P0C78

DTC P0C77 or P0C78

Diagnostic Instructions

* Perform the Diagnostic System Check - Vehicle Diagnostic System Check - Vehicle prior to using this diagnostic procedure.
* Review Strategy Based Diagnosis Strategy Based Diagnosis for an overview of the diagnostic approach.
* Diagnostic Procedure Instructions Diagnostic Procedure Instructions provides an overview of each diagnostic category.

DTC Descriptor
DTC P0C77
- Hybrid Battery System Precharge Time Too Short

DTC P0C78
- Hybrid Battery System Precharge Time Too Long

Circuit/System Description

The hybrid battery system voltage is controlled by two high voltage contactors. The high voltage contactors allow the high voltage DC batteries to be connected to the vehicle or safely contain the high voltage DC within the hybrid battery pack assembly. Of the two contactors, one is a pre-charge contactor and the other is the primary contactor. The two contactors are closed in a specific sequence by the starter/generator control module. The pre-charge contactor is closed first. This causes high voltage to flow through the pre-charge resistor, allowing system voltage to build slowly. Once the system voltage has raised and stabilized, the primary contactor is closed. Both contactors are controlled by the starter/generator control module. The starter/generator control module supplies B+ to each contactor at all times. When the contactors are to be closed, the starter/generator control module will provide a ground to the contactor through a low side driver.

Conditions for Running the DTC

P0C77
* No faults are set against the battery current sensor
* No faults are set against the internal bus voltage sensor
* Bus voltage is less than 50% before the start of precharge

P0C78
* No faults are set against the battery current sensor
* No faults are set against the internal battery voltage sensor
* No faults are set against the internal bus voltage sensor

Conditions for Setting the DTC

P0C77

Bus voltage is greater than 95% in less than 75 ms after the start of precharge

P0C78

Bus voltage has not reached 95% in less than 1 second after the start of precharge

OR

Battery current is greater than 5 A for longer than 100 ms after the start of precharge

Action Taken When the DTC Sets

DTCs P0C77 and P0C78 are type B DTCs

Conditions for Clearing the DTC

DTCs P0C77 and P0C78 are type B DTCs

Diagnostic Aids

Some conditions than may cause a too long pre-charge are:

* Pre-charge contactor that is inoperative and does not close
* Excessive resistance in the closed contacts of the pre-charge contactor
* Excessive resistance in the pre-charge resistor
* An open or excessive resistance in any of the high voltage (orange) circuits or terminal supplying voltage to the pre-charge resistor and contactor

Some conditions than may cause a too short pre-charge are:

* Primary contactor or pre-charge contractor stuck in the closed position
* Primary contactor control circuit shorted to ground, causing the primary contactor to remain closed even when not commanded closed by the starter/generator control module
* Too little resistance in the pre-charge resistor

Reference Information
Schematic Reference

Hybrid Energy Storage Schematics [1][2]Electrical Diagrams
Connector End View Reference

Component Connector End Views Connector End Views By Name
Description and Operation

Drive Motor Battery System Description Drive Motor Battery System Description
Electrical Information Reference

* Circuit Testing Circuit Testing
* Connector Repairs Connector Repairs
* Testing for Intermittent Conditions and Poor Connections Testing for Intermittent Conditions and Poor Connections
* Wiring Repairs Wiring Repairs

DTC Type Reference

Powertrain Diagnostic Trouble Code (DTC) Type Definitions Powertrain Diagnostic Trouble Code (DTC) Type Definitions
Scan Tool Reference

Control Module References Control Module References for scan tool information
Special Tools

EL-48900 - HEV Safety Kit

For equivalent regional tools, refer to Special Tools Tools and Equipment.

Circuit/System Testing

Danger: Always perform the High Voltage Disabling procedure prior to servicing any High Voltage component or connection. Personal Protection Equipment (PPE) and proper procedures must be followed.


The High Voltage Disabling procedure will perform the following tasks:


* Identify how to disable high voltage.

* Identify how to test for the presence of high voltage.

* Identify condition under which high voltage is always present and personal protection equipment (PPE) and proper procedures must be followed.


Before working on any high voltage system, be sure to wear the following Personal Protection Equipment:


* Safety glasses with appropriate side shields when within 15 meters (50 feet) of the vehicle, either indoors or outdoors.

* Certified and up-to-date Class "0" Insulation gloves rated at 1000V with leather protectors.


- Visually and functionally inspect the gloves before use.

- Wear the Insulation gloves with leather protectors at all times when working with the high voltage battery assembly, whether the system is energized or not.


Failure to follow the procedures exactly as written may result in serious injury or death.


Danger: The eAssist battery pack assembly will utilize an exchange program. Please consult the most recent revision of bulletin/PI #PIPXXYYZZ, available in Service Information (SI), for a list of approved eAssist battery pack assembly service procedures. Components that may be removed and serviced without exchanging the complete battery pack assembly are identified in the bulletin/PI. Please contact the GM Technical Assistance Center (1-877-446-8227) if you have any questions.


1. Ignition OFF, disable high voltage at the A4 hybrid battery pack. Refer to High Voltage Disabling High Voltage Disabling.
2. Disconnect the X1 and X2 harness connectors at the KR134 pre-charge contactor.
3. Connect the 12 V battery.
4. Ignition ON, verify a test lamp illuminates between the B+ circuit terminal A X1.

• If the test lamp does not illuminate, test the B+ circuit for a short to ground or an open/high resistance. If the circuit tests normal, replace the K59 starter/generator control module.

5. Test for less than 1 V between the control circuit terminal A X2 and ground.

• If greater than the specified range, test the control circuit for a short to voltage.

Note: This step checks the resistance of the closed contactor. Excessive resistance in the closed contacts may cause a slow pre-charge. To verify the resistance, the contactor must be closed. To close the contactor, all terminals at the contactor must be removed and the contactor B+ and control circuits jumpered to B+ and ground. This will close the contacts and allow the resistance of the contacts to be measured.

6. Install a 10 A fused jumper wire between the B+ terminal A X1 and 12 V. Install a jumper wire between the control terminal A X2 and ground. Test for less than 2 ohm between the high voltage terminal 1+ and 2-.

• If less than the specified range, replace the KR134 pre-charge contactor.

7. Ignition OFF, connect the X1 and X2 harness connectors at the KR134 pre-charge contactor. Disconnect the X4 harness connector at the K59 starter/generator control module.
8. Test for infinite resistance between the control circuit terminal 6 and ground.

• If less than the specified value, test the control circuit for a short to ground.

9. Test for 90-125 ohm between the B+ circuit terminal 4 and the control circuit terminal 6.

• If not within the specified range, test the control circuit for an open/high resistance. If the circuit tests normal, test or replace the KR118 hybrid battery precharge contactor.

10. Test for infinite resistance between the control circuit terminal 5 and ground.

• If less than the specified value, test the control circuit for a short to ground.

11. Test for infinite resistance between the KR38 main contactor high voltage terminal 1+ and 2-.

• If less than the specified value, replace the KR38 main contactor.

12. Test for 5-10 ohm between the R25 hybrid/EV battery pre-charge resistor terminals.

• If not within the specified range, replace the R25 hybrid/EV battery pre-charge resistor.

13. Test each of the high voltage circuits and terminals supplying the R25 hybrid/EV battery pre-charge resistor and KR134 pre-charge contactor for an open or high resistance.

• If an open/high resistance is found, replace the appropriate harness or component.

14. If all circuits test normal, replace the K59 starter/generator control module.

Repair Instructions

Perform the Diagnostic Repair Verification Verification Tests after completing the diagnostic procedure.

Control Module References Control Module References for starter/generator control module replacement, programming, and setup