Illustration 1 | g00596877 |
Schematic For An Unexpected Shutdown |
Note: CID 566 FMI 7 replaces the former CID 330 FMI 7 for a fault with an unexpected shutdown.
The CID 566 alerts the operator that the GSC did not control the engine shutdown. The GSC normally controls all engine shutdowns. If an outside influence causes the engine to shut down, the GSC indicates a CID 566. There is only one failure mode for a CID 566 and the mode is FMI 7 (faulty mechanical response).
The diagnostic code causes the following sequence of events:
- On a running engine, the GSC detects that the engine speed has dropped from the rated speed to 0 rpm when the GSC has not called for a shutdown.
- The GSC determines that no fault for the engine speed sensor is present that explains the drop in the speed signal.
- The GSC indicates a CID 566 FMI 7 and the GSC disables the engine from running.
Note: An unexpected shutdown fault will initiate a signal from the shunt trip circuit breaker.
Note: Diagnostic codes are created when the harness connector (40 contact) is disconnected from the GSC during these troubleshooting procedures. Clear these created diagnostic codes after the particular fault is corrected. In a properly operating system, when the harness connector is removed from the GSC, the following diagnostic codes are recorded.
- CID 100 FMI 3 pressure sensor (engine oil)
- CID 110 FMI 3 temperature sensor (engine coolant)
- CID 111 FMI 3 fluid level sensor (engine coolant)
- CID 190 FMI 3 speed sensor (engine)
- CID 331 FMI 2 switch (engine control)
- CID 336 FMI 2 switch (engine control)
Procedure
The following condition is a possible cause of a CID 566 FMI 7:
- A component that is not under the control of the GSC has caused an engine shutdown.
The GSC treats this diagnostic code as a shutdown fault. Clear the diagnostic code from the fault log after troubleshooting is complete.
Note: This procedure requires many voltage measurements during simulated engine cranking. The fuse for the starting motor "F4" on the relay module is removed in order to prevent the activation of the starting motor. Voltage measurements must be made quickly before the total cycle crank time (setpoint P17) elapses. The total cycle crank time has been defaulted to ninety seconds. See Systems Operation, "Engine/Generator Programming OP5". If a voltage measurement takes too long (more than 90 seconds), the GSC indicates an overcrank fault. The indicator for the overcrank shutdown will FLASH. In order to continue with a voltage measurement, the overcrank fault must be reset by turning the ECS to OFF/RESET. Then turn the ECS to START.
- Perform an initial check.
Before proceeding with the troubleshooting procedures, do the following steps:
- Make sure that there are NO OTHER ACTIVE FAULTS. Erroneous troubleshooting and needless replacement of parts can be caused by a failure to check for other diagnostic codes. The operator will make many voltage measurements while the GSC is attempting to crank the engine. The GSC detects other diagnostic codes. If the GSC detects other diagnostic codes, the GSC will prevent the starting of the engine by sending a signal to the PEEC electronic control module. This signal will turn off the fuel shutoff solenoid and this signal will shut down the engine.
- Check the fuel level and the fuel quality.
- Check for a plugged fuel filter.
- Check for a plugged air filter.
- Refer to the Engine Service Manual if there is an obvious engine fault. Also, refer to the Engine Service Manual if there is an obvious fault with the fuel system.
- Check the engine speed sensor for the PEEC electronic control module.
- Check the air shutoff solenoid for activation. If the air shutoff solenoid is activated and the air shutoff solenoid cannot be deactivated, begin troubleshooting with 17. Otherwise begin troubleshooting with 2.
- Verify the diagnostic code.
- Observe the upper display. Check that the CID 566 FMI 7 is showing.
Expected Result: A CID 566 FMI 7 is showing as an active fault.
Results:
- No - A CID 566 FMI 7 is NOT showing. No active CID 566 FMI 7 exists. STOP.
- Yes - Only a CID 566 FMI 7 is showing. Proceed to 3. (If an inactive CID 566 FMI 7 is showing in the fault log, check the history of the genset and proceed to 3.)
- No - A CID 566 FMI 7 is NOT showing. No active CID 566 FMI 7 exists. STOP.
- Observe the upper display. Check that the CID 566 FMI 7 is showing.
- Check the system voltage.
- Ensure that the engine is off. Measure the system voltage at the battery. Make a note of this measurement. The measurement for the system voltage is used for comparison in future steps of this procedure.
Expected Result: For 24 volt systems, the system voltage should be from 24.8 to 29.5 DCV. For 32 volt systems, the system voltage should be from 33.1 to 39.3 DCV.
Results:
- OK - Proceed to 4.
- NOT OK - System voltage is NOT correct. For troubleshooting, see the procedure for system voltage. STOP.
- OK - Proceed to 4.
- Ensure that the engine is off. Measure the system voltage at the battery. Make a note of this measurement. The measurement for the system voltage is used for comparison in future steps of this procedure.
- Check the setpoint P01. PEEC engines have ETR systems.
- Check the setpoint P01 for proper programming ("0" for ETR). See Systems Operation, "Setpoint Viewing OP2".
Expected Result: Setpoint P01 should be programmed to "0" for ETR.
Results:
- OK - Proceed to 5.
- Not OK - Setpoint P01 is NOT programmed correctly. Reprogram setpoint P01. See Systems Operation, "Engine/Generator Programming OP5".
- OK - Proceed to 5.
- Check the setpoint P01 for proper programming ("0" for ETR). See Systems Operation, "Setpoint Viewing OP2".
- Check the fuses.
- Turn the ECS to OFF/RESET.
- Check fuse "F10" on the relay module.
Expected Result: Fuse "F10" should not be blown.
Results:
- OK - Proceed to 7.
- NOT OK - One or more of the fuses are blown. Proceed to 6.
- OK - Proceed to 7.
- Troubleshoot the blown fuse.
For reference, see the preceding System Schematics and Testing And Adjusting, "Schematics and Wiring Diagrams".
- The ECS remains in the OFF/RESET position.
- Remove the fuse that is blown.
- Measure the resistance from RM-39 of the relay module to ground (B-).
Expected Result: The resistance of the circuit should be less than 3 ohms for the circuit with the fuse that is blown.
Results:
- OK - Resistance is greater than 3 ohms and fuse is no longer blowing. Carefully check ALL wires that are connected to the appropriate terminal of the relay module for abrasion or worn spots in the insulation that could be causing the short. Check the wires in the panel and the generator panel. Also check the wires on the engine harness. Refer to the various wiring diagrams. Repair the wiring or replace wiring, if necessary. STOP.
- NOT OK - If a resistance is less than 3 ohms, there is a short to ground (B-). Remove one component or wire at a time that is in series with the load side of the fuse terminal. Remove a component or wire until the faulty component or wire is isolated. Repair the faulty component or wiring. If necessary, replace the faulty component or wiring. STOP.
- NOT OK - If a resistance is greater than 3 ohms and the fuse still blows when all wires are removed from the appropriate terminal, replace the relay module. See Testing And Adjusting, "Relay Module - Replace". STOP.
- Measure the resistance from RM-39 of the relay module to ground (B-).
- Check the condition of the low voltage.
This test continues troubleshooting from 5. Fuse "F4" remains removed from the relay module. For reference, see the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". Prepare to make voltage measurements at the relay module.
- Prepare to measure voltage at the generator housing.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- At the generator housing, measure the voltage from TS2-40 to the TS1-2 terminal.
Expected Result: The voltage should increase to greater than 4.0 DCV. Then the voltage should stabilize to between 1.5 and 2.0 DCV.
Results:
- OK - Voltage is correct. The fault is with the fuel shutoff solenoid, the PEEC electronic control module, the fuel rack, or an open wire between TS2-40 and the fuel solenoid. See the Service Manual, "Engine Electronic Troubleshooting". STOP.
- NOT OK - Voltage is low. Check the wiring. Proceed to 8.
- OK - Voltage is correct. The fault is with the fuel shutoff solenoid, the PEEC electronic control module, the fuel rack, or an open wire between TS2-40 and the fuel solenoid. See the Service Manual, "Engine Electronic Troubleshooting". STOP.
- Check that the diagnostic code exists.
- Make sure that no other diagnostic codes are active.
- Check the upper display for any active diagnostic codes.
Expected Result: Only CID 566 FMI 7 is active.
Results:
- OK - Only CID 566 FMI 7 is active. Proceed to 9.
- NOT OK - A diagnostic code other than CID 566 FMI 7 is active. Correct the other diagnostic code. Proceed to the corresponding troubleshooting procedure. STOP.
- OK - Only CID 566 FMI 7 is active. Proceed to 9.
- Check the system voltage.
- Prepare to measure voltage at the generator housing.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- At the generator housing, measure the voltage from TS2-40 to the TS1-2 terminal.
Expected Result: The voltage should increase to greater than 4.0 DCV. Then the voltage should stabilize to between 1.5 and 2.0 DCV.
Results:
- OK - The voltage is correct. There is an open circuit between TS2-39 and TS2-40. Carefully check the resistance of the contacts for the ESPB. Check all wires for abrasion or worn spots in the insulation. Check the wires in the control panel and the generator housing. Repair the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- NOT OK - The voltage remains low. Proceed to 10.
- OK - The voltage is correct. There is an open circuit between TS2-39 and TS2-40. Carefully check the resistance of the contacts for the ESPB. Check all wires for abrasion or worn spots in the insulation. Check the wires in the control panel and the generator housing. Repair the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- Measure the voltage of the PEEC shutoff solenoid.
- Prepare to measure the voltage from the contact "A" of the PEEC shutoff solenoid to the -battery.
- Turn the ECS to OFF/RESET and then turn the ECS to the START.
- Measure the voltage from contact "A" of the PEEC shutoff solenoid to -battery.
Expected Results: The voltage should increase to greater than 4.0 DCV. Then the voltage should stabilize to between 1.5 and 2.0 DCV.
- OK - The voltage is correct. There is an open circuit between PEEC shutoff solenoid and TS2-39. Carefully check the resistance of the contacts for the ESPB. Check all wires for abrasion or worn spots in the insulation. Check the wires in the control panel and the generator housing. Repair the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- NOT OK - The voltage remains low. Proceed to 11.
- OK - The voltage is correct. There is an open circuit between PEEC shutoff solenoid and TS2-39. Carefully check the resistance of the contacts for the ESPB. Check all wires for abrasion or worn spots in the insulation. Check the wires in the control panel and the generator housing. Repair the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- Check the supply voltage of the PEEC electronic control module.
Fuse "F4" remains removed from the relay module. Prepare to make a voltage measurement at the PEEC electronic control module.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- At the PEEC ECM, measure the voltage from contact 1 to the contact 21.
Expected Result: The voltage should be ± 2.0 DCV of the system voltage that was previously measured in 3.
Results:
- OK - Voltage is correct. There is a fault in the PEEC electronic control module. There could be an open between the PEEC electronic control module and TS2-39. See the Service Manual, "Engine Electronic Troubleshooting". STOP.
- NOT OK - Voltage is low. Proceed to 12.
- OK - Voltage is correct. There is a fault in the PEEC electronic control module. There could be an open between the PEEC electronic control module and TS2-39. See the Service Manual, "Engine Electronic Troubleshooting". STOP.
- Check the voltage at the terminal strip TS1.
Fuse "F4" remains removed from the relay module. Prepare to make voltage measurements at the terminal strip in the generator terminal box.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- Measure the voltage from terminal TS1-6 to terminal TS1-2.
Expected Result: the voltage should be ± 2.0 DCV of the system voltage that was previously measured in 3.
Results:
- OK - Voltage is correct. There is an open between TS1-6 and the PEEC electronic control module. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- NOT OK - Voltage is low. Proceed to 13.
- OK - Voltage is correct. There is an open between TS1-6 and the PEEC electronic control module. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- Check the voltage at the slave relay.
Fuse "F4" remains removed from the relay module. Prepare to make voltage measurements at the slave relay (SR).
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- Measure the voltage from terminal 30 of the slave relay to terminal B- of the relay module.
Expected Result: the voltage should be ± 2.0 DCV of the system voltage that was previously measured in 3.
Results:
- OK - Voltage is correct. Proceed to 14.
- NOT OK - Voltage is NOT correct. Check the wiring. STOP.
- OK - Voltage is correct. Proceed to 14.
- Check the voltage at the slave relay.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- Measure the voltage from terminal 87 of the slave relay to terminal B- of the relay module.
Expected Result: the voltage should be ± 2.0 DCV of the system voltage that was previously measured in 3.
Results:
- OK - Voltage is correct. Proceed to 15.
- NOT OK - Voltage is NOT correct. Replace the slave relay. STOP.
- OK - Voltage is correct. Proceed to 15.
- Check that the diagnostic code exists.
- Make sure that no other diagnostic codes are active.
- Check the upper display for any active diagnostic codes.
Expected Result: Only CID 566 FMI 7 is active.
Results:
- OK - Only CID 566 FMI 7 is active. Proceed to 16.
- NOT OK - A diagnostic code other than CID 566 FMI 7 is active. Correct the other diagnostic code. Proceed to the corresponding troubleshooting procedure. STOP.
- OK - Only CID 566 FMI 7 is active. Proceed to 16.
- Check the system voltage.
- Recheck the voltage on terminal TS1-6. See 12.
Expected Result: The voltage should be ± 2.0 DCV of the system voltage that was previously measured in 3.
Results:
- OK - The voltage is correct. There is an open circuit between TS1-6 of the terminal strip and the PEEC electronic control module. Check the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- NOT OK - The voltage remains low. Check the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- OK - The voltage is correct. There is an open circuit between TS1-6 of the terminal strip and the PEEC electronic control module. Check the wiring. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- Recheck the voltage on terminal TS1-6. See 12.
- Check the voltage at the air shutoff solenoid.
This test continues troubleshooting from the preliminary step (initial check). Prepare to make a voltage measurement at the air shutoff solenoid. (The air shutoff solenoid may be active for 15 seconds.)
- Remove fuse "F4" from the relay module.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- At the air shutoff solenoid, measure the voltage across the terminals of solenoid.
Expected Result: The voltage should be from 0 to 2.0 DCV.
Results:
- OK - Voltage is correct. If the air shutoff solenoid cannot be reset then the fault is in the air shutoff solenoid. Refer to the Engine Service Manual. STOP.
- NOT OK - Voltage is high. Proceed to 18.
- OK - Voltage is correct. If the air shutoff solenoid cannot be reset then the fault is in the air shutoff solenoid. Refer to the Engine Service Manual. STOP.
- Check the voltage at the relay module.
Fuse "F4" remains removed from the relay module. Prepare to make a voltage measurement at the relay module.
- Turn the ECS to OFF/RESET and then turn the ECS to START.
- At the relay module, measure the voltage from RM-19 to the B- terminal.
Expected Result: The voltage should be ± 2.0 DCV of the system voltage that was previously measured in 3.
Results:
- OK - The voltage is correct. A wire or a component that is located between RM-19 of the relay module and the air shutoff solenoid is shorted to the battery (B+). Repair the circuit. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- NOT OK - The voltage is high. Proceed to 19.
- OK - The voltage is correct. A wire or a component that is located between RM-19 of the relay module and the air shutoff solenoid is shorted to the battery (B+). Repair the circuit. See the "Generator Set Wiring Diagram" in the Testing And Adjusting, "Schematics & Wiring Diagrams". STOP.
- Check the ASR.
Fuse "F4" remains removed from the relay module.
- Remove fuse "F3" from the relay module.
- Turn the ECS to OFF/RESET.
- Make sure that "K6" is not shown on the lower GSC display. (If "K6" is showing, make sure that no other diagnostic codes are active.)
- At the relay module, measure the resistance from RM-5 to RM-19. A measurement of less than 100 ohms indicates that the air shutoff relay is shorted.
Expected Result: The resistance should be greater than 10000 ohms.
Results:
- OK - Resistance is greater than 10000 ohms. Check for a short from the battery (B+) to RM-19 of the relay module. Repair the shorted wiring. If the short is internal to the relay module, replace the relay module. See Testing And Adjusting, "Relay Module - Replace". STOP.
- NOT OK - Resistance is less than 100 ohms. The short is internal to the relay module. Replace the relay module. See Testing And Adjusting, "Relay Module - Replace". STOP.
- OK - Resistance is greater than 10000 ohms. Check for a short from the battery (B+) to RM-19 of the relay module. Repair the shorted wiring. If the short is internal to the relay module, replace the relay module. See Testing And Adjusting, "Relay Module - Replace". STOP.