1104211 RIM AS Caterpillar parts
69D, 768C, 769C, 769D, 770, 770G, 770G OEM, 771C, 771D, 772G
Rating:
Alternative (cross code) number:
CA1104211
110-4211
1104211
CA1104211
110-4211
1104211
Weight: 348 pounds 158 kg.
QUARRY TRUCK, TRUCK,
You can buy:
This part in 2 request:
Show.
This information for suppliers only!
2020-09-18
2020-07-30
Compatible equipment models: 1104211:
Number on catalog scheme:
4
For full view, you need register
Information:
General Information
Starting systems usually have four major components: ... Start switch... Start relay... Starter solenoid... Starter motor
Illustration 1. Typical cranking circuit.The only exception to this typical cranking circuit is that some small engines do not require the start relay. In this case, the start switch is connected directly to the starter solenoid.
Start switches are relatively low current devices. They are rated to switch approximately 5 to 20 amps. Because the coil of a start relay between TP2 (Test Point 2) and TP1 in Illustration 1 draws about 1 amp, the start switch can easily turn on the start relay and have long life.
The switch contacts of a typical start relay are rated to switch between 100 and 300 amps. Because a starter solenoid requires only 5 to 50 amps, the start relay can easily switch this load.
The starter solenoid has two functions: it engages the pinion with the flywheel, and it is a high current switch rated about 1000 amps that actually turns on the starting motor.
The starter solenoid has two coils: the pull-in coil (W) draws about 40 amps and hold-in coil (X) requires about 5 amps. The instant the start relay closes, both coils (W and X) receive power. Battery voltage is applied to the high end of both coils, at Test Point (3) which is the "start" terminal (S). The low end of hold-in coil (X) is permanently connected to the ground post of the starter motor. Grounding for the low end, Test Point (4), of pull-in coil (W) is momentary, and takes place through the DC resistance of the starter motor. When magnetic force builds in both coils, the starter pinion is moved to engage the ring gear. Only then will the solenoid contacts close to power the starter motor. This temporarily removes the ground from pull-in coil (W), and puts battery voltage on both ends of it while the motor cranks. During this period, the pull-in coil is out of the circuit and draws no current. Cranking continues until power to the motor solenoid is turned off by the start switch.
The result of these switches and relays is to permit a 5 amp dash-mounted switch to turn on a 500 to 1000 amp motor for cranking an engine.
Battery voltage (power) available during cranking depends on the temperature of the batteries. See Chart A. This chart is only a GUIDE as to what to expect from a NORMAL system.
Chart B shows maximum allowable voltage drops in the high current battery circuit to the starter. These values are maximums for machines with more than about 2000 SMH. Newer machines have less voltage drops.
Voltage drops greater than those listed are usually caused by loose and/or corroded connections or bad switch contacts.
The entire diagnostic procedure can be reduced to: ... confirming that batteries are within specifications... switches and cables/wiring from the batteries to the starter are not causing too much voltage loss.
The flow chart in Illustration 2 shows the entire procedure.
If the machine is equipped
Starting systems usually have four major components: ... Start switch... Start relay... Starter solenoid... Starter motor
Illustration 1. Typical cranking circuit.The only exception to this typical cranking circuit is that some small engines do not require the start relay. In this case, the start switch is connected directly to the starter solenoid.
Start switches are relatively low current devices. They are rated to switch approximately 5 to 20 amps. Because the coil of a start relay between TP2 (Test Point 2) and TP1 in Illustration 1 draws about 1 amp, the start switch can easily turn on the start relay and have long life.
The switch contacts of a typical start relay are rated to switch between 100 and 300 amps. Because a starter solenoid requires only 5 to 50 amps, the start relay can easily switch this load.
The starter solenoid has two functions: it engages the pinion with the flywheel, and it is a high current switch rated about 1000 amps that actually turns on the starting motor.
The starter solenoid has two coils: the pull-in coil (W) draws about 40 amps and hold-in coil (X) requires about 5 amps. The instant the start relay closes, both coils (W and X) receive power. Battery voltage is applied to the high end of both coils, at Test Point (3) which is the "start" terminal (S). The low end of hold-in coil (X) is permanently connected to the ground post of the starter motor. Grounding for the low end, Test Point (4), of pull-in coil (W) is momentary, and takes place through the DC resistance of the starter motor. When magnetic force builds in both coils, the starter pinion is moved to engage the ring gear. Only then will the solenoid contacts close to power the starter motor. This temporarily removes the ground from pull-in coil (W), and puts battery voltage on both ends of it while the motor cranks. During this period, the pull-in coil is out of the circuit and draws no current. Cranking continues until power to the motor solenoid is turned off by the start switch.
The result of these switches and relays is to permit a 5 amp dash-mounted switch to turn on a 500 to 1000 amp motor for cranking an engine.
Battery voltage (power) available during cranking depends on the temperature of the batteries. See Chart A. This chart is only a GUIDE as to what to expect from a NORMAL system.
Chart B shows maximum allowable voltage drops in the high current battery circuit to the starter. These values are maximums for machines with more than about 2000 SMH. Newer machines have less voltage drops.
Voltage drops greater than those listed are usually caused by loose and/or corroded connections or bad switch contacts.
The entire diagnostic procedure can be reduced to: ... confirming that batteries are within specifications... switches and cables/wiring from the batteries to the starter are not causing too much voltage loss.
The flow chart in Illustration 2 shows the entire procedure.
If the machine is equipped
Caterpillar parts catalog:
Parts rim Caterpillar catalog:
69D, 768C, 769C, 769D, 771C, 771D, 963
2467599
RIM GP-DEMOUNTABLE
770, 770G, 770G OEM
770, 770G, 770G OEM
1149219
RIM GP-SINGLE
769C, 769D, 770, 770G, 770G OEM, 771D, 772G
769C, 769D, 770, 770G, 770G OEM, 771D, 772G
1432138
RIM GP
69D, 769C, 769D, 770, 770G, 770G OEM, 771D, 772G
69D, 769C, 769D, 770, 770G, 770G OEM, 771D, 772G
1111733
RIM GP
769C
769C
1360479
RIM GP
771D
771D
1560217
RIM GP
769D, 770
769D, 770
1622179
RIM GP
769D
769D
1118740
RIM GP
771D
771D
2643169
RIM GP
772, 772G, 772G OEM
772, 772G, 772G OEM
768C, 769C, 771D
2638883
RIM AS
772, 772G, 772G OEM
772, 772G, 772G OEM
773B, 773D, 773E
6G1742
RIM AS
772, 772B, 773B, 773D, 773E, 773F
772, 772B, 773B, 773D, 773E, 773F
2A7313
RIM AS
772B, 773B, 773D, 773E, 773F, 775B, 775D, 775E, 775F, 775G, 775G OEM
772B, 773B, 773D, 773E, 773F, 775B, 775D, 775E, 775F, 775G, 775G OEM
1379859
RIM AS
789B
789B
1047208
RIM AS
789B
789B
1047204
RIM AS
789, 789B
789, 789B
740, D350E, D350E II, D400E, D400E II
1666397
RIM AS
725, 730, D250E II, D300E, D300E II
725, 730, D250E II, D300E, D300E II
1251995
RIM AS
D300E, D300E II
D300E, D300E II
1244478
RIM AS
D300E, D300E II
D300E, D300E II
1532776
RIM AS
D250E, D250E II
D250E, D250E II
1180588
RIM AS
D250E, D250E II
D250E, D250E II