5007483 ** LEVER COVER KIT EVINRUDE
B10EL4AAA, B10EL4AAB, B10EL4INS, B10PL4AAA, B10PL4AAB, B10PL4INS, B10PX4INS, B10R4AAA, B10R4AAB, B10R4INS, B10RL4INS, B10TEL4AAA, B10TEL4INS, B10TPL4AAA, B10TPL4AAB, B10TPL4INS, B10TPX4INS, B15PL4AAA, B15PL4INS, B15R4AAA, B15R4AAB, B15R4INS, B15RL4IN
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Rating:
Compatible models:
B10EL4AAA
B10EL4AAB
B10EL4INS
B10PL4AAA
B10PL4AAB
B10PL4INS
B10PX4INS
B10R4AAA
B10R4AAB
B10R4INS
B10RL4INS
B10TEL4AAA
B10TEL4INS
B10TPL4AAA
B10TPL4AAB
B10TPL4INS
B10TPX4INS
B15PL4AAA
B15PL4INS
B15R4AAA
B15R4AAB
B15R4INS
B15RL4INS
B15TE4INS
E10EL4AAB
E10EL4INS
E10PL4INS
E10TEL4AAB
E15PL4INS
E15R4INS
EVINRUDE
BRP EVINRUDE entire parts catalog list:
- BINNACLE MOUNT REMOTE CONTROL » 5007483
B10EL4INS 2012
B10PL4AAA, B10PX4AAA, E10PL4AAA, E10PX4AAA 2012
B10PL4AAB, B10PX4AAB, E10PL4AAB, E10PX4AAB 2012
B10PL4INS 2012
B10PX4INS, E10PX4INS 2012
B10R4AAA, B10RL4AAA, E10R4AAA, E10RL4AAA 2012
B10R4AAB, B10RL4AAB, B10TEL4AAB, E10R4AAB, E10RL4AAB 2012
B10R4INS, E10R4INS 2012
B10RL4INS, E10RL4INS 2012
B10TEL4AAA, E10TEL4AAA 2012
B10TEL4INS, E10TEL4INS 2012
B10TPL4AAA, B10TPX4AAA, E10TPL4AAA, E10TPX4AAA 2012
B10TPL4AAB, B10TPX4AAB, E10TPL4AAB, E10TPX4AAB 2012
B10TPL4INS, E10TPL4INS 2012
B10TPX4INS, E10TPX4INS 2012
B15PL4AAA, B15PL4AAB, E15PL4AAA, E15PL4AAB 2012
B15PL4INS 2012
B15R4AAA, B15RL4AAA, E15R4AAA, E15RL4AAA 2012
B15R4AAB, B15RL4AAB, B15TE4AAA, B15TE4AAB, B15TEL4AAA, B15TEL4AAB, E15R4AAB, E15RL4AAB, E15TE4AAA, E15TE4AAB, E15TEL4AAA, E15TEL4AAB 2012
B15R4INS, E15RL4INS 2012
B15RL4INS, B15TEL4INS, E15TE4INS, E15TEL4INS 2012
B15TE4INS 2012
E10EL4AAB 2012
E10EL4INS 2012
E10PL4INS 2012
E10TEL4AAB 2012
E15PL4INS 2012
E15R4INS 2012
Information:
Electronic Controls
Electronic Control Module
The ECM consists of two main components, the control computer (hardware) and the personality module (software). The control computer consists of a microprocessor and electronic circuitry. The Personality Module is the software for the control computer which stores operating maps that define power and torque curves refer to illustration 1. The two work together in order to control engine operation.
Illustration 1 g00648808
Personality ModuleEngine Governor
The ECM governs the engine speed by controlling the amount of fuel that is delivered by the injectors. Refer to Illustration 2. The desired engine speed is determined by input from the throttle switch. Actual engine speed is measured by the engine speed/timing sensors. The ECM changes the amount of fuel that is injected until the actual engine speed matches the desired engine speed.Fuel Injection
The ECM controls the timing and the amount of fuel that is delivered to the cylinders. This determination is based on the actual conditions and the desired conditions at any given time.The ECM compares the desired engine speed to the actual engine speed. The actual engine speed is determined via a signal from the engine speed/timing sensor. If the desired engine speed is greater than the actual engine speed, the ECM injects more fuel in order to increase the actual engine speed.The ECM controls the amount of fuel that is injected by varying the signals to the injectors. The injectors will pump fuel only if the injector solenoid is energized. The ECM sends a high voltage signal to the solenoid. This high voltage signal energizes the solenoid. By controlling the timing and the duration of the high voltage signal, the ECM can control injection timing and the amount of fuel that is injected.FRC Limit
The personality module inside the ECM sets certain limits on the amount of fuel that can be injected. The FRC limit is a limit that is based on the boost pressure. The boost pressure is calculated as the difference in pressure between atmospheric pressure and turbocharger outlet pressure. The FRC limit is used to control the air/fuel ratio for control of emissions. When the ECM senses a higher boost pressure, the ECM increases the FRC limit. A higher boost pressure indicates that there is more air in the cylinder. When the ECM increases the FRC limit, the ECM allows more fuel into the cylinder.Rated Fuel Position
The rated fuel position is a limit that is based on the power rating of the engine. The rated fuel position is similar to the rack stops and the torque spring on a mechanically governed engine. The rated fuel position determines maximum power and torque values for a specific engine family and a specific rating. The rated fuel position is programmed in the personality module at the factory.Cold Mode Operation
The ECM limits engine power during cold mode operation and the ECM modifies injection timing during cold mode operation. Cold mode operation provides the following benefits:
Increased cold weather starting capability
Reduced warm-up time
Reduced white smokeCold mode is active if the engine oil temperature falls below a predetermined value and other conditions are met. Cold mode remains active until the engine has warmed or until a time limit has been exceeded.Injection Actuation Pressure Control System
The injection actuation pressure control valve (IAPCV) that is internal to the unit injector hydraulic pump is a precision displacement control actuator. This actuator controls the swashplate angle for the variable displacement unit injector hydraulic pump. The swashplate angle controls the pump output flow to the injectors. The injection actuation pressure sensor provides a sensor signal to the ECM. The sensor signal represents the output pressure of the unit injector hydraulic pump. A desired pressure is calculated by the ECM and a control signal is sent to the IAPCV.Self-Diagnostics
The Electronic Control Module (ECM) has the ability to detect problems with the electronic system and with engine operation. When a problem is detected, a code is generated. An alarm may also be generated. There are two types of codes:
Diagnostic
EventDiagnostic Code - When a problem with the electronic system is detected, the ECM generates a diagnostic code. This indicates the specific problem with the circuitry.Diagnostic codes can have two different states:
Active
LoggedActive Code - An active diagnostic code indicates that an active problem has been detected. Active codes require immediate attention. Always service active codes prior to servicing logged codes.Logged Code - Every generated code is stored in the permanent memory of the ECM. The codes are logged.Event Code - An event code is generated by the detection of an abnormal engine operating condition. For example, an event code will be generated if the oil pressure is too low. In this case, the event code indicates the symptom of a problem.Logged codes may not indicate that a repair is needed. The problem may have been temporary. The problem may have been resolved since the logging of the code. If the system is powered, it is possible to generate an active diagnostic code whenever a component is disconnected. When the component is reconnected, the code is no longer active. Logged codes may be useful to help troubleshoot intermittent problems. Logged codes can also be used to review the performance of the engine and of the electronic system.Password
Several parameters and most logged events are protected by factory passwords. Factory passwords are available only to Caterpillar dealers.Note: Refer to Troubleshooting, "Factory Passwords" for information, if factory passwords are needed.
Illustration 2 g01762020
Illustration 3 g01762533
Electronic Control Module
The ECM consists of two main components, the control computer (hardware) and the personality module (software). The control computer consists of a microprocessor and electronic circuitry. The Personality Module is the software for the control computer which stores operating maps that define power and torque curves refer to illustration 1. The two work together in order to control engine operation.
Illustration 1 g00648808
Personality ModuleEngine Governor
The ECM governs the engine speed by controlling the amount of fuel that is delivered by the injectors. Refer to Illustration 2. The desired engine speed is determined by input from the throttle switch. Actual engine speed is measured by the engine speed/timing sensors. The ECM changes the amount of fuel that is injected until the actual engine speed matches the desired engine speed.Fuel Injection
The ECM controls the timing and the amount of fuel that is delivered to the cylinders. This determination is based on the actual conditions and the desired conditions at any given time.The ECM compares the desired engine speed to the actual engine speed. The actual engine speed is determined via a signal from the engine speed/timing sensor. If the desired engine speed is greater than the actual engine speed, the ECM injects more fuel in order to increase the actual engine speed.The ECM controls the amount of fuel that is injected by varying the signals to the injectors. The injectors will pump fuel only if the injector solenoid is energized. The ECM sends a high voltage signal to the solenoid. This high voltage signal energizes the solenoid. By controlling the timing and the duration of the high voltage signal, the ECM can control injection timing and the amount of fuel that is injected.FRC Limit
The personality module inside the ECM sets certain limits on the amount of fuel that can be injected. The FRC limit is a limit that is based on the boost pressure. The boost pressure is calculated as the difference in pressure between atmospheric pressure and turbocharger outlet pressure. The FRC limit is used to control the air/fuel ratio for control of emissions. When the ECM senses a higher boost pressure, the ECM increases the FRC limit. A higher boost pressure indicates that there is more air in the cylinder. When the ECM increases the FRC limit, the ECM allows more fuel into the cylinder.Rated Fuel Position
The rated fuel position is a limit that is based on the power rating of the engine. The rated fuel position is similar to the rack stops and the torque spring on a mechanically governed engine. The rated fuel position determines maximum power and torque values for a specific engine family and a specific rating. The rated fuel position is programmed in the personality module at the factory.Cold Mode Operation
The ECM limits engine power during cold mode operation and the ECM modifies injection timing during cold mode operation. Cold mode operation provides the following benefits:
Increased cold weather starting capability
Reduced warm-up time
Reduced white smokeCold mode is active if the engine oil temperature falls below a predetermined value and other conditions are met. Cold mode remains active until the engine has warmed or until a time limit has been exceeded.Injection Actuation Pressure Control System
The injection actuation pressure control valve (IAPCV) that is internal to the unit injector hydraulic pump is a precision displacement control actuator. This actuator controls the swashplate angle for the variable displacement unit injector hydraulic pump. The swashplate angle controls the pump output flow to the injectors. The injection actuation pressure sensor provides a sensor signal to the ECM. The sensor signal represents the output pressure of the unit injector hydraulic pump. A desired pressure is calculated by the ECM and a control signal is sent to the IAPCV.Self-Diagnostics
The Electronic Control Module (ECM) has the ability to detect problems with the electronic system and with engine operation. When a problem is detected, a code is generated. An alarm may also be generated. There are two types of codes:
Diagnostic
EventDiagnostic Code - When a problem with the electronic system is detected, the ECM generates a diagnostic code. This indicates the specific problem with the circuitry.Diagnostic codes can have two different states:
Active
LoggedActive Code - An active diagnostic code indicates that an active problem has been detected. Active codes require immediate attention. Always service active codes prior to servicing logged codes.Logged Code - Every generated code is stored in the permanent memory of the ECM. The codes are logged.Event Code - An event code is generated by the detection of an abnormal engine operating condition. For example, an event code will be generated if the oil pressure is too low. In this case, the event code indicates the symptom of a problem.Logged codes may not indicate that a repair is needed. The problem may have been temporary. The problem may have been resolved since the logging of the code. If the system is powered, it is possible to generate an active diagnostic code whenever a component is disconnected. When the component is reconnected, the code is no longer active. Logged codes may be useful to help troubleshoot intermittent problems. Logged codes can also be used to review the performance of the engine and of the electronic system.Password
Several parameters and most logged events are protected by factory passwords. Factory passwords are available only to Caterpillar dealers.Note: Refer to Troubleshooting, "Factory Passwords" for information, if factory passwords are needed.
Illustration 2 g01762020
Illustration 3 g01762533
Parts EVINRUDE:
5041708
5040983
5040983 * PLUG CAP W/RESISTANCE
B10EL4AAA, B10EL4AAB, B10EL4INS, B10PL4AAA, B10PL4AAB, B10PL4INS, B10PX4INS, B10R4AAA, B10R4AAB, B10R4INS, B10RL4INS, B10TEL4AAA, B10TEL4INS, B10TPL4AAA, B10TPL4AAB, B10TPL4INS, B10TPX4INS, B3R4AAA, B4R4AAA, B4R4INS, B6R4AAA, B6R4INS, E10EL4AAB, E10E
5040377
5040769
5040769 * RIVET 3-22
B10EL4AAA, B10EL4AAB, B10EL4INS, B10PL4AAA, B10PL4AAB, B10PL4INS, B10PX4INS, B10R4AAA, B10R4AAB, B10R4INS, B10RL4INS, B10TEL4AAA, B10TEL4INS, B10TPL4AAA, B10TPL4AAB, B10TPL4INS, B10TPX4INS, B15R4AAA, B15R4AAB, B3R4AAA, B4R4AAA, B4R4INS, B6R4AAA, B6R4
0216124
5040546
5040546 * FUEL CONNECTOR
B10EL4INS, B10PL4INS, B10PX4INS, B10R4INS, B10RL4INS, B10TEL4INS, B10TPL4INS, B10TPX4INS, B15PL4INS, B15R4INS, B15RL4INS, B15TE4INS, B6R4INS, E10EL4INS, E10PL4INS, E15PL4INS, E15R4INS
5040767
5040767 * FLOAT ARM PIN
B10EL4AAA, B10EL4AAB, B10EL4INS, B10PL4AAA, B10PL4AAB, B10PL4INS, B10PX4INS, B10R4AAA, B10R4AAB, B10R4INS, B10RL4INS, B10TEL4AAA, B10TEL4INS, B10TPL4AAA, B10TPL4AAB, B10TPL4INS, B10TPX4INS, B15PL4AAA, B15PL4INS, B15R4AAA, B15R4AAB, B15R4INS, B15RL4IN
5041285
5041285 * STOP SCREW L=15
B10EL4AAA, B10EL4AAB, B10EL4INS, B10PL4AAA, B10PL4AAB, B10PL4INS, B10PX4INS, B10R4AAA, B10R4AAB, B10R4INS, B10RL4INS, B10TEL4AAA, B10TEL4INS, B10TPL4AAA, B10TPL4AAB, B10TPL4INS, B10TPX4INS, E10EL4AAB, E10EL4INS, E10PL4INS, E10TEL4AAB