3838284 Heat exchanger Volvo.Penta
D5A-T; D5A-TA; D5A-B TA, D5A-T; D5A-TA; D5A-B TA
Heat
Price: query
Rating:
Number on catalog scheme: 1
Compatible models:
D5A-T; D5A-TA; D5A-B TA
Volvo.Penta
Volvo Penta entire parts catalog list:
- Heat Exchanger and Thermostat Housing » 3838284
- Heat Exchanger and Thermostat Housing
- Two Circuit Cooling System with Heat Exchanger, Charge Air Cooler and Thermostat Housing
- Two Circuit Cooling System with Heat Exchanger, Charge Air Cooler and Thermostat Housing
- Heat Exchanger, Components
- Heat Exchanger and Thermostat Housing. Sea Water Cooling
- Heat Exchanger and Thermostat Housing. Sea Water Cooling
- Heat Exchanger, Charge Air Cooler and Thermostat Housing. Sea Water Cooling
- Heat Exchanger, Charge Air Cooler and Thermostat Housing. Sea Water Cooling
- Keel Cooling, Two Circuit with Charge Air Cooler, Heat Exchanger and Thermostat Housing
- Keel Cooling, Two Circuit with Charge Air Cooler, Heat Exchanger and Thermostat Housing
- Heat Exchanger, Components
Information:
Engine Speed Governing
The master ECM maintains the desired engine speed by controlling the actuator for the throttle. The actuator is located at the inlet to the aftercooler. The actuator is electrically controlled and electrically actuated.The master ECM issues a throttle command that represents a percent of the level of electrical current. The output can be viewed on Caterpillar Electronic Technician (ET).Desired engine speed is determined by the status of the idle/rated switch, the desired speed input (analog voltage or 4 to 20 mA), and parameters such as maximum engine high idle speed that are programmed into the software. Actual engine speed is detected via a signal from the speed/timing sensor. Parameters such as governor gain can be programmed with Cat ET.Air/Fuel Ratio Control
The master ECM provides control of the air/fuel mixture for performance and for efficiency at low emission levels. The system consists of an electronic fuel metering valve, output drivers in the master ECM, and maps in the master ECM. The control compensates for changes in the BTU of the fuel in order to maintain desired emission levels.The following steps describe the basic operation:
The master ECM determines the desired flow rates for the air and for the fuel. The flow rates are determined by these factors:
Desired engine speed
Actual engine speed
Calculated engine load
The command for the flow of the fuel is sent to the electronic fuel metering valve via the CAN data link. This process is repeated continuously during engine operation.Start/Stop Sequencing
The master ECM contains the logic and the outputs for control of starting and of shutdown. The customer programmable logic responds to signals from the following components: engine control, emergency stop switch, remote start switch, data link and other inputs.When the programmable logic determines that it is necessary to crank the engine, the master ECM supplies +Battery voltage to the relay for the starting motor. The master ECM removes the voltage when the programmable crank terminate speed is reached or when a programmable cycle crank time has expired.The engine must be equipped with an energize-to-run type of gas shutoff valve (GSOV). The source of the voltage to the GSOV depends on the engine's configuration. The GSOV may be energized by the customer's equipment or by the engine's control system.If the engine's control system controls the GSOV, the master ECM supplies +Battery voltage to the GSOV whenever the programmable logic determines that fuel is required to operate the engine.For more information on programmable parameters, refer to Troubleshooting, "Programming Parameters".Engine Monitoring and Protection
The control system monitors both the engine operation and the engine's electrical circuits.Problems with engine operation such as low oil pressure produce an event code. The master ECM can issue a warning or a shutdown. This depends on the severity of the condition. For more information, refer to Troubleshooting, "Event Codes".Problems with an electrical circuit such as an open circuit produce a diagnostic code. For more information, refer to Troubleshooting, "Diagnostic Trouble Codes".Ignition Control
The control system provides variable ignition timing that is sensitive to detonation.Each cylinder has an ignition transformer that is located under the valve cover for the cylinder. To initiate combustion, an ECM sends a pulse of approximately 100 volts to the primary coil of an ignition transformer at the appropriate time and for the appropriate duration. The transformer steps up the voltage in order to create a spark across the spark plug electrode.Detonation sensors monitor the engine for excessive detonation. The engine has ten detonation sensors. Each sensor monitors two adjacent cylinders. The sensors generate data on vibration that is processed by each ECM in order to determine detonation levels. If detonation reaches an unacceptable level, the appropriate ECM retards the ignition timing of the affected cylinder or cylinders. If retarding the timing does not limit detonation to an acceptable level, the master ECM shuts down the engine.The master ECM and the slave ECM provide extensive diagnostics for the ignition system. The master ECM can receive a discrete input for ignition timing in order to allow operation with alternate fuels such as propane that require a timing offset.
The master ECM maintains the desired engine speed by controlling the actuator for the throttle. The actuator is located at the inlet to the aftercooler. The actuator is electrically controlled and electrically actuated.The master ECM issues a throttle command that represents a percent of the level of electrical current. The output can be viewed on Caterpillar Electronic Technician (ET).Desired engine speed is determined by the status of the idle/rated switch, the desired speed input (analog voltage or 4 to 20 mA), and parameters such as maximum engine high idle speed that are programmed into the software. Actual engine speed is detected via a signal from the speed/timing sensor. Parameters such as governor gain can be programmed with Cat ET.Air/Fuel Ratio Control
The master ECM provides control of the air/fuel mixture for performance and for efficiency at low emission levels. The system consists of an electronic fuel metering valve, output drivers in the master ECM, and maps in the master ECM. The control compensates for changes in the BTU of the fuel in order to maintain desired emission levels.The following steps describe the basic operation:
The master ECM determines the desired flow rates for the air and for the fuel. The flow rates are determined by these factors:
Desired engine speed
Actual engine speed
Calculated engine load
The command for the flow of the fuel is sent to the electronic fuel metering valve via the CAN data link. This process is repeated continuously during engine operation.Start/Stop Sequencing
The master ECM contains the logic and the outputs for control of starting and of shutdown. The customer programmable logic responds to signals from the following components: engine control, emergency stop switch, remote start switch, data link and other inputs.When the programmable logic determines that it is necessary to crank the engine, the master ECM supplies +Battery voltage to the relay for the starting motor. The master ECM removes the voltage when the programmable crank terminate speed is reached or when a programmable cycle crank time has expired.The engine must be equipped with an energize-to-run type of gas shutoff valve (GSOV). The source of the voltage to the GSOV depends on the engine's configuration. The GSOV may be energized by the customer's equipment or by the engine's control system.If the engine's control system controls the GSOV, the master ECM supplies +Battery voltage to the GSOV whenever the programmable logic determines that fuel is required to operate the engine.For more information on programmable parameters, refer to Troubleshooting, "Programming Parameters".Engine Monitoring and Protection
The control system monitors both the engine operation and the engine's electrical circuits.Problems with engine operation such as low oil pressure produce an event code. The master ECM can issue a warning or a shutdown. This depends on the severity of the condition. For more information, refer to Troubleshooting, "Event Codes".Problems with an electrical circuit such as an open circuit produce a diagnostic code. For more information, refer to Troubleshooting, "Diagnostic Trouble Codes".Ignition Control
The control system provides variable ignition timing that is sensitive to detonation.Each cylinder has an ignition transformer that is located under the valve cover for the cylinder. To initiate combustion, an ECM sends a pulse of approximately 100 volts to the primary coil of an ignition transformer at the appropriate time and for the appropriate duration. The transformer steps up the voltage in order to create a spark across the spark plug electrode.Detonation sensors monitor the engine for excessive detonation. The engine has ten detonation sensors. Each sensor monitors two adjacent cylinders. The sensors generate data on vibration that is processed by each ECM in order to determine detonation levels. If detonation reaches an unacceptable level, the appropriate ECM retards the ignition timing of the affected cylinder or cylinders. If retarding the timing does not limit detonation to an acceptable level, the master ECM shuts down the engine.The master ECM and the slave ECM provide extensive diagnostics for the ignition system. The master ECM can receive a discrete input for ignition timing in order to allow operation with alternate fuels such as propane that require a timing offset.