information is for reference only. Always consult a qualified technician for diagnosis and repair. Do not attempt high-voltage system repairs yourself. Sources: [1]