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    詳細描述

    Troubleshooting

    1600 Series Industrial Engine

    Electrical Connector - Inspect

    Most electrical faults are caused by poor connections.

    The following procedure will assist in detecting faults

    with connectors and with wiring. If a fault is found,

    correct the condition and verify that the fault is

    resolved.

    Intermittent electrical faults are sometimes resolved

    by disconnecting and reconnecting connectors. It is

    very important to check for diagnostic codes

    immediately before disconnecting a connector. Also

    check for diagnostic codes after reconnecting the

    connector. If the status of a diagnostic code is

    changed due to disconnecting and reconnecting a

    connector, there are several possible reasons. The

    likely reasons are loose terminals, improperly

    crimped terminals, moisture, corrosion, and

    inadequate mating of a connection.

    Illustration 30

    g01131019

    Seal for a three-pin connector (typical example)

    Follow these guidelines:

    •   Always use a breakout harness for a voltmeter

    probe or a test light. Never break the insulation of a

    wire in order to access a circuit for measurements.

    •   If a wire is cut, always install a new terminal for the

    repair.

    The connection  of any  electrical equipment  and

    the  disconnection  of   any  electrical  equipment

    may cause an explosion hazard which may result

    in injury  or death. Do  not connect any  electrical

    equipment or disconnect any electrical equipment

    in an explosive atmosphere.

    This document has been printed from SPI2. NOT FOR RESALE.


     

    116

    KENR8774

    Diagnostic Functional Tests

    Table 49

    TroubleshootingTest Steps

    Values

    Results

    1. Check Connectors for Moisture and Corrosion

    Harness,

    connectors,

    and seals are

    OK.

    Result: A fault has been found with the harness or the

    connectors.

    A. Inspect all the harnesses. Ensure that the routing of the wiring

    harness allows the wires to enter the face of each connector at a

    perpendicular angle. Otherwise, the wire will deform the seal bore.

    This will create a path for the entrance of moisture. Verify that the

    seals for the wires are sealing correctly.

    Repair the connectors or the wiring, as required. Ensure that

    all of the seals are correctly installed. Ensure that the con-

    nectors have been reattached.

    If corrosion is evident on the pins, sockets or the connector,

    use only denatured alcohol to remove the corrosion. Use a

    cotton swab or a soft brush to remove the corrosion.

    If moisture was found in the connectors, run the engine for

    several minutes and check again for moisture. If moisture re-

    appears, the moisture is wicking into the connector. Even if

    the moisture entry path is repaired, it may be necessary to re-

    place the wires.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    Result: The harness, connectors, and seals are in good

    condition.

    B. Ensure that the sealing plugs are in place. If any of the plugs are

    missing, replace the plug. Ensure that the plugs are inserted cor-

    rectly into the connector.

    C. Disconnect the suspect connector and inspect the connector

    seal. Ensure that the seal is in good condition. If necessary, replace

    the connector.

    D. Thoroughly inspect the connectors for evidence of moisture

    entry.

    Note: It is normal to see some minor seal abrasion on connector

    seals. Minor seal abrasion will not allow the entry of moisture.

    If moisture or corrosion is evident in the connector, the source of

    the moisture entry must be found and the source of the moisture

    entry must be repaired. If the source of the moisture entry is not re-

    paired, the fault will recur. Simply drying the connector will not recti-

    fy the fault. Check the following items for the possible moisture

    entry path:

    Proceed to Test Step 2.

    · Missing seals

    · Incorrectly installed seals

    · Nicks in exposed insulation

    · Improperly mated connectors

    Moisture can also travel to a connector through the inside of a wire.

    If moisture is found in a connector, thoroughly check the connector

    harness for damage. Also check other connectors that share the

    harness for moisture.

    Note: The ECM is a sealed unit. If moisture is found in an ECM

    connector, the ECM is not the source of the moisture. Do not re-

    place the ECM.

    2. Check the Wires for Damage to the Insulation

    The wiring is   Result: There is damage to the harness.

    OK

    A. Carefully inspect each wire for signs of abrasion, nicks, and

    cuts.

    Inspect the wires for the following conditions:

    · Exposed insulation

    Repair the wires or replace the wires, as required.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    · Rubbing of a wire against the engine

    · Rubbing of a wire against a sharp edge

    Result: The wires are free of abrasion, nicks, and cuts and

    the harness is correctly clamped.

    B. Check all of the fasteners for the harness and the strain relief

    components on the ECM in order to verify that the harness is cor-

    rectly secured. Also check all of the fasteners in order to verify that

    the harness is not compressed. Pull back the harness sleeves in

    order to check for a flattened portion of wire. A fastener that has

    been overtightened flattens the harness. This damages the wires

    that are inside the harness.

    Proceed to Test Step 3.

    3. Inspect the Connector Terminals

    Terminals are  Result: The terminals of the connector are damaged.

    aligned and

    undamaged

    Repair the terminals and/or replace the terminals, as

    required.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    117

    Diagnostic Functional Tests

    (Table 49, contd)

    TroubleshootingTest Steps

    Values

    Results

    A. Visually inspect each terminal in the connector. Verify that the

    terminals are not damaged. Verify that the terminals are correctly

    aligned in the connector and verify that the terminals are correctly

    located in the connector.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    Result: The terminals are OK.

    Proceed to Test Step 4.

    Illustration 31

    g01802454

    A typical example of the lock wedge.

    (1) Lock wedge

    Table 50

    TroubleshootingTest Steps

    Values

    Results

    4. Perform a Pull Test on Each Wire Terminal Connection

    Pull test OK    Result: A wire has been pulled from a terminal or a terminal

    has been pulled from the connector in the 45 N  (10 lb) pull

    test.

    A. Ensure that the locking wedge for the connector is installed cor-

    rectly. Terminals cannot be retained inside the connector if the lock-

    ing wedge is not installed correctly.

    Replace the terminal. Replace damaged connectors, as

    required.

    B. Perform the 45 N (10 lb) pull test on each wire. Each terminal

    and each connector should easily withstand 45 N  (10 lb) of tension

    and each wire should remain in the connector body. This test

    checks whether the wire was correctly crimped in the terminal and

    whether the terminal was correctly inserted into the connector.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    Result: All terminals pass the pull test.

    Proceed to Test Step 5.

    5. Check Individual Pin Retention into the Socket

    The sockets    Result: Terminals are damaged.

    provide good

    A. Verify that the sockets provide good retention for the pins. Insert  retention for  Replace the damaged terminals. Verify that the repair elimi-

    a new pin into each socket one at a time in order to check for a

    good grip on the pin by the socket.

    the new pin.    nates the problem.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    Result: The terminals are OK.

    Proceed to Test Step 6.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    118

    KENR8774

    Diagnostic Functional Tests

    (Table 50, contd)

    TroubleshootingTest Steps

    Values

    Results

    6. Check the Locking Mechanism of the Connectors

    The connec-   Result: The locking mechanism for the connector is dam-

    tors are

    A. Ensure that the connectors lock correctly. After locking the con- locked and

    aged or missing.

    nectors, ensure that the two halves cannot be pulled apart.

    are not

    damaged

    Repair the connector or replace the connector, as required.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    B. Verify that the latch tab of the connector is correctly latched. Also

    verify that the latch tab of the connector returns to the locked

    position.

    Result: The connectors are in good condition.

    Proceed to Test Step 7.

    8. Perform the “Continuous Monitor”  on the Electronic Serv-

    ice Tool

    Intermittent

    faults were

    indicated.

    Result: No intermittentfaults were found.

    If you were sent from another procedure, return to the proce-

    dure and continue testing. If this test confirms that the fault

    has been eliminated, return the engine to service.

    A. Run the “Continuous Monitor” test using the electronic service

    tool. Refer to Troubleshooting, “Electronic Service Tools”.

    B. Wiggle the wiring harness in order to reproduce intermittent

    faults.

    Result: At least one intermittent fault was indicated.

    Repair the harness or the connector.

    If an intermittent fault exists, the status will be highlighted.

    Use the electronic service tool in order to clear all logged di-

    agnostic codes and then verify that the repair eliminates the

    fault.

    i05527710

    Electrical Power Supply - Test

    (Electronic Control Module)

    This procedure tests that the correct voltage is being

    supplied to the Electronic Control Module (ECM).

    This procedure covers the following codes:

    Table 51

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    Electrical system voltage B+ out-of- DTC 112 is set when the Electronic Control Module (ECM) detects an alternator output

    range high                    greater than 32 Vat pin X3:3 for more than 0.5 seconds.

    112

    Electrical system voltage B+ out-of- DTC 113 is set when the ECM detects less than 10.3 Vat pin X3:3 for more than 0.5

    113

    626

    range low

    seconds.

    DTC 626 is set when power is interrupted to the ECM. Loose or dirty connections at

    fuses, relay connections, and battery or ground cables can cause the ECM to power

    down.

    Unexpected Reset Fault

    Follow the troubleshooting procedure in order to identify the root cause of the fault.

    The ECM is grounded to the battery negative terminal

    at ECM pins X3:6 and X3:7.

    The ECM receives ignition voltage at pin X3:3. The

    ignition voltage signals the ECM to provide a ground

    path from pin X3:5 to terminal 85 on the main power

    relay. Switching the relay provides power from the

    battery positive terminal through the fuses and relay

    terminals 30 and 87 to ECM pins X4:1 and X4:2.

    Fault Detection/Management

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    119

    Diagnostic Functional Tests

    The ECM internally monitors battery voltage. When

    the ECM continuously receives less than 10.3 V or

    more than 32 V, a DTC will be set.

    Illustration 32

    g03502100

    Schematic diagram for the electrical power supply circuit to the ECM.

    Illustration 33

    g03502143

    Illustration 34

    g03502144

    View of the pin locations on the X3 ECM connector

    for the ECM power supply

    View of the pin locations on the X4 ECM connector

    for the ECM power supply

    (3) Ignition keyswitch

    (5) Main relay

    (6) Ground

    (1) Battery +

    (2) Battery +

    (7) Ground

    This document has been printed from SPI2. NOT FOR RESALE.


     

    120

    KENR8774

    Diagnostic Functional Tests

    Table 52

    Required Tools

    Part Description

    Relay Breakout Harness

    Tool

    Part Number

    Qty

    A

    27610378

    1

    Batteries  give  off  flammable  fumes  which  can

    explode.

    To avoid  injury or  death, do  not strike  a match,

    cause  a  spark,  or  smoke   in  the  vicinity  of  a

    battery.

    Table 53

    TroubleshootingTest Steps

    Values

    Results

    1. Inspect Electrical Connectors and Wiring

    Damaged wire    Result: A damaged wire or damaged connector was found. A

    or connector

    fuse was blown.

    A. Thoroughly inspect the battery connections and the con-

    nections to the keyswitch, the main power relay, and the ECM.

    Refer to Troubleshooting, “Electrical Connectors - Inspect” for

    details.

    Repair the damaged wire or the damaged connector. Replace

    any blown fuses.

    Use the electronic service tool to clear all logged diagnostic co-

    des. Verify that the repair eliminates the fault.

    B. Check the harness for abrasion and for pinch points from

    the battery to the ECM, and from the keyswitch to the ECM.

    Result: All connectors, pins, and sockets are correctly con-

    nected and/or inserted and the harness is free of corrosion, of

    abrasion or of pinch points.

    C. Check the fuses.

    Proceed to Test Step 2.

    2. Check for Active Diagnostic Codes or Logged Diagnos-  Diagnostic

    Result: None of the diagnostic codes are active or recently

    tic Codes

    codes

    logged.

    A. Connect the electronic service tool to the diagnostic

    connector.

    If the fault is intermittent,refer to Troubleshooting, “Electrical

    Connectors - Inspect”.

    If the ECM is receiving no battery voltage, proceed to Test Step

    3.

    B. Turn the keyswitch to the ON position.

    C. Check if any of the diagnostic codes listed in Table 51  are

    active or recently logged.

    Result: At least one of the diagnostic codes is active or re-

    cently logged.

    Proceed to Test Step 3.

    3. Check the Batteries

    Battery load test Result: The batteries do not pass the load test. The measured

    passed

    voltage is less than 21 V.

    A. Load-test the batteries. Use a suitable battery load tester.

    Refer to Systems Operation, Testing and Adjusting, “Battery -

    Test” for the correct procedure.

    Recharge or replace the faulty batteries.

    Use the electronic service tool in order to clear all logged diag-

    nostic codes and then verify that the repair eliminates the fault.

    Result: The batteries pass the load test. The measured voltage

    is at least 21 V.

    Proceed to Test Step 4.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    121

    Diagnostic Functional Tests

    (Table 53, contd)

    TroubleshootingTest Steps

    Values

    Results

    4. Check for Battery Voltage at the ECM Main Power Relay  21 V to 27 V

    Result: The measured voltage is not within the expected

    Inputs

    range.

    A. Turn the keyswitch to the OFF position.

    If a fuse is blown, there is a short in the wiring. If a fuse is not

    blown, there is an open circuit in the wiring.

    B. Connect Tooling A to the main relay and the power distribu-

    tion connector.

    Repair the harness or replace the harness.

    Result: The measured voltage is within the expected range.

    C. Turn the keyswitch to the ON position.

    Proceed to Test Step 5.

    D. Use a multimeter to measure the voltage between the fol-

    lowing points:

    · Relay terminal 86 and ground

    · Relay terminal 30 and ground

    E. Turn the keyswitch to the OFF position.

    5. Check the Main Relay Signal Voltage at the Relay

    0.06 V to 2 V

    Result: The measured voltage is within the expected range.

    A. Turn the keyswitch to the ON position.

    Proceed to Test Step 6.

    B. Use a multimeter to measure the voltage between relay ter-

    minal 85 and ground.

    Result: The measured voltage is not within the expected

    range.

    Proceed to Test Step 7.

    6. Check the Output Voltage From the Relay

    21 V to 27 V

    Result: The measured voltage is not within the expected

    range.

    A. Use a multimeter to measure the voltage between relay ter-

    minal 87 and ground.

    Replace the ECM main power relay.

    Result: The measured voltage is within the expected range.

    Proceed to Test Step 7.

    7. Check the Resistance of the Wiring Between the Main

    Relay and the ECM

    Less than 5

    Ohms

    Result: At least one of the resistance measurements is greater

    than 5 Ohms.

    A. Turn the keyswitch to the OFF position.

    B. Disconnect the X3 and X4 ECM connectors.

    There is an open circuit or high resistance in the wiring between

    the main relay and the ECM.

    Repair the harness or replace the harness.

    C. Use a multimeter to measure the resistance between the

    following points:

    Result: All resistance measurements are less than 5 Ohms.

    · Relay terminal 85 and ECM X3:5

    · Relay terminal 87 and ECM X4:1

    · Relay terminal 87 and ECM X4:2

    Proceed to Test Step 8.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    122

    KENR8774

    Diagnostic Functional Tests

    (Table 53, contd)

    TroubleshootingTest Steps

    Values

    Results

    8. Check the Resistance Between the ECM Connectors

    and Ground.

    Less than 5

    Ohms for Step    the expected range.

    C.

    Result: At least one of the resistance measurements not within

    A. Turn the keyswitch to the OFF position.

    B. Disconnect the negative battery cable.

    There is a fault in the wiring.

    Greater than

    500 Ohms for

    Repair the harness or replace the harness.

    Note: Use the disconnected cable for the ground test point in Step D.

    the following steps.

    Result: All resistance measurements are within the expected

    Greater than 1k

    Ohm for step E.

    range.

    C. Use a multimeter to measure the resistance between the

    following points:

    Proceed to Test Step 10.

    · ECM X3:6 and ground

    · ECM X3:7 and ground

    D. Use a multimeter to measure the resistance between ECM

    X3:3 and ground

    E. Use a multimeter to measure the resistance between the

    following points:

    · ECM X3:5 and ground

    · ECM X4:1 and ground

    · ECM X4:2 and ground

    10. Check the Resistance of the Ignition Keyswitch Signal  Less than 5

    Result: The measured resistance is greater than 5 Ohms.

    Wire

    Ohms

    There is an open circuit or high resistance in the ignition key-

    switch signal wire.

    A. Disconnect the connector for the ignition keyswitch.

    Repair the harness or replace the harness.

    B. Use a multimeter to measure the resistance between the

    connector for the ignition keyswitch and ECM X3:3 on the har-

    ness connector.

    Result: The measured resistance is less than 5 Ohms.

    Replace the ignition keyswitch.

    If the fault persists, contact Perkins Global Technical Support

    i05535204

    Electrical Power Supply - Test

    (Injector Driver Module)

    This procedure tests that the correct voltage is being

    supplied to the Injector Driver Module (IDM).

    This procedure covers the following codes:

    Table 54

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    DTC 523 is set by the ECM when the ignition keyswitch signal voltage to the IDM is less

    than 10.3 V.

    523

    IDM voltage low

    DTC 525 is set by the ECM when there is an internal IDM failure.

    When this DTC is set, replace the IDM.

    525

    533

    IDM Fault

    IDM relay voltage high

    DTC 533 is set by the ECM when the voltage from the IDM power relay exceeds 32 V.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    123

    Diagnostic Functional Tests

    (Table 54, contd)

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    DTC 534 is set by the ECM when the voltage from the IDM main power relay is less than

    10.3 V.

    534

    IDM relay voltage low

    Follow the troubleshooting procedure in order to identify the root cause of the fault.

    The IDM is grounded to the battery negative terminal

    at IDM pins X3:1, X3:2, X3:3, X3:22 and X3:26.

    The IDM receives ignition voltage at pin X3:7. The

    ignition voltage signals the IDM to provide a ground

    path from pin X3:27 to terminal 85 on the IDM main

    power relay. Switching the relay provides power from

    the battery positive terminal through a fuse and relay

    terminals 30 and 87 to ECM pins X3:4, X3:23, X3:24,

    and X3:25. Switching the relay also supplies power

    through a fuse to pin X3:8 logic power.

    Fault Detection/Management

    The IDM internally monitors battery voltage. When

    the IDM continuously receives less than 10.3 V or

    more than 32 V, a DTC will be set.

    Illustration 35

    g03506173

    Schematic diagram for the IDM electrical power supply

    This document has been printed from SPI2. NOT FOR RESALE.


     

    124

    KENR8774

    Diagnostic Functional Tests

    Illustration 36

    g03506844

    View of the pin locations for the IDM power supply on

    the IDM X3 connector

    (1) Ground

    (2) Ground

    (3) Ground

    (4) Power

    (7) Ignition keyswitch

    (8) IDM logic power

    (22) Ground

    (23) Power

    (24) Power

    (25) Power

    (26) Ground

    (27) IDM power relay

    Table 55

    Required Tools

    Tool

    Part Number

    Part Description

    Qty

    A

    27610378

    Relay Breakout Harness

    1

    Batteries  give  off  flammable  fumes  which  can

    explode.

    To avoid  injury or  death, do  not strike  a match,

    cause  a  spark,  or  smoke   in  the  vicinity  of  a

    battery.

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    125

    Diagnostic Functional Tests

    Table 56

    TroubleshootingTest Steps

    Values

    Results

    1. Inspect Electrical Connectors and Wiring

    Damaged wire    Result: A damaged wire or damaged connector was found. A

    or connector

    fuse was blown.

    A. Thoroughly inspect the battery connections and the con-

    nections to the keyswitch, the IDM relay and the IDM. Refer to

    Troubleshooting, “Electrical Connectors - Inspect” for details.

    Repair the damaged wire or the damaged connector. Replace

    any blown fuses.

    Use the electronic service tool to clear all logged diagnostic co-

    des. Verify that the repair eliminates the fault.

    B. Check the harness for abrasion and for pinch points from

    the battery to the IDM, and from the keyswitch to the IDM.

    Result: All connectors, pins, and sockets are correctly con-

    nected and/or inserted and the harness is free of corrosion, of

    abrasion or of pinch points.

    C. Check the fuses.

    Proceed to Test Step 2.

    2. Check for Active Diagnostic Codes or Logged Diagnos-  Diagnostic

    Result: None of the diagnostic codes are active or recently

    tic Codes

    codes

    logged.

    A. Connect the electronic service tool to the diagnostic

    connector.

    If the fault is intermittent,refer to Troubleshooting, “Electrical

    Connectors - Inspect”.

    If the ECM is receiving no battery voltage, proceed to Test Step

    3.

    B. Turn the keyswitch to the ON position.

    C. Check if any of the diagnostic codes listed in Table 54  are

    active or recently logged.

    Result: At least one of the diagnostic codes is active or re-

    cently logged.

    Proceed to Test Step 3.

    3. Check the Batteries

    Battery load test Result: The batteries do not pass the load test. The measured

    passed

    voltage is less than 21 V.

    A. Load-test the batteries. Use a suitable battery load tester.

    Refer to Systems Operation, Testing and Adjusting, “Battery -

    Test” for the correct procedure.

    Recharge or replace the faulty batteries.

    Use the electronic service tool in order to clear all logged diag-

    nostic codes and then verify that the repair eliminates the fault.

    Result: The batteries pass the load test. The measured voltage

    is at least 21 V.

    Proceed to Test Step 4.

    4. Check for Battery Voltage at the IDM Main Power Relay 21 V to 27 V

    Result: The measured voltage is not within the expected

    Inputs

    range.

    A. Turn the keyswitch to the OFF position.

    If a fuse is blown, there is a short in the wiring. If a fuse is not

    blown, there is an open circuit in the wiring.

    B. Connect Tooling A to the IDM relay and the power distribu-

    tion connector.

    Repair the harness or replace the harness.

    Result: The measured voltage is within the expected range.

    C. Turn the keyswitch to the ON position.

    Proceed to Test Step 5.

    D. Use a multimeter to measure the voltage between the fol-

    lowing points:

    · Relay terminal 86 and ground

    · Relay terminal 30 and ground

    E. Turn the keyswitch to the OFF position.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    126

    KENR8774

    Diagnostic Functional Tests

    (Table 56, contd)

    TroubleshootingTest Steps

    Values

    Results

    5. Check the IDM Relay Signal Voltage at the Relay

    0.06 V to 2 V

    Result: The measured voltage is within the expected range.

    A. Turn the keyswitch to the ON position.

    Proceed to Test Step 6.

    B. Use a multimeter to measure the voltage between relay ter-

    minal 85 and ground.

    Result: The measured voltage is not within the expected

    range.

    Proceed to Test Step 7.

    6. Check the Output Voltage From the Relay

    21 V to 27 V

    Result: The measured voltage is not within the expected

    range.

    A. Use a multimeter to measure the voltage between relay ter-

    minal 87 and ground.

    Replace the IDM power relay.

    Result: The measured voltage is within the expected range.

    Proceed to Test Step 7.

    7. Check the Resistance of the Wiring Between the IDM

    Relay and the IDM

    Less than 5

    Ohms

    Result: At least one of the resistance measurements is greater

    than 5 Ohms.

    A. Turn the keyswitch to the OFF position.

    B. Disconnect the X3 IDM connector.

    There is an open circuit or high resistance in the wiring between

    the main relay and the ECM. The fuse between relay terminal

    87 and ECM X3:8 may have blown.

    C. Use a multimeter to measure the resistance between the

    following points:

    If necessary, replace the fuse. Repair the harness or replace

    the harness.

    · Relay terminal 85 and IDM X3:27

    · Relay terminal 87 and IDM X3:4

    · Relay terminal 87 and IDM X3:23

    · Relay terminal 87 and IDM X3:24

    · Relay terminal 87 and IDM X3:25

    · Relay terminal 87 and IDM X3:8

    Result: All resistance measurements are less than 5 Ohms.

    Proceed to Test Step 8.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    127

    Diagnostic Functional Tests

    (Table 56, contd)

    TroubleshootingTest Steps

    Values

    Results

    8. Check the Resistance Between the ECM Connectors

    and Ground.

    Less than 5

    Ohms for Step    is greater than 5 Ohms.

    C.

    Result: At least one of the resistance measurements in Step C

    A. Turn the keyswitch to the OFF position.

    B. Disconnect the negative battery cable.

    There is an open circuit or high resistance in the wiring.

    Greater than

    900 Ohms for

    Repair the harness or replace the harness.

    Note: Use the disconnected cable for the ground test point in step D.

    the following steps.

    Result: At least one of the resistance measurements in Step D

    is less than 900 Ohms.

    C. Use a multimeter to measure the resistance between the

    following points:

    · IDM X3:1 and ground

    There is a short to ground in the wiring.

    Repair the harness or replace the harness.

    · IDM X3:2 and ground

    · IDM X3:3 and ground

    · IDM X3:22 and ground

    Result: All resistance measurements are within the expected

    · IDM X3:26 and ground

    range.

    D. Use a multimeter to measure the resistance between the

    following points:

    Proceed to Test Step 10.

    · IDM X3:4 and ground

    · IDM X3:23 and ground

    · IDM X3:24 and ground

    · IDM X3:25 and ground

    · IDM X3:8 and ground

    · IDM X3:27 and ground

    · IDM X3:7 and ground

    10. Check the Resistance of the Ignition Keyswitch Signal  Less than 5

    Result: The measured resistance is greater than 5 Ohms.

    Wire

    Ohms

    There is an open circuit or high resistance in the ignition key-

    switch signal wire.

    A. Disconnect the connector for the ignition keyswitch.

    Repair the harness or replace the harness.

    B. Use a multimeter to measure the resistance between the

    connector for the ignition keyswitch and IDM X3:7 on the har-

    ness connector.

    Result: The measured resistance is less than 5 Ohms.

    Replace the ignition keyswitch.

    If the fault persists, contact Perkins Global Technical Support

    i05538541

    Note: A compressed air source of 689 kPa  (100 psi)

    is required in order to perform this procedure.

    Injection Actuation Pressure -

    Note: If the Electronic Control Module (ECM) detects

    low boost pressure or an incorrect feedback signal

    from the Injection Control Pressure (ICP) sensor, the

    ECM commands the Injection Pressure Regulator

    (IPR) valve to reduce ICP.

    Test

      Table 57

    Required Tools

    Tool

    Part Number

    Part Description

    Qty

    A

    27610374

    Actuator Breakout Harness

    1

    1

    1

    Pressure Sensor Breakout

    Harness

    B

    C

    27610393

    27610384

    ICP Sensor Adaptor

    High-pressure Hose

    D

    E

    F

    3033222C

    1875784C

    27610398

    1

    1

    1

    ICP Sensor

    UVC Sensor Breakout Harness

    This document has been printed from SPI2. NOT FOR RESALE.


     

    128

    KENR8774

    Diagnostic Functional Tests

    Illustration 37

    g03509736

    Illustration 38

    g03509756

    (1) IPR valve

    (2) Engine Oil Temperature (EOT) sensor

    1. Disconnect the engine wiring harness connector

    from IPR valve (1). Inspect the engine harness

    terminals and the IPR valve for corrosion, bent

    pins, or pins pushed back. Make any necessary

    repairs.

    6. Disconnect the engine harness connector from

    Engine Oil Temperature (EOT) sensor (2).

    7. Slowly loosen the EOTsensor from the EOT port

    until oil flows out, indicating that the oil level is

    above the sensor.

    2. Connect Tooling A to the IPR. Do not connect to

    the engine harness.

    Note: Oil will spill out, if the sensor is removed. Catch

    the oil in a suitable container.

    Note: If the engine harness is connected to Tooling A,

    the ignition keyswitch fuse will blow or damage the

    wiring harness.

    If the oil level was above the EOTsensor, tighten

    the sensor and reconnect the harness. Continue

    with this procedure.

    3. Apply battery voltage and ground to the IPR valve.

    If the oil level is low, place a suitable container

    under the port to catch the oil. Crank the engine

    and check if oil flows out of the EOT port.

    Note: Do not leave the IPR valve energized for more

    than 120 seconds. This can damage the IPR valve.

    If oil does not flow out while cranking, the lube oil

    pump may not be supplying oil to the reservoir.

    Refer to Troubleshooting, “Oil Pressure Is Low”.

    If the engine starts, disconnect ground and battery

    voltage from the actuator breakout harness.

    4. Use the electronic service tool to monitor injection

    control pressure while cranking the engine for 20

    seconds. Record the results.

    5. If the injection control pressure increases above

    28 MPa (4061 psi), the mechanical system is

    operating correctly for the engine to start. Either

    the ECM is not controlling the IPR or the IPR circuit

    has failed. Troubleshoot any active diagnostic

    codes. Refer to Troubleshooting, “Diagnostic

    Trouble Codes”. Do not continue with this

    procedure until all diagnostic codes have been

    cleared.

    If 28 MPa (4061 psi) ICP cannot be reached,

    continue with this procedure.

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    129

    Diagnostic Functional Tests

    10. Install the test hose assembly to the high-

    pressure pump.

    Illustration 39

    g03509817

    Test hose

    (3) 13/16-16 NPT fitting

    (C) Tooling C - ICP Sensor Adaptor

    (D) Tooling D - High-pressure hose

    (E) Tooling E - ICP sensor

    Illustration 41

    g03509858

    Valve cover gasket

    (5) Pass-through connector for the ICP sensor

    8. Fabricate a test hose assembly using Tooling C,

    Tooling D, Tooling E, and a 13/16-16 NPT fitting

    11. Disconnect the engine wiring harness from valve

    cover gasket ICP connector (5).

    Note: Retain the high-pressure hose and the ICP

    sensor for future diagnostics.

    12. Connect Tooling F between the high-pressure

    hose assembly and the engine wiring harness.

    Note: Do not connect Tooling F to the valve cover

    gasket connector.

    13. Connect Tooling A to the IPR. Do not connect to

    the engine harness.

    Note: If the engine harness is connected to Tooling A,

    the ignition keyswitch fuse will blow or damage the

    wiring harness.

    14. Apply battery voltage and ground to the IPR

    valve.

    15. Use the electronic service tool to monitor the

    injection control pressure while cranking the

    engine for 20 seconds. Record the results.

    If the ICP increases above 28 MPa  (4061 psi), the

    high-pressure pump and IPR are operating

    correctly for the engine to start. Remove the test

    hose assembly from the high-pressure pump.

    Continue with this procedure.

    Illustration 40

    g03509843

    If 28 MPa (4061 psi) cannot be reached, proceed

    to Test Step 26.

    View of the high-pressure oil hose fitting on the high-

    pressure pump (some items are not shown for

    clarity).

    (4) High-pressure oil hose fitting

    9. Disconnect the high-pressure oil hose from high-

    pressure pump fitting (4).

    Note: Oil will spill from the hose. Position the high-

    pressure oil hose so that oil will not spill.

    This document has been printed from SPI2. NOT FOR RESALE.


     

    130

    KENR8774

    Diagnostic Functional Tests

    Perform any necessary repairs.

    25. Install the valve mechanism cover. Refer to

    Disassembly and Assembly, “Valve Mechanism

    Cover - Remove and Install”.

    26. Remove Tooling C and Tooling E from Tooling D.

    Illustration 42

    g03509859

    (6) Air line fitting

    (7) In-line shut-off valve

    (8) 13/16-16 NPT fitting

    (9) High-pressure oil hose

    16. Install a 13/16-16 NPT fitting, a shut-off valve, and

    an air line fitting to the high-pressure oil hose that

    is connected to the cylinder head.

    Illustration 43

    g03509859

    Note: If the system does not leak when air pressure

    is applied, the system will maintain pressure. When

    the hose is removed, oil will be released with air

    pressure. Use the in-line shut-off valve to control and

    contain bleed-off mixture (air and oil).

    27. Install a 13/16-16 NPT fitting, a shut-off valve, and

    an air line fitting to the high-pressure oil hose that

    is connected to the cylinder head.

    28. Remove the oil level gauge from the oil fill tube.

    17. Remove the oil level gauge from the oil fill tube.

    29. Close the in-line shut-off valve.

    18. Close the in-line shut-off valve.

    30. Connect the air supply to the air line fitting.

    19. Connect the air supply to the air line fitting.

    31. Apply 689 kPa (100 psi) of pressure. Slowly open

    the shut-off valve.

    20. Apply 689 kPa (100 psi) of pressure. Slowly open

    the shut-off valve.

    32. Listen for an air leak in the crankcase through the

    oil fill tube.

    21. Listen for an air leak in the crankcase through the

    oil fill tube.

    A leak should be heard through the IPR valve

    when the IPR valve is not energized.

    If a leak is not heard, go back and check previous

    test results.

    33. Connect Tooling A to the IPR. Do not connect to

    the engine harness.

    If a leak is heard, continue with this procedure.

    Note: If the engine harness is connected to Tooling A,

    the ignition keyswitch fuse will blow or damage the

    wiring harness.

    22. Close the in-line shut-off valve to stop the air flow.

    23. Remove the valve mechanism cover. Refer to

    Disassembly and Assembly, “Valve Mechanism

    Cover - Remove and Install”.

    34. Apply battery voltage and ground to the IPR

    valve. Listen for an air leak in the crankcase

    through the oil fill tube.

    24. Open the in-line shut-off valve and listen for leaks.

    Check the following components:

    If the IPR valve is energized, the air leak should

    stop.

    •   Injector oil inlet adaptor and o-rings

    •   ICP sensor

    Note: Do not leave the IPR valve energized for more

    than 120 seconds. This can damage the IPR valve.

    •   O-ring for the high-pressure oil rail

    •   End plugs in the high-pressure oil rail

    If the air leak does not stop, replace the IPR valve.

    Refer to Disassembly and Assembly, “Injection

    Actuation Pressure Control Valve - Remove and

    Install”.

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    131

    Diagnostic Functional Tests

    If the air leak stops, continue with this procedure.

    35. Remove the high-pressure oil pump. Refer to

    Disassembly and Assembly, “Unit Injector

    Hydraulic Pump - Remove and Install”.

    Check that the high-pressure oil pump gear is

    tightened to a torque of 224 N·m  (165.21344 lb ft).

    If the high-pressure oil pump gear is tight, or the

    pump cam does not rotate, replace the pump.

    Refer to Disassembly and Assembly, “Unit Injector

    Hydraulic Pump - Remove and Install”.

    If this procedure did not rectify the fault, contact

    Perkins  Global Technical Support.

    i05543549

    Injection Actuation Pressure

    Control Valve - Test

    This procedure covers the following codes:

    Table 58

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    Injection Control Pressure regulator DTC 241 is set b, y the Electronic Control Module (ECM) when the Output Circuit Check

    OCC self test failed

    (OCC) test has failed after the Key-On Engine-Off (KOEO) Standard Test has been run.

    241

    Follow the troubleshooting procedure in order to identify the root cause of the fault.

    The IPR valve is supplied with voltage at pin A of the

    IPR connector through a 12-pin connector (pin 9)

    from the ignition keyswitch. The control of the

    injection control system is gained by the ECM

    grounding pin B of the IPR valve through pin X1:12 of

    the ECM. Precise control is gained by varying the

    percentage of ON/OFF time of the IPR solenoid. A

    high duty cycle indicates a high amount of injection

    control pressure is being commanded. A low duty

    cycle indicates less pressure being commanded.

    Fault Detection/Management

    An open or short to ground in the Injection Control

    Pressure (ICP) circuit can be detected by an on-

    demand output circuit check during KOEO Standard

    Test. If there is a circuit fault detected, a Diagnostic

    Trouble Code (DTC) will be set. When the engine is

    running, the ECM can detect if the ICP is equal to the

    desired pressure. When the measured ICP does not

    compare to the desired pressure, the ECM will ignore

    the measured ICP signal and controls the engine with

    the desired value.

    This document has been printed from SPI2. NOT FOR RESALE.


     

    132

    KENR8774

    Diagnostic Functional Tests

    Illustration 44

    g03510058

    Illustration 45

    g03510138

    View of the pin locations for the IPR valve on the X1

    ECM connector

    (12) IPR ground

    (24) IPR power

    Table 59

    Required Tools

    Tool

    Part Number

    Part Description

    Qty

    A

    27610374

    Actuator Breakout Harness

    1

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    133

    Diagnostic Functional Tests

    Table 60

    TroubleshootingTest Steps

    Values

    Results

    1. Inspect Electrical Connectors and Wiring

    Damaged wire   Result: A damaged wire or damaged connector was found.

    or connector

    A. Thoroughly inspect the connections to the IPR, the ECM X1

    connector, the 12-pin connector, and the ignition keyswitch.

    Refer to Troubleshooting, “Electrical Connectors - Inspect” for

    details.

    Repair the damaged wire or the damaged connector.

    Use the electronic service tool to clear all logged diagnostic co-

    des. Verify that the repair eliminates the fault.

    Result: All connectors, pins, and sockets are correctly con-

    nected and/or inserted and the harness is free of corrosion, of

    abrasion or of pinch points.

    B. Check the harness for abrasion and for pinch points from

    the IPR to the ECM, and from the keyswitch to the IPR.

    Proceed to Test Step 2.

    2. Run the Key-On Engine-Off (KOEO) Standard Test

    Diagnostic

    codes

    Result: A 241 diagnostic code is not active.

    A. Connect the electronic service tool to the diagnostic

    connector.

    The IPR valve circuit appears to be operating correctly at this

    time.

    If a fault is still suspected, proceed to Test Step 3 in order to

    continue testing the IPR valve circuit.

    B. Turn the keyswitch to the ON position.

    C. Select “Tests”  from the menu bar. Select “Key-On Engine-

    Off”  from the drop-down menu.

    Result: A 241 diagnostic code is active.

    D. From the KOEO Diagnostics menu, select  “Standard”  ,

    then select “Run”  .

    Proceed to Test Step 3.

    Note: This test takes less than 5 seconds.

    E. Record all active diagnostic codes.

    3. Check the Voltage at IPR Valve Connector

    21 V to 27 V for Result: The voltage measurement between IPR valve pin A

    Step E.        and ground is not within the expected range.

    A. Turn the keyswitch to the OFF position.

    Less than 0.25  There is an open circuit in the wiring between the fuse for the

    V for step F.    ignition keyswitch and the IPR valve connector.

    Repair the harness or replace the harness.

    B. Disconnect the engine harness connector from the IPR

    valve.

    C. Connect Tooling A to the harness connector for the IPR

    valve.

    Result: The voltage measurement between IPR valve pin B

    and ground is greater than 0.25 V.

    D. Turn the keyswitch to the ON position.

    The IPR valve ground wire is shorted to another voltage

    source.

    E. Use a multimeter to measure the voltage between IPR

    valve pin A and ground.

    Repair the harness or replace the harness.

    F. Use a multimeter to measure the voltage between IPR valve

    pin B and ground.

    Result: The voltage measurements are within the expected

    range.

    Proceed to Test Step 4.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    134

    KENR8774

    Diagnostic Functional Tests

    (Table 60, contd)

    TroubleshootingTest Steps

    Values

    Results

    4. Check the Resistance Between the 12-Pin Connector

    and the IPR Valve Connector

    Less than 5

    Ohms

    Result: The measured resistance is greater than 5 Ohms.

    There is an open circuit in the wiring between the 12-pin con-

    nector and the IPR valve connector.

    A. Turn the keyswitch to the OFF position.

    B. Disconnect the 12-pin connector.

    Repair the harness or replace the harness.

    Result: The measured resistance is less than 5 Ohms.

    Proceed to Test Step 5.

    C. Remove the fuse from the ignition keyswitch circuit.

    D. Use a multimeter to measure the resistance between pin 9

    on the 12-pin connector and pin A on the harness connector

    for the IPR valve.

    5. Check the Resistance of the IPR Circuit Including the

    IPR Valve

    5 Ohms to 20   Result: The resistance measurement is within the expected

    Ohms

    range.

    A. Turn the keyswitch to the OFF position.

    The IPR valve circuit appears to be OK.

    If a fault persists, contact Perkins Global Technical Support.

    B. Disconnect the ECM X1 connector.

    Result: The resistance measurement is not within the expected

    C. Disconnect Tooling A from the engine harness.

    D. Connect the engine harness connector to the IPR valve.

    E. Remove the fuse from the ignition keyswitch circuit.

    range.

    Proceed to Test Step 6.

    F. Use a multimeterto measure the resistance between ECM

    X1:12 and the fuse connector.

    6. Check the Resistance of the IPR Valve Coil

    5 Ohms to 20   Result: The resistance measurement is not within the expected

    Ohms

    range.

    A. Disconnect the engine harness connector from the IPR

    valve.

    Replace the IPR valve. Refer to Disassembly and Assembly,

    “Injection Actuation Pressure Control Valve - Remove and

    Install”.

    B. Connect Tooling A to the IPR valve.

    C. Use a multimeter to measure the resistance between pin A

    and pin B on the IPR valve.

    Result: The resistance measurement is within the expected

    range.

    The fault is in the wiring or the connectors. Refer to Trouble-

    shooting, “Electrical Connector - Inspect” in order to identify the

    fault.

    i05546457

    Injection Actuation Pressure

    Sensor - Test

    This procedure covers the following codes:

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    135

    Diagnostic Functional Tests

    Table 61

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    DTC 124 is set by the Electronic Control Module (ECM) if signal voltage is less than

    0.039 V for more than 1 second.

    Injection Control Pressure signal

    out-of-rangelow

    124

    125

    332

    DTC 124 can be set due to an open circuit or short to ground on the signal circuit, a failed

    Injection Control Pressure (ICP) sensor. The DTC can also be set due to the sensor sup-

    ply circuit being open or shorted to ground.

    DTC 125 is set by the ECM if the signal voltage is greater than 4.9 V for more than 0.1

    second.

    Injection Control Pressure signal

    out-of-rangehigh

    DTC can be set due to the signal circuit shorted to the sensor supply voltage or battery

    voltage.

    DTC 332 is set by the ECM if the voltage signal from the ICP sensor is greater than ex-

    pected with the keyswitch in the ON position and the engine not running.

    Injection Control Pressure above

    spec. with engine not running

    If the ECM sets DTC 332, the ECM will ignore the ICP signal and operate the IPR with

    fixed values based on engine operating conditions.

    Follow the troubleshooting procedure in order to identify the root cause of the fault.

    Function

    The ECM continuously monitors the signal of the ICP

    sensor to determine if the signal is within an expected

    range. If the ECM detects a voltage greater or less

    than expected, the ECM will set a DTC, ignore the

    ICP sensor signal, and use a preset value based on

    engine operating conditions.

    The ICP sensor is a micro strain gauge sensor. The

    ICP sensor is under the valve cover, forward of the

    No. 6 fuel injector in the high-pressure oil rail. The

    engine harness connection on the valve cover gasket

    for the ICP sensor is left of the No. 1 and No. 2

    injector connector. The ECM supplies a 5 V reference

    signal which the ICP sensor uses to produce a linear

    analog voltage that indicates pressure.

    The ICP sensor provides a feedback signal voltage to

    the ECM indicating injection control pressure. The

    ECM monitors ICP as the engine is operating to

    modulate the IPR. This is a closed loop function

    which means the ECM continuously monitors and

    adjusts for ideal ICP determined by conditions such

    as load, speed, and temperature.

    The ECM monitors the ICP signal to determine if the

    performance of the hydraulic system is satisfactory.

    During engine operation, if the ECM recognizes that

    the ICP signal is greater or less than the value that

    the Injection Pressure Regulator is trying to achieve,

    the ECM will set a DTC.

    The ICP signal from the ECM is one of the signals the

    Injector Driver Module uses to command the correct

    injector timing.

    ICP Circuit Operation

    The ICP sensor is supplied a 5 V reference signal at

    Pin 2 through valve cover gasket pin 8 from ECM pin

    X1:14. The ICP sensor supplied a signal ground at

    pin 1 through valve cover gasket pin 7 from ECM pin

    X1:6. The ECM monitors the ICP signal from sensor

    pin 3 through valve cover gasket pin 6 to ECM pin

    X1:20.

    Fault Detection/Management

    This document has been printed from SPI2. NOT FOR RESALE.


     

    136

    KENR8774

    Diagnostic Functional Tests

    Illustration 46

    g03514918

    Schematic diagram of the ICP sensor circuit

    Illustration 47

    g03520740

    View of the pin locations for the ICP sensor on the X1

    ECM connector

    (6) Ground

    (14) Power

    (20) Signal

    Table 62

    Required Tools

    Tool

    A

    Part Number

    27610376

    27610375

    Part Description

    4mm Plug 3-way Harness

    500 Ohm Resistor Harness

    Qty

    1

    1

    B

    Under Valve Cover Sensor

    Breakout Harness

    C

    27610398

    1

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    137

    Diagnostic Functional Tests

    Table 63

    TroubleshootingTest Steps

    Values

    Results

    1. Inspect Electrical Connectors and Wiring

    Damaged wire   Result: A damaged wire or damaged connector was found.

    or connector

    A. Thoroughly inspect the connections to the ICP sensor, the

    ECM X1 connector, and the valve cover connector. Refer to

    Troubleshooting, “Electrical Connectors - Inspect” for details.

    Repair the damaged wire or the damaged connector.

    Use the electronic service tool to clear all logged diagnostic co-

    des. Verify that the repair eliminates the fault.

    B. Check the harness for abrasion and for pinch points from

    the ICP sensor to the ECM.

    Result: All connectors, pins, and sockets are correctly con-

    nected and/or inserted and the harness is free of corrosion, of

    abrasion or of pinch points.

    Proceed to Test Step 2.

    2. Run the Key-On Engine-Off(KOEO) Continuous Monitor

    Test

    Diagnostic

    codes

    Result: One of the Diagnostic codes listed in Table 61  is

    active.

    A. Connect the electronic service tool to the diagnostic

    connector.

    Proceed to Test Step 3.

    B. Turn the keyswitch to the ON position.

    Result: One of the Diagnostic codes listed in Table 61  became

    active only when wiggling the connectors.

    C. Select “Tests”  from the menu bar. Select “Key-On Engine-

    Off”  from the drop-down menu.

    Repair or replace any suspect connectors.

    D. From the KOEO Diagnostics menu, select  “Continuous

    Monitor” , then select “Run”  .

    E. Monitor the ICP signal voltage and verify any active DTCs

    for the ICP sensor circuit.

    F. Wiggle the connectors associated with the ICP sensor

    circuit.

    3. Check the Signal Voltage With the Sensor

    Disconnected

    Less than 0.039 Result: The voltage measurement is greater than 0.039 V.

    V

    There is a short to another voltage source on the sensor signal

    A. Turn the keyswitch to the OFF position.

    wire.

    Repair the harness or replace the harness.

    B. Remove the valve cover. Refer to Disassembly and Assem-

    bly, “Valve Mechanism Cover - Remove and Install”. Leave the

    valve cover harness connected to the engine harness.

    Result: The voltage measurement is less than 0.039 V

    Proceed to Test Step 4.

    C. Disconnect the ICP sensor from the valve cover harness

    connector.

    D. Turn the keyswitch to the ON position.

    E. Use the electronic service tool to monitor the ICP sensor

    signal voltage.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    138

    KENR8774

    Diagnostic Functional Tests

    (Table 63, contd)

    TroubleshootingTest Steps

    Values

    Results

    4. Check the Sensor Supply Voltage

    4.5 V to 5.5 V   Result: The measured voltage is greater than 5.5 V.

    There is a short to battery in the sensor power wiring.

    Repair the harness or replace the harness.

    A. Turn the keyswitch to the OFF position.

    B. Connect Tooling C to ICP connector on the valve cover

    harness.

    Result: The measured voltage is less than 4.5 V

    C. Turn the keyswitch to the ON position.

    There is an open circuit or short to ground in the sensor power

    wiring.

    D. Use a multimeter to measure the voltage between pin 2 on

    the breakout harness and ground.

    Result: The measured voltage is within the expected range.

    Proceed to Test Step 5.

    5. Monitor the Signal Voltage With the 500 Ohm Resistor

    Harness Installed

    4.9 V to 5.1 V   Result: The measured voltage is less than 4.9 V.

    Proceed to Test Step 6.

    A. Turn the keyswitch to the OFF position.

    B. Install Tooling B between pin 2 and pin 3 on Tooling C.

    C. Turn the keyswitch to the ON position.

    Result: The measured voltage is within the expected range.

    Proceed to Test Step 8.

    D. Use the electronic service tool to monitor the ICP sensor

    signal voltage.

    E. Turn the keyswitch to the OFF position.

    F. Remove Tooling B.

    6. Check for a Short to Ground in the Sensor Signal Wire  Greater than 1 k Result: The measured resistance is less than 1 k Ohm.

    Ohm

    A. Turn the keyswitch to the OFF position.

    B. Disconnect the negative battery cable.

    There is a short to ground in the sensor signal wiring.

    Repair the harness or replace the harness.

    Result: The measured resistance is greater than 1 k Ohm.

    C. Use a multimeter to measure the resistance between pin 3

    on Tooling C and the disconnected negative battery cable.

    Proceed to Test Step 7.

    7. Check the Sensor Signal Wire for an Open Circuit

    A. Turn the keyswitch to the OFF position.

    Less than 5

    Ohms

    Result: The measured resistance is greater than 5 Ohms.

    There is an open circuit or high resistance in the sensor signal

    wire.

    B. Disconnect the engine harness connector from ECM X1.

    Repair the harness or replace the harness.

    C. Use a multimeter to measure the resistance between pin 3

    on Tooling C and terminal X1:20 on the engine harness

    connector.

    Result: The measured resistance is less than 5 Ohms.

    Proceed to Test Step 8.

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    KENR8774

    139

    Diagnostic Functional Tests

    (Table 63, contd)

    TroubleshootingTest Steps

    Values

    Results

    8. Check the Resistance of the Sensor Ground Wire

    A. Turn the keyswitch to the OFF position.

    Less than 5

    Ohms

    Result: The measured resistance is greater than 5 Ohms.

    There is an open circuit or high resistance in the sensor ground

    wiring.

    B. Disconnect the engine harness connector from ECM X1.

    Repair the harness or replace the harness.

    C. Use a multimeter to measure the resistance between pin 1

    on Tooling C and terminal X1:6 on the engine harness

    connector.

    Result: The measured resistance is less than 5 Ohms.

    Remove all tooling, reconnect all disconnected connectors, and

    install all removed components. Use the electronic service tool

    to clear all active diagnostic codes.

    Proceed to Test Step 9.

    9. Check for Active Diagnostic Codes

    Diagnostic

    codes

    Result: One of the diagnostic codes listed in Table 61  is still

    active.

    A. Turn the keyswitch to the ON position.

    Replace the ICP sensor. Refer to Disassembly and Assembly,

    “Injection Actuation Pressure Control Sensor - Remove and

    Install”.

    B. Use the electronic service tool to run the  “KOEO Standard

    Test”  .

    If the fault persists, contact Perkins Global Technical Support.

    C. Use the electronic service tool to check for active diagnos-

    tic codes.

    Result: The diagnostic code is no longer active.

    Return the engine to service.

    i05561312

    Injector Solenoid - Test

    This procedure covers the following codes:

    Table 64

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    High side to low side open (cylinder

    1)

    421

    High side to low side open (cylinder

    2)

    422

    423

    424

    425

    426

    431

    432

    High side to low side open (cylinder

    3)

    DTCs 421-426 are set by the Electronic Control Module (ECM) when the rising time is too

    High side to low side open (cylinder  long for the open or close coil. These codes normally indicate a harness or a coil is open.

    4)

    High side to low side open (cylinder

    5)

    High side to low side open (cylinder

    6)

    High side shorted to low side (cylin-

    der 1)

    DTCs 431-436 are set by the ECM when the rising time to 20 A is short, but not zero for

    High side shorted to low side (cylin-  the open or close coil. These codes normally indicate an internally shorted coil.

    der 2)

    (continued)

    This document has been printed from SPI2. NOT FOR RESALE.


     

    140

    KENR8774

    Diagnostic Functional Tests

    (Table 64, contd)

    Diagnostic Trouble Codes

    DTC

    Code Description

    Comments

    High side shorted to low side (cylin-

    der 3)

    433

    High side shorted to low side (cylin-

    der 4)

    434

    435

    436

    451

    452

    453

    454

    455

    456

    High side shorted to low side (cylin-

    der 5)

    High side shorted to low side (cylin-

    der 6)

    High side short to ground or VBAT

    (cylinder 1)

    High side short to ground or VBAT

    (cylinder 2)

    High side short to ground or VBAT

    (cylinder 3)

    DTCs 451-456 are set by the ECM when the rising time to 20 A is zero for the open or

    close coil. These codes normally indicate the harness or coil is shorted to ground.

    High side short to ground or VBAT

    (cylinder 4)

    High side short to ground or VBAT

    (cylinder 5)

    High side short to ground or VBAT

    (cylinder 6)

    Follow the troubleshooting procedure in order to identify the root cause of the fault.

    Function

    When the engine is running, the IDM can detect

    individual injector coil open and shorts to ground or

    battery. A Key-On Engine-Off (KOEO) Injector Test

    allows the operator to enable all injector coils when

    the engine is off to verify circuit operation. When the

    IDM detects a fault, DTCs are transmitted over the

    CAN datalink between the ECM and the IDM.

    The Injector Driver Module (IDM) is used to control

    the injectors. The IDM receives camshaft position and

    crankshaft position signals and fueling information via

    the CAN datalink from the ECM. The IDM calculates

    injection timing and injector actuation time based on

    the fuel quantity requested for any engine operating

    condition.

    The IDM transmits a high and low side drive output to

    the injectors. The high side output supplies the

    injectors with a power supply of 48 VDC at 20 A. The

    low side output supplies a return circuit to each

    injector coil.

    Injector Circuit Operation

    When a coil needs to be energized, the IDM turns on

    both the high side and low side driver.

    The injectors are under the valve cover. Each injector

    has a close and open coil. The IDM continuously

    monitors the amount of time (rising time) taken by

    each coil to draw 20 A. The time is compared to

    calibrated values and the IDM determines if a circuit

    or injector fault exists. Each injector has six failure

    modes and 3 DTCs. A failure can occur on the open

    or close coil circuit.

    High Side Drive Output

    The IDM regulates the current at an average of 20 A.

    When the current reaches 24 A, the IDM shuts off the

    high side driver. When the current drops to 16 A, the

    IDM turns on the high side driver.

    Low Side Drive Return

    When a short to ground condition is detected on an

    injector (low or high side), The IDM discontinues

    power to the shorted injector and operates the engine

    on the remaining cylinders.

    The injector solenoids are grounded through the low

    side return circuits. The ECM monitors the low side

    return circuits. The ECM monitors the low side return

    signal for diagnostic purposes and utilizes the fly

    back current from the injector solenoids to help

    charge the drive capacitors internal to the ECM.

    The last digit of the injector DTC corresponds to the

    cylinder where the fault has been detected.

    Fault Detection/Management

    This document has been printed from SPI2. NOT FOR RESALE.

     

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