471523 Connecting rod Volvo.Penta
TD61A; TD61AW; TD61ACE
Connecting
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$73.38
28-02-2018
158 Hundredths Pounds
A1 Cardone: A1 Cardone
Cardone 47-1523 Remanufactured Import Window Lift Motor
Gears are redesigned with a stronger, less brittle material which eliminates the main mode of failure.||New high quality gaskets are used in every window lift unit which prevents water from entering the unit.||All original components are triple-tested to ensure "like new" performance||Every unit is 100% tested to ensure quality and reliability
Gears are redesigned with a stronger, less brittle material which eliminates the main mode of failure.||New high quality gaskets are used in every window lift unit which prevents water from entering the unit.||All original components are triple-tested to ensure "like new" performance||Every unit is 100% tested to ensure quality and reliability
Compatible models:
TD61A; TD61AW; TD61ACE
Volvo.Penta
Volvo Penta entire parts catalog list:
Information:
the air inlet temperature is greater than 90 °C (194 °F) for more than four seconds.System Response:The Electronic Control Module (ECM) logs the event. The ECM transmits a warning to the display in the cab. The ECM will reset the event when the air inlet temperature is less than 87 °C (189 °F) for more than four seconds.
Low powerTest Step 1. Check the Engine
Check for a problem in the engine's air inlet and exhaust systems.
Check for a restriction in the air inlet system. A restriction of the air that is coming into the engine can cause high cylinder temperatures. High cylinder temperatures cause higher than normal temperatures in the cooling system.
Check for a restriction in the exhaust system. A restriction of the air that is coming out of the engine can cause high cylinder temperatures.
If the air inlet system for this application is equipped with an aftercooler, check the aftercooler. A restriction of air flow through the air to air aftercooler can cause overheating. Check for debris or deposits which would prevent the free flow of air through the aftercooler.
Check the operating conditions of the engine.
Consider high ambient temperatures. When ambient temperatures are too high for the rating of the cooling system, there is not enough of a temperature difference between the ambient air and coolant temperatures.
Consider high altitude operation. The cooling capability of the cooling system is reduced at higher altitudes. A pressurized cooling system that is large enough to keep the coolant from boiling must be used.
The engine may be running in the lug condition. When the load that is applied to the engine is too large, the engine will run in the lug condition. When the engine is running in the lug condition, engine rpm does not increase with an increase of fuel. This lower engine rpm causes a reduction in coolant flow through the system.
High cooling system temperatures can cause high air inlet temperatures. Check the cooling system for problems.
Verify that the cooling system is filled with coolant to the proper level. If the coolant level is too low, air may be allowed to enter the cooling system. Air in the cooling system will cause cavitation and a reduction in coolant flow.
Check the quality of the coolant. Refer to the Operation and Maintenance Manual for coolant recommendations.
Check for air in the cooling system. Air can be introduced into the cooling system in different ways. The most common cause of air in the cooling system is the improper filling of the cooling system. Refer to the Operation and Maintenance Manual for the proper filling procedure for your engine.The next likely cause is combustion gas leakage into the cooling system. Combustion gas can be introduced into the cooling system through damaged liner seals, cracks in the liners, a damaged cylinder head, or a damaged cylinder head gasket.
Check the cooling system hoses and clamps for damage.Clamps that are damaged and hoses that are leaking can usually be discovered during a visual inspection.Hoses that have no visual leaks can soften during operation. The soft areas of the hose can kink or the soft areas of the hose may collapse during operation. This can restrict the coolant flow. This can cause the engine to overheat. Check the hoses for soft spots.Internal cracks can also develop in cooling system hoses. This type of deterioration usually produces particles that can build up in the cooling system. This may cause a restriction in the coolant flow through components. Check the hoses for spots that are hard or brittle.
Check the water pump. Remove the water pump and check for damage to the impeller. A water pump with a damaged impeller will not pump an adequate amount of coolant through the system.
Check the operation of the water temperature regulator. A water temperature regulator that does not open, or a water temperature regulator that only opens part of the way can cause overheating.
If the cooling system for this application is equipped with an expansion tank, check the shunt line for the expansion tank.The shunt line must be submerged in the expansion tank. If the shunt line is not submerged, air will be introduced into the cooling system.Check the shunt line for a restriction. A restriction of the shunt line from the expansion tank to the inlet of the water pump will cause a reduction in water pump efficiency. A reduction in water pump efficiency will result in low coolant flow.Expected Result:A thorough inspection of the engine revealed the cause of the high air inlet temperature.Results:
OK - The cause of the high air inlet temperature has been identified.Repair: Repair the problem. Ensure that the repair eliminates the original problem.STOP
Low powerTest Step 1. Check the Engine
Check for a problem in the engine's air inlet and exhaust systems.
Check for a restriction in the air inlet system. A restriction of the air that is coming into the engine can cause high cylinder temperatures. High cylinder temperatures cause higher than normal temperatures in the cooling system.
Check for a restriction in the exhaust system. A restriction of the air that is coming out of the engine can cause high cylinder temperatures.
If the air inlet system for this application is equipped with an aftercooler, check the aftercooler. A restriction of air flow through the air to air aftercooler can cause overheating. Check for debris or deposits which would prevent the free flow of air through the aftercooler.
Check the operating conditions of the engine.
Consider high ambient temperatures. When ambient temperatures are too high for the rating of the cooling system, there is not enough of a temperature difference between the ambient air and coolant temperatures.
Consider high altitude operation. The cooling capability of the cooling system is reduced at higher altitudes. A pressurized cooling system that is large enough to keep the coolant from boiling must be used.
The engine may be running in the lug condition. When the load that is applied to the engine is too large, the engine will run in the lug condition. When the engine is running in the lug condition, engine rpm does not increase with an increase of fuel. This lower engine rpm causes a reduction in coolant flow through the system.
High cooling system temperatures can cause high air inlet temperatures. Check the cooling system for problems.
Verify that the cooling system is filled with coolant to the proper level. If the coolant level is too low, air may be allowed to enter the cooling system. Air in the cooling system will cause cavitation and a reduction in coolant flow.
Check the quality of the coolant. Refer to the Operation and Maintenance Manual for coolant recommendations.
Check for air in the cooling system. Air can be introduced into the cooling system in different ways. The most common cause of air in the cooling system is the improper filling of the cooling system. Refer to the Operation and Maintenance Manual for the proper filling procedure for your engine.The next likely cause is combustion gas leakage into the cooling system. Combustion gas can be introduced into the cooling system through damaged liner seals, cracks in the liners, a damaged cylinder head, or a damaged cylinder head gasket.
Check the cooling system hoses and clamps for damage.Clamps that are damaged and hoses that are leaking can usually be discovered during a visual inspection.Hoses that have no visual leaks can soften during operation. The soft areas of the hose can kink or the soft areas of the hose may collapse during operation. This can restrict the coolant flow. This can cause the engine to overheat. Check the hoses for soft spots.Internal cracks can also develop in cooling system hoses. This type of deterioration usually produces particles that can build up in the cooling system. This may cause a restriction in the coolant flow through components. Check the hoses for spots that are hard or brittle.
Check the water pump. Remove the water pump and check for damage to the impeller. A water pump with a damaged impeller will not pump an adequate amount of coolant through the system.
Check the operation of the water temperature regulator. A water temperature regulator that does not open, or a water temperature regulator that only opens part of the way can cause overheating.
If the cooling system for this application is equipped with an expansion tank, check the shunt line for the expansion tank.The shunt line must be submerged in the expansion tank. If the shunt line is not submerged, air will be introduced into the cooling system.Check the shunt line for a restriction. A restriction of the shunt line from the expansion tank to the inlet of the water pump will cause a reduction in water pump efficiency. A reduction in water pump efficiency will result in low coolant flow.Expected Result:A thorough inspection of the engine revealed the cause of the high air inlet temperature.Results:
OK - The cause of the high air inlet temperature has been identified.Repair: Repair the problem. Ensure that the repair eliminates the original problem.STOP
Parts connecting Volvo Penta:
843247
843247 Connecting pipe
AD31D; AD31D-A; AD31XD, AD31L-A; AD31P-A; AD41L-A, AD41D; D41D; TAMD41D, D3-110I-D; D3-110I-E; D3-110I-F, D3-110I-G; D3-140A-G; D3-140I-G, D3-110I-H; D3-140A-H; D3-140I-H, D4-180I-B; D4-180I-C; D4-180I-D, D4-180I-F; D4-225A-F; D4-225I-F, D6-280A-A; D
241149
241149 Connecting kit
AQD70D; TAMD70D; TAMD70E, D100A; D100AK; D100B, D100BHC; D100BRC; TD100AHC, D120A; D120AK; TD120A, D42A; D42A PP, D70B; D70B PP; D70B K, D70CHC; D70CRC; TD70CHC, MD100A; TMD100A; TMD100AK, MD120A; MD120AK; TMD120A, MD70B; MD70BK; TMD70B, MD70C; TMD70
465812
465812 Connecting rod
TAMD61A; TAMD62A, TAMD63L-A; TAMD63P-A, TD61A; TD61AW; TD61ACE, TWD610P; TWD610PB; TWD710P
346940
346940 Connecting rod
D100A; D100AK; D100B, D120A; D120AK; TD120A, D70B; D70B PP; D70B K, TD100G-87; TD1030ME; TWD1030ME, TD100G; TD100G-85; TD100G-87, TD60A; TD60B; TD60B PP, TD60D; TD60D-83; TD60DPP-83, TD61A; TD61AW; TD61ACE, TD70G; TD70G-83; TD70GPP
1698678
1698678 Connecting rod
TAD1030P, TAD1230P; TD121GP-87; TWD1210P, TD100G-87; TD1030ME; TWD1030ME, TD100G-87; TD1030VE; TAD1030V, TD121G-87; TWD1210V; TWD1211V, TD164KAE, TD610M; TD630ME; TWD630ME, TD61A; TD61AW; TD61ACE, TD71A; TID71A; TWD710V, TWD1230ME, TWD610P; TWD610PB;
3090386
3090386 Connecting rod
TAD1230P; TD121GP-87; TWD1210P, TD100G-87; TD1030ME; TWD1030ME, TD100G-87; TD1030VE; TAD1030V, TD121G-87; TWD1210V; TWD1211V, TD610M; TD630ME; TWD630ME, TD610V; TWD610V; TD630VE, TD61A; TD61AW; TD61ACE, TD71A; TID71A; TWD710V, TWD1230ME, TWD610P; TWD
3090257
3090257 Connecting rod
TD100G-87; TD1030VE; TAD1030V, TD61A; TD61AW; TD61ACE, TWD1230ME, TWD610P; TWD610PB; TWD710P
846793
846793 Connecting pipe
TD60D; TD60D-83; TD60DPP-83, TD610G; TWD610G; TD710G, TD610M; TD630ME; TWD630ME, TD610V; TWD610V; TD630VE, TD61A; TD61AW; TD61ACE, TD71A; TID71A; TWD710V, TWD610P; TWD610PB; TWD710P