8M0047129 COVER ASSEMBLY Mariner
7200V13IR, 7200V23ID, 7200V23IR, 7225413IY, 7225V13ID, 7225V13IR, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250423IY, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID
COVER
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- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
7225V13ID 2006
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
7250V13ID 2006,2007
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
- GEAR HOUSING, OFFSHORE, DRIVESHAFT » 8M0047129
- GEAR HOUSING(DRIVESHAFT)(STANDARD-COUNTER ROTATION) » 8M0047129
Information:
Introduction
The article below explains the proper interpretation of oil samples that are taken from 770G and 772G Off-Highway Truck (OHT) engines. The oil samples that are taken from these engines have shown some unique characteristics. These characteristics could be misunderstood. A misinterpretation of the results from the oil sample could lead to unnecessary inspections or repairs. The problem that is identified below does not have a known permanent solution. Until a permanent solution is known, use the solution that is identified below.Problem
Oil samples taken from 770G and 772G engines have shown highly elevated values of potassium and aluminum. The elevated values may occur during the first thousand hours of operation. After the first thousand hours of operation, the potassium (K) and aluminum (Al) will slowly decrease to more typical levels.The source of these elements has been traced to the brazing flux that is used to manufacture the aluminum Air-to-Air Aftercooler (ATAAC). The brazing flux is made from a compound that contains a high concentration of potassium and aluminum. Residual amounts of this flux remain in the new ATAAC. Air from the turbocharger flows through the ATAAC during operating conditions. Moisture in the air reacts chemically with the brazing flux. This reaction releases small amounts of potassium and aluminum into the air stream. The potassium and aluminum enter the engine oil through the combustion air and the oil film on the cylinder liners.In oil sample analysis, potassium (K) is commonly used as an indicator of coolant contamination. Aluminum (Al) is commonly used to indicate severe bearing wear and dirt entry. The correct interpretation of the oil sample is difficult when elevated values of potassium and aluminum are present.Solution
Potassium and aluminum from the core of the ATAAC do not cause abnormal wear of the engine. Iron, lead, and chromium values are not affected by this source of potassium and aluminum. The service life of the core of the ATAAC is not reduced by the reaction with the brazing flux.Potassium could reach 200 parts per million and aluminum could reach 100 parts per million during the first thousand hours of operation. The ratio of potassium to aluminum is about 3 to 1 in most samples. After the first thousand hours of operation, the potassium and aluminum will slowly decrease. Potassium will eventually reach 25 parts per million or less. Aluminum will eventually reach 10 parts per million or less.Elevated potassium from the ATAAC brazing flux will make the identification of coolant contamination more difficult. Most heavy-duty coolants contain high concentrations of sodium and/or potassium compounds. Sodium and potassium results are used to determine if coolant has entered the engine oil. An indicator of coolant contamination in the oil sample is 25 parts per million or more of sodium and/or potassium. The ATAAC brazing flux may temporarily elevate potassium levels. If there are elevated levels of potassium, the analyst must use other indicators to determine if the engine oil has been contaminated with coolant. The following items are other indicators of coolant contamination.
25 parts per million or more of sodium
Positive water
Elevated levels of boron, magnesium, silicon, and copper
Positive glycolA trained Schedule Oil Sampling (S O S) analyst uses these other indicators to determine if the oil is contaminated with coolant.Elevated aluminum values could indicate severe wear on connecting rod or main bearings. The S O S analyst should look for correlating evidence of bearing wear when elevated aluminum levels are occurring. If bearing wear is occurring, there will also be highly elevated lead values and elevated iron values. The lead is part of the overlay on the bearing surface. If lead values are normal, the bearing wear is highly unlikely. Severe bearing wear will also increase the wear on iron components within the engine. The source of the iron wear is from the crankshaft.Elevated aluminum could also be an indication of dirt entry. The combination of elevated Si and Al is used to identify dirt contamination of an engine oil. With dirt entry, the Si value is 3 to 5 times higher than the Al value. If Si values are normal, then the elevated Al is not part of dirt contamination. Dirt contamination also causes abrasive wear in the engine. Therefore, iron, lead, chrome, and copper values are elevated when dirt contamination is present. If the silicon levels are normal, and the wear metals are normal, dirt contamination is not present.After these initial spikes in potassium and aluminum, the results from the oil samples should slowly return to normal. Continue to use trend analysis and S O S guidelines for evaluating subsequent oil samples.
The article below explains the proper interpretation of oil samples that are taken from 770G and 772G Off-Highway Truck (OHT) engines. The oil samples that are taken from these engines have shown some unique characteristics. These characteristics could be misunderstood. A misinterpretation of the results from the oil sample could lead to unnecessary inspections or repairs. The problem that is identified below does not have a known permanent solution. Until a permanent solution is known, use the solution that is identified below.Problem
Oil samples taken from 770G and 772G engines have shown highly elevated values of potassium and aluminum. The elevated values may occur during the first thousand hours of operation. After the first thousand hours of operation, the potassium (K) and aluminum (Al) will slowly decrease to more typical levels.The source of these elements has been traced to the brazing flux that is used to manufacture the aluminum Air-to-Air Aftercooler (ATAAC). The brazing flux is made from a compound that contains a high concentration of potassium and aluminum. Residual amounts of this flux remain in the new ATAAC. Air from the turbocharger flows through the ATAAC during operating conditions. Moisture in the air reacts chemically with the brazing flux. This reaction releases small amounts of potassium and aluminum into the air stream. The potassium and aluminum enter the engine oil through the combustion air and the oil film on the cylinder liners.In oil sample analysis, potassium (K) is commonly used as an indicator of coolant contamination. Aluminum (Al) is commonly used to indicate severe bearing wear and dirt entry. The correct interpretation of the oil sample is difficult when elevated values of potassium and aluminum are present.Solution
Potassium and aluminum from the core of the ATAAC do not cause abnormal wear of the engine. Iron, lead, and chromium values are not affected by this source of potassium and aluminum. The service life of the core of the ATAAC is not reduced by the reaction with the brazing flux.Potassium could reach 200 parts per million and aluminum could reach 100 parts per million during the first thousand hours of operation. The ratio of potassium to aluminum is about 3 to 1 in most samples. After the first thousand hours of operation, the potassium and aluminum will slowly decrease. Potassium will eventually reach 25 parts per million or less. Aluminum will eventually reach 10 parts per million or less.Elevated potassium from the ATAAC brazing flux will make the identification of coolant contamination more difficult. Most heavy-duty coolants contain high concentrations of sodium and/or potassium compounds. Sodium and potassium results are used to determine if coolant has entered the engine oil. An indicator of coolant contamination in the oil sample is 25 parts per million or more of sodium and/or potassium. The ATAAC brazing flux may temporarily elevate potassium levels. If there are elevated levels of potassium, the analyst must use other indicators to determine if the engine oil has been contaminated with coolant. The following items are other indicators of coolant contamination.
25 parts per million or more of sodium
Positive water
Elevated levels of boron, magnesium, silicon, and copper
Positive glycolA trained Schedule Oil Sampling (S O S) analyst uses these other indicators to determine if the oil is contaminated with coolant.Elevated aluminum values could indicate severe wear on connecting rod or main bearings. The S O S analyst should look for correlating evidence of bearing wear when elevated aluminum levels are occurring. If bearing wear is occurring, there will also be highly elevated lead values and elevated iron values. The lead is part of the overlay on the bearing surface. If lead values are normal, the bearing wear is highly unlikely. Severe bearing wear will also increase the wear on iron components within the engine. The source of the iron wear is from the crankshaft.Elevated aluminum could also be an indication of dirt entry. The combination of elevated Si and Al is used to identify dirt contamination of an engine oil. With dirt entry, the Si value is 3 to 5 times higher than the Al value. If Si values are normal, then the elevated Al is not part of dirt contamination. Dirt contamination also causes abrasive wear in the engine. Therefore, iron, lead, chrome, and copper values are elevated when dirt contamination is present. If the silicon levels are normal, and the wear metals are normal, dirt contamination is not present.After these initial spikes in potassium and aluminum, the results from the oil samples should slowly return to normal. Continue to use trend analysis and S O S guidelines for evaluating subsequent oil samples.
Parts cover Mariner:
892854T01
888491
888491 COVER
7135V13ID, 7135V13UB, 7135V13ZB, 7200V13IR, 7200V23ID, 7200V23IR, 7225V13ID, 7225V13IR, 7225V13TF, 7225V13UB, 7225V13ZB, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID
880596T50
880596T50 COVER KIT
7135V13ID, 7135V13UB, 7135V13ZB, 7200V13IR, 7200V23ID, 7200V23IR, 7225V13ID, 7225V13IR, 7225V13TF, 7225V13UB, 7225V13ZB, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID, 7F75413ZD
887936T04
887936T04 COVER, Flywheel
7200V13IR, 7200V23ID, 7200V23IR, 7225V13ID, 7225V13IR, 7225V13TF, 7225V13UB, 7225V13ZB, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID
893405T
893405T COVER
7200V13IR, 7200V23ID, 7200V23IR, 7225V13ID, 7225V13IR, 7225V13TF, 7225V13UB, 7225V13ZB, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID
879150A90
8M0050726
8M0050726 COVER KIT
7200V13IR, 7200V23ID, 7200V23IR, 7225V13ID, 7225V13IR, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID
8M0050821
8M0050821 COVER KIT, Flush, Standard
7200V13IR, 7200V23ID, 7200V23IR, 7225V13ID, 7225V13IR, 7225V23ID, 7225V23IR, 7225V24IB, 7225V24ID, 7250V13ID, 7250V23IR, 7275V23ID, 7275V23IR, 7300V23ID