B162212
DTC B162212 indicates abnormal continuity between the squib circuit of the driver side airbag (usually the seat-mounted side airbag) and the vehicle positive power supply (B+, battery voltage) — Atto 3
Safety System
DTC B162212 indicates abnormal continuity between the squib circuit of the driver side airbag (usually the seat-mounted side airbag) and the vehicle positive power supply (B+, battery voltage).
In the SRS (Supplemental Restraint System) control logic, the airbag squib circuit must maintain a high-impedance open state at rest.
The control unit determines circuit integrity by monitoring circuit voltage.
Detecting a short to power in this circuit indicates damaged wiring insulation contacting a constant power wire, or an insulation failure of the igniter coil inside the airbag module.
This fault immediately forces the SRS into fail-safe mode, which: 1) Disables the driver side airbag, preventing deployment during a side impact; 2) Illuminates the airbag warning lamp; 3) Creates a risk of unintended airbag deployment in extreme cases (despite multiple protections in modern systems).
Because it involves a core component of the passive safety system, this fault classifies as severe and requires immediate repair.
Likely Causes — Atto 3
- 1Mechanical damage to the wiring harness under the seat: The driver-side airbag wiring harness moves forward and backward with the seat. Repeated bending or crushing by foreign objects (such as coins or toys) wears through the insulation, causing a short circuit to the seat heater wire or constant power wire.
- 2SRS connector water ingress and corrosion: Liquid enters the yellow dedicated SRS connector under the seat during vehicle wading or interior cleaning, causing an electrolytic short circuit between the terminals, or verdigris creates continuity between the power supply terminal and the airbag circuit terminal.
- 3Internal short circuit in the airbag module: Aging, static electricity, or manufacturing defects damage the igniter (Squib) internal coil insulation, causing the primary coil to contact the secondary coil or housing and create a short to power.
- 4Improper post-accident repair: Failing to replace the damaged wiring harness to specification after a collision or using non-genuine parts causes incorrect wire routing, leaving the airbag circuit parallel to the power supply circuit with insufficient insulation.
- 5Internal SRS control unit fault: A damaged MOSFET or sampling resistor in the internal monitoring circuit falsely reports a short to power, or an internal drive circuit fault actually shorts the circuit to power.
What To Do
- 1Safe power-down: Turn off the ignition, disconnect the negative battery cable, and wait at least 3 minutes (some models require 90 seconds, but BYD SRS capacitor discharge usually takes 3 minutes) to fully discharge the system.
- 2Fault status confirmation: Connect the BYD dedicated diagnostic tool (VDS2000 or EDT). Enter the SRS system to read fault codes. Confirm B162212 is a current fault (Current DTC). Check the voltage value in the freeze frame data (usually displays as 12V or battery voltage).
- 3Visual and physical inspection: Inspect the yellow SRS connector under the driver's seat (usually on the outside of the seat slide rail or at the seat base) for signs of water ingress, terminal corrosion, and bent pins. Check the wiring harness for wear or damaged insulation within the seat's travel range.
- 4Circuit isolation test: Disconnect the driver-side airbag module connector (remove the seat side trim panel or backrest cover). Use the dedicated shorting bar to short the harness-side connector and measure the harness-side voltage. If battery voltage remains, the fault is in the wiring harness; if it reads 0V, the fault is in the airbag module.
- 5Harness continuity check: Disconnect the SRS control unit connector (usually located in the center tunnel or under the dashboard). Use a multimeter to measure continuity between the driver side airbag ignition wire (usually a yellow harness; refer to the wiring diagram for model-specific pin assignments) and the power supply (B+) and ground to check for short circuits.
- 6Insulation resistance measurement: Use a megohmmeter (500V range) to measure the insulation resistance between the airbag ignition circuit and other power supply circuits. Normal resistance is greater than 10MΩ. Resistance below 1MΩ confirms insulation damage.
- 7Component replacement verification: If testing confirms an internal short circuit in the airbag module, replace the driver side airbag module (Note: Use only certified replacement parts of the same model and batch). If testing confirms a wiring harness fault, repair the damaged section and reinforce it with corrugated conduit and fabric tape. Leave sufficient slack at seat movement points.
- 8System reset and matching: Reconnect all connectors, connect the battery, and turn the ignition switch to ON (do not start). Use the diagnostic tool to clear fault codes and perform an SRS system self-diagnosis. On some models, perform a 'Configuration and Setting' or 'Coding' operation to write the new airbag module parameters.
- 9Function check: Confirm the airbag warning lamp turns off after the 6-second self-check. Read the data stream: the 'driver side airbag resistance value' must be between 2.0 and 3.0 Ω, and the voltage must be 0 V (static). Move the seat forward and backward to confirm no wiring harness interference.
Real-World Cases
Seat adjustment chafed the wiring harness, causing a short circuit.
Model: Qin Pro DM 2019. Customer reported the airbag warning light staying on. Scan tool read current DTC B162212. Inspection revealed the wiring harness under the driver's seat was pinched when the seat track was in the fully forward position. The yellow airbag wire insulation had chafed through and contacted the red seat heater power wire, causing a short circuit. Repair: replaced the entire damaged harness section, rerouted the cable path, added protective sleeving at flex points, and ensured no interference through full seat travel. After clearing the DTC, the system returned to normal. Resistance: 2.4Ω.
Connector corroded and shorted after wading
Vehicle: BYD E2 2019. The vehicle waded through water about 30 cm deep, after which the SRS warning light came on. DTCs B162212 and B162213 (short to ground) appeared alternately. Removed the driver's seat and found the SRS connector (yellow) contained obvious water stains and corrosion; insulation resistance between terminals had dropped to 0.5 MΩ. Repair: Cleaned the connector using precision electrical contact cleaner, blew it dry, applied specialised electrical contact protectant, and replaced the waterproof seal. The airbag module sustained no damage, and the fault cleared after the repair. Recommend checking the vehicle floor sealing.
Wiring incorrectly connected after accident repair
Vehicle: Qin EV 2019. After left front collision repairs, the airbag warning light stayed on. DTC B162212 retrieved. Inspection found that during the repair, an unauthorised workshop swapped the side airbag and seat heater connectors when replacing the seat (same pin count, different colours). This connected the airbag circuit directly to 12V power. Fix: Corrected the connector connections, checked the airbag module (resistance measured 2.2Ω, normal), cleared the fault codes, and the system returned to normal. Note: BYD SRS connectors have mechanical keying; forcing them may cause damage.
Replaced airbag module due to internal short circuit
Vehicle: BYD E3 2020. The airbag warning light illuminated suddenly while driving without collision impact. Fault code B162212. Disconnected the SRS control unit in the engine compartment and the wiring harness under the seat. Measured separately: the wiring harness side showed good insulation to ground and to power supply (>20MΩ), with infinite resistance. At the airbag module side, measured continuity between the igniter terminals and the housing, confirming an internal short circuit. Repair: Replaced the driver's seat side airbag module (required dismantling the seat backrest; gas generator retaining torque: 7.5 N·m). Performed online matching and programming after replacement. Fault resolved.
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]