Usage:
This instruction is written for electronic technicians only, and must not be used by service personnel with no training or knowledge of electronics. For repairs that can be done by the Caterpillar Dealer Serviceman, with no knowledge of electronics, see Special Instruction Form SMHS6964 "Using 1P3500 and 2P8280 Injection Timing Groups."
As an aid to the technician for troubleshooting the inverter and timing light, the following information is given in this instruction:
- 1. Circuit board illustrations showing the position of each of the components and the test points (T) for using a voltmeter or an oscilloscope.
- 2. Schematics of the electrical circuit so the technician can easily follow the sequence of the circuit.
- 3. Test point values.
- 4. Electrical parts replacement information.
- 5. Timing light calibration procedure.
- 2. Schematics of the electrical circuit so the technician can easily follow the sequence of the circuit.
Timing Light
1P3500 And 2P8280 Timing Lights - Electrical Schematic, Test Points And Parts List
Inverter - Electrical Schematic, Test Points And Parts List
There is a two position switch that is marked ADV.-RPM on the side of the 1P3499 Timing Light. When the timing light is in use, operation of the ADV.-RPM switch is as follows:
RPM Position
A fuel injection pulse opens the switch in the transducer and starts a positive pulse (TP9) of fixed duration, from the monostable composed of Q2 and Q3. This pulse turns on a transistor switch Q4, allowing current to pass through meter M1, which mechanically averages pulses from an operating engine, and is calibrated to read RPM. Switch S2 grounds the gate of SCR1 to prevent the flash tube from strobing.
ADV. Position
A fuel injection pulse again starts a pulse from the monostable. Adjustment of R7, the TIME-ADVANCE control, now determines the pulse duration from the monostable. When R7 is adjusted so that TDC on the damper coincides with the pointer on the block of an operating engine, the monostable pulse duration is exactly the same as the fuel system advance measured in seconds. Transistor switch Q4 again turns on, allowing current to pass through meter M1, causing a meter indicator that is calibrated in degrees of advance instead of seconds.
Electrical Calibration Procedure
Before the electrical calibration can be done, the following equipment must be obtained.
- 1) Oscilloscope with triggered sweep. Heath Co. M/N SO-4530 or equivalent.
- 2) Signal generator. Heath M/N SG-72A or equivalent.
- 3) Electronic counter. Data Precision M/N 5740 or equivalent.
- 4) Electronic switch (dealer built).
- 2) Signal generator. Heath M/N SG-72A or equivalent.
Calibration Procedure
(1) Hold the 1P3499 Timing Light in the same position (about a 45° angle) as if measuring the timing advance on an engine, and check the mechanical meter zero. Make an adjustment to zero if necessary.
(2) To remove the protective rubber boot from the flash tube, twist the rubber boot and pull it away from the timing light as shown.
(3) Remove the right side (side that has the serial number tag) of the timing light case.
(4) Connect the 1P3499 Timing Light to a circuit like the one that follows. This will simulate (be the same as) a fuel flow transducer on an engine that is operating at 2400 RPM.
(5) Turn the TIME-ADV. control counterclockwise (CCW) to its minimum ADV. position, which is just before the control switches to the TIME position.
(6) Move the RPM-ADV. switch to the ADV. position. Check the calibration of the counter and scope if possible.
(7) Connect the scope from TP9 (violet wire on R7) to circuit ground (ground side of CR-6). Set the scope to 2V/DIV. vertical deflection and 50 mus/DIV. triggered sweep.
(8) Put a jumper across the trigger switch, S1 [a piece of .060" (1.5) solder wedged between the two contacts works very well] on the 1P3499 Timing Light. Connect the timing light to 110 V AC.
(9) Adjust R9 for a 180-250 microseconds wide pulse. The timing light should be flashing.
(10) Turn the TIME-ADV. control fully clockwise (CW) and observe the pulse width at TP9. It should be at least 6 milliseconds. If it is not, pad C8 with .07 MFD per additional millisecond required.
(11) Adjust the TIME-ADV. control (R7) to obtain exactly a 2.50 millisecond wide pulse on the scope. Sweep: .5 ms/DIV. Vertical: 2V/DIV.
(12) Hold the timing light at 45° as if it were being used on an engine to measure advance. Adjust R8 for 36° advance on meter M1.
(13) Set the RPM-ADV. switch to RPM and adjust R20 to get 2400 RPM on meter M1.
(14) Check again to make sure of the 36° and 2400 RPM settings.
(15) Assemble the timing light and check the 2400 RPM setting.
Timing Light Test Point Values
(1) To measure the test point values 1 through 6, use a Simpson 260 VOM, or equivalent with No trigger supplied to the timing light, but with the trigger button depressed.
(2) All waveforms are taken from a test made on a Caterpillar Fuel Injection Test Bench operating at 1000 RPM using the correct fuel flow transducer. Similar waveforms can be obtained using the testing circuit described in Step 4 of the topic, CALIBRATION PROCEDURE.
(3) The scope waveforms for test points 7 and 8 are with the TIME-ADVANCE control in the TIME position and the ADV.-RPM switch in the ADV. position.
(4) The waveforms for test points 9, 10 and 11 are with the TIME-ADVANCE control in the ADVANCE position and the ADV.-RPM switch in the ADVANCE position. Note: Min. 6 ms location (A) at the FULL ADVANCE position (the more degrees of advance, the wider the pulse width).
Inverter
Inverter Test Point Values
To measure the test point values, plug a 230V, 40W or a 130V, 25W light bulb into the inverter output receptacle.