AU
U011887

DTC U011887 is a U-category CAN bus communication fault indicating a subnet communication interruption between the AC Controller and the Battery Cooling Controller (BCC) — Seal U

Thermal Management System

DTC U011887 is a U-category CAN bus communication fault indicating a subnet communication interruption between the AC Controller and the Battery Cooling Controller (BCC).

In the BYD Qin EV300 architecture, the air conditioning system uses an independent CAN subnet.

The BCC manages the battery pack liquid cooling system, controlling components such as the battery cooling water pump and the battery cooler three-way valve.

The AC Controller requires real-time cooling demand and status information from the BCC to coordinate refrigerant distribution between the cabin air conditioning and the battery cooling system.

The AC Controller triggers this DTC when it fails to receive valid CAN messages from the BCC for a continuous period (typically multiple message cycles of 100–200 ms).

These messages include IDs containing signals for battery cooling requests, temperature, and flow rate.

This fault forces the thermal management system into a degraded mode.

This limits battery cooling capacity, which may reduce fast charging speeds or cause battery overheating.

The air conditioning system may also forcibly restrict cooling output or enter limp-home protection mode.

However, this fault typically does not cause a complete vehicle breakdown.

4
Cases Logged
5
Causes
Likely Causes — Seal U
  • 1A/C sub-network CAN wiring harness fault: CAN-H or CAN-L circuit open, short to ground, short to power, or poor connection in the high-temperature, high-humidity front compartment environment. Water ingress or mud contamination corrodes the wiring harness, especially near the right front wheel arch (common BCC mounting location).
  • 2BCC power supply or ground fault: A blown BCC constant power (+B) fuse, poor relay contact, or a loose or oxidized ground point (G point) causes the controller to intermittently lose power or reset, failing to maintain CAN communication.
  • 3Poor connector contact: An aging seal ring on the BCC 24-pin (or 32-pin) connector causes pins (especially CAN communication pins) to back out, oxidize, or corrode due to water ingress, interrupting signal transmission.
  • 4BCC internal fault: Damaged controller internal CAN transceiver chip (TJA1042 or similar model), power management chip failure, or software crash preventing message transmission.
  • 5Abnormal terminating resistance: The air conditioning sub-network contains a 120Ω terminating resistor at the BCC or AC end. An open circuit or resistance drift (due to water ingress) causes CAN signal reflection, degrades communication quality, and eventually interrupts communication.
What To Do
  • 1
    Freeze frame analysis: Use VDS2000/3000 or a dedicated BYD diagnostic tool to read the fault freeze frame. Confirm vehicle speed, ambient temperature, and air conditioning status at the time of the fault. Determine if the fault is intermittent (e.g., after driving on rough roads or wading).
  • 2
    Basic power supply check: Disconnect the BCC connector and measure the voltage at the BCC power supply pins (usually pins 1/2 are +B, pins 3/4 are ground). Voltage must be 12V±0.5V and ground resistance must be less than 1Ω. Inspect the BCC-related fuse in the front compartment power distribution box (e.g., F1/16 15A) for blown elements or poor contact.
  • 3
    CAN bus physical layer check: Measure the terminating resistance between CAN-H (usually Pin11 or Pin21, yellow wire) and CAN-L (usually Pin22 or Pin12, green wire) at the BCC connector. Turn off the ignition switch. The resistance should be approximately 60Ω (two 120Ω resistors in parallel). A 120Ω reading indicates a missing terminating resistor on one side. An infinite reading indicates an open circuit. A 0Ω reading indicates a short circuit.
  • 4
    CAN line voltage and waveform check: Turn the ignition switch ON. Measure CAN-H to ground voltage (2.5-2.7V) and CAN-L to ground voltage (2.3-2.5V). The difference is approximately 0.2V. Use an oscilloscope to verify the waveform is a standard CAN waveform without distortion or noise interference.
  • 5
    Harness continuity and insulation test: Measure CAN line continuity from the air conditioning controller to the BCC; resistance must be less than 1Ω. Measure CAN line insulation resistance to the vehicle body; resistance must be greater than 10MΩ. Inspect the harness sleeve for damage, specifically at the front longitudinal beam and firewall pass-through points.
  • 6
    Substitution verification: If the wiring harness is normal, first update the BCC software to the latest version. If unsuccessful, cross-check the BCC unit by substitution (swap with the same vehicle model or install a new part). Finally, verify the air conditioning controller.
  • 7
    Fault Clearing and Road Test Verification: After repair, clear the fault code and perform a road test of at least 20 km, including bumpy roads, maximum A/C cooling mode, and DC fast charging conditions. Verify the fault does not recur.
Real-World Cases
BYD DTC AI Analysis

Worn wiring harness in right front wheel arch caused intermittent communication interruption

A 2017 Qin EV300. The customer reported the air conditioning suddenly blew hot air when driving on rough roads, and the coolant temperature warning light on the instrument panel lit intermittently. The scan tool retrieved U011887 (current fault) and U011187 (history fault). Inspection found the BCC mounted behind the right front wheel arch liner; its harness retaining clip had detached, allowing the harness to rub against the wheel arch metal edge when the vehicle hit bumps. This wore through the CAN-L wire insulation and caused an intermittent open circuit. Soldered and heat-shrunk the harness, re-secured the routing with cable ties, and added a rubber protective sleeve. Fault resolved.
BYD DTC AI Analysis

Water ingress corroded BCC connector, causing communication failure

After driving through standing water in the rain, the A/C stopped cooling. Scanner read DTC U011887, which would not clear. Found the BCC mounted low in the front compartment. The connector seal had aged and deformed, letting moisture enter during the water crossing. Green corrosion formed on the CAN communication pins (Pin11 and Pin22), raising contact resistance to 15Ω (normal <0.5Ω). Cleaned the pins with precision electrical contact cleaner, applied dielectric grease, installed a new waterproof seal, and wrapped the connector with waterproof tape. Resistance read normal after reconnecting; fault cleared.
BYD DTC AI Analysis

Air conditioning subnet termination resistor missing after accident repair

Following front-end collision repairs, a Qin EV300 displayed multiple communication faults including U011887 and U012E87 (lost communication with electronic fan). After replacing the front compartment wiring harness, the technician failed to connect the air-conditioning sub-network twisted pair correctly and did not replace the 120Ω termination resistor at the BCC that was damaged in the accident. CAN resistance measured infinite, confirming the missing termination resistor. Replacing the BCC (with built-in termination resistor) restored total resistance to 60Ω, cleared all communication fault codes, and returned air-conditioning and thermal management functions to normal.
BYD DTC AI Analysis

Poor contact at BCC power fuse holder

The vehicle failed to start after DC fast charging, with DTC U011887 and BMS-related faults stored. Inspection found the BCC power supply fuse base (front compartment fuse box F1/16 15A) had contact spring fatigue from repeated insertion and removal, causing excessive contact resistance (measured 8Ω). During high-current fast charging, this dropped the BCC supply voltage below 9V, interrupting communication. Replaced the fuse box base and fuse; supply voltage now stable at 12.4V. Fault eliminated.
Other Seal U 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.