- Caterpillar Products
- All C27 Engines
- All C32 Engines
Introduction
This Special Instruction provides guidance for when levels of lead (Pb) in engine oil samples are elevated to a point of Action Required according to S·O·S wear tables.
Lead in engine oil does not always come from main or rod bearings. However this Special Instruction presumes that the bearings are the most likely source. Lead from other sources, such as excessive thrust washer or bronze bushing wear, most commonly is accompanied by highly elevated levels of copper (Cu).
Note: This publication is to be used to explore the root cause of elevated lead in oil samples. Due to the risk of debris introduction from physical bearing inspections or replacements, investigate the root cause thoroughly prior to disassembling the engine.
Additional Resources
Professional classroom instruction on oil sampling, analysis, and interpretation is available, course 08E1017 S·O·S Services Interpretation Training I. Course information, help sheets, wear tables, and community discussion is available under S·O·S Services on Dealer.cat.com (https://dealer.cat.com/en/home.html). Other helpful resources:
- Operation and Maintenance Manual, SEBU6250, "Caterpillar Machine Fluids Recommendations"
- Special Instruction, SEBD0640, "Oil and Your Engine"
Action Required : Example
Valid at 500 Oil Hours | Typical C32 Machine Engine Wear | ||
---|---|---|---|
Element | No Action Required | Monitor | Action Required |
Copper | 0 to 15 | 16 to 19 | Over 19 |
Iron | 0 to 28 | 29 to 34 | Over 34 |
Chromium | 0 to 2 | 3 to 4 | Over 4 |
Aluminum | 0 to 3 | 4 to 5 | Over 5 |
Lead | 0 to 5 | 6 to 7 | Over 7 |
Silicon | 0 to 10 | 11 to 13 | Over 13 |
Tin | 0 to 2 | 3 to 4 | Over 4 |
Typical example wear table. Values subject to change.
Illustration 1 | g06216457 |
Example of a trend chart with lead (Pb) and Oxidation elevated to Action Required |
If an oil analysis returns from the lab with an elevated level of lead and action is required, follow the steps listed below.
- Review and Validate the Sample
- Determine the Root Cause - Wear or Chemistry
- Resolve and Proceed
Review and Validate the Sample
Illustration 2 | g03403239 |
Sample Collection, Age, and Analysis
Verify that the sample was collected and delivered correctly. Verify that the lab has been used in the past. Verify the hours of the oil. Was an oil change missed?
Compare to Trend
Has the lead (Pb) level in the oil from this engine been steady or trending upward in recent samples? If the lead level is trending up, has the rate of increase been gradual or rapid? Has a follow-up sample been taken and analyzed to confirm a rapidly increasing trend? If the trend is indeed increasing rapidly, the engine should be shutdown and action taken immediately to investigate and resolve the problem. A rapid increase occurs when the Pb sample results go from normal to Action Required within one sampling period.
Service Records
Carefully consider service records including recent component changes, modifications to lubrication, cooling or fuel systems, or any adjustments to the oil renewal system if equipped. Do service records reflect any change of suppliers or formulations of oil, coolant, or fuel? Lead is common in various greases sometimes used as assembly aids.
Operation Records
Consider operational changes including major changes in haul cycle, profile, shift, operator, and so on. Is the operator noting anything unusual? Has the fuel burn rate changed or have there been any changes to the rate of oil consumption or frequency/volume of oil additions?
Consider Collecting Another Sample
Has resampling been considered after changing oil and filters? Has this sample been collected early due to elevated lead in the previous sample?
Review and Validation Checklist | ||
---|---|---|
Points to Consider | Notes | |
Sample Collection, Age, Analysis | Correctly Collected? | |
Correctly Analyzed? | ||
Reported Hours Correct? | ||
Oil Change Interval (OCI) Correct? | ||
Compare to Trend from this engine | Steady? | |
Gradually Increasing? | ||
Rapidly Increasing? (1) | ||
Service Records | Major Component Replacements? | |
Modifications to lubrication, cooling, or fuel system? | ||
Changes in Oil, Coolant, of Fuel Suppliers? | ||
Changes in Oil, Coolant, or Fuel Formulations? | ||
Operation Records | Changes to haul cycle or profile? | |
Changes in shift or operator? | ||
Noteworthy operator comments? | ||
Rate changes in fuel burn or oil additions? | ||
Consider Resample | Is it safe to change oil and filters and resample? | |
Has the engine been resampled? |
(1) | Shutdown and resolve, if rapidly increasing trend is confirmed. |
Determine Root Cause
Lead is most often removed from bearings by mechanical wear or chemical wear.
Mechanical Wear
Mechanical wear of main and connecting rod bearings most commonly originates from one or more of the sources listed below:
- Dirt/Debris Introduction from Service or Operation
- Dirt Ingestion Through the Air System
- Abnormal Operating Conditions
- Out of Specification or Damaged Components
Dirt/Debris Introduction from Service or Operation
Illustration 3 | g03403290 |
Dirt and debris can be introduced into the lubrication system anytime the engine is opened for service, repair, or oil additions. Review service and operation records to understand when the engine has been opened and to identify other possible sources for dirt or debris entry, including changes in personnel. Routine inspection of oil filter media and magnetic drain plugs for signs of debris is encouraged.
Note: The first few samples from new or newly rebuilt engines often contain elevated levels of silicon from seal materials. Elevated levels of silicon in new or newly rebuilt engines can be normal.
Dirt Ingestion Through the Air System
The chemical makeup of dirt is regionally unique, but generally dirt contains at least silicon and aluminum in a ratio close to Si:Al = 3:1. Dirt ingestion through the air system often generates elevated levels of iron and chromium first from liners, pistons, and rings via abrasive wear. Levels of lead often rise shortly thereafter as dirt enters the lubrication system. Regular testing to find and fix leaks in the air system is encouraged. Refer to the following for additional information for testing the air system:
- Testing and Adjusting, RENR8327, "Air Inlet System - Test and Inspect"
- Testing and Adjusting, SENR1450, "Air Inlet System - Test and Inspect"
- Service Magazine, SEPD0712, "Procedure to Test the Air Induction System"
Abnormal Operating Conditions
Illustration 4 | g06216462 |
Review records for evidence of overspeed, low oil level, low oil pressure, high coolant temperatures, and other abnormal operating conditions. If the product is equipped with an overspeed protection system, the operator should enable the system and leave the system engaged. Disabling or overriding overspeed protection systems can rapidly accelerate bearing wear and increase risk of component breakage. Pumping small quantities of oil and usage of oil with incorrect chemistry can aerate the oil and accelerate bearing wear. High coolant temperatures can also increase bearing wear and lead loss by reducing oil viscosity and accelerating oxidation. Lead levels can rise rapidly when operating in abnormal conditions. Extra diligence with a quality oil sampling and analysis program is encouraged.
Out of Specification or Damaged Components
Illustration 5 | g06216464 |
When lead levels are elevated alone, without contaminants such as water, glycol, or fuel, deterioration indicators (oxidation, nitration, sulfation), or other wear elements (Fe, Cr, Ni, Cu, Sn, Si, Al), crankshaft, and connecting rod history becomes a common area of focus. How many hours are on the crankshaft and connecting rods? Has the crankshaft been polished, or ground and polished? Did the salvage procedure follow best practices as published in Reuse and Salvage Guidelines, SEBF9217, "Specifications for Crankshafts in C7, C9, C-9, C10, C11, C12, C-12, C13, C-13, C15, C-15, C16, C-16, C18, C-18, C27, C30, and C32 Engines" and Reuse and Salvage Guidelines, SEBF8042, "Procedure for Grinding and Polishing the Crankshaft" Were correctly sized bearings installed if the crankshaft has been ground? Over-polishing of crankshaft journals often creates journal inconsistencies which can accelerate bearing wear and lead loss.
End of Life Components
Wear metal concentrations tend to rise as components reach the end of the components service life. If the engine components are approaching targeted replacement points, a gradual increase in wear metal concentration can be normal. Pay close attention to oil analysis results. Slight reductions in oil change interval, changes to the usage profile, or similar adjustments may be required to reach the targeted replacement points.
Chemical Wear
Problems with oil chemistry that contribute to loss of lead from bearings most commonly originate from one or more of the sources listed below:
- Extended Usage of Old Oil
- Fuel Contamination (Dilution)
- Coolant Contamination
- Oil Deterioration
Extended Usage of Old Oil
Illustration 6 | g03403243 |
There is no other maintenance procedure as important as regularly changing oil and filters.
Operation and Maintenance Manuals specify a maximum oil change interval (OCI) based on close monitoring of wear metals/oil condition and the following targeted milestones: service hours or calendar time, whichever comes first. Products that operate in severe conditions, or that have high fuel burn rates, may require more frequent oil changes. Refer to Special Instruction, SEBD0640, "Oil and Your Engine" for additional information.
Fuel Contamination (Dilution)
Illustration 7 | g03403306 |
Raw fuel can enter the lubrication system directly from leaking injector seals, transfer pump seals, and cracked fuel supply manifolds. Unburned fuel can also enter the lubrication system indirectly through leaking injector seals, injectors with poor spray patterns, by frequent cold starting and by misguided efforts to alter fuel or timing profiles. Unburned fuel in the combustion chamber can wash the oil film from the liners, pistons, and rings resulting in increasing levels of iron and chromium in engine oil samples.
As oil becomes contaminated (diluted) with fuel, the oil viscosity drops, which reduces the thickness of the oil film that separates the crank journals from the bearings. A viscosity decrease of 2 cSt or more is usually a sign of fuel dilution. Careful attention to viscosity trends is encouraged.
The levels of lead and other wear metals in oil samples may not increase significantly as a result of fuel dilution. However, if the viscosity becomes very low, catastrophic bearing damage can occur. This type of failure occurs quickly, and without warning.
Fuel in engine oil also dilutes important oil additives, reducing effectiveness. Refer to Troubleshooting, RENR5622, "Fuel Dilution of Engine Oil". The first few oil samples from new, or newly rebuilt engines often contain elevated concentrations of fuel. The elevated concentration of fuel in early oil samples can be normal.
Coolant Contamination
Illustration 8 | g06176272 |
Coolant can contaminate engine oil through leaking cylinder head gaskets, water ferrules, cracked cylinder heads, leaking water pump seals, cracked liners, leaking heat exchangers, leaking fuel injector seals, and other sources. Coolant in the engine oil can create a thick sludge capable of blocking oil passages and clogging oil filters. Such substances can also reduce oil lubricating properties and act as oxidation catalysts. The primary indicators of coolant contamination are elevated Na and or K in the oil. The Na and K are from the inhibitor additives in the coolant. Eventually coolant contamination will increase Pb ,Fe, Cu, and oil viscosity. Refer to Troubleshooting, RENR5622, "Oil Contains Coolant".
Oil Deterioration
Oil oxidizes naturally with time in service and the oxidation process accelerates with high temperatures. For these reasons, oxidation is often associated with long OCIs and/or high temperature operation. Oxidation results in oil thickening, formation of resins, piston deposits, loss of lubricating qualities, and accelerated wear. Highly oxidized oil can leave a honey-colored residue on crankshaft journals. Likelihood of oil filter plugging, filter bypass, and exposure of engine bearings to debris increases with increasing oxidation.
As acids of nitrogen and sulfur form in the engine oil, these acids break down the additives in the oil and accelerate the oxidation process. These acids also create a corrosive environment where lead from engine bearings can leach into the oil.
Oxidation Guidelines | |||
---|---|---|---|
Typical New Oil
Oxidation - UFM |
Monitor Compartment
Oxidation - UFM |
Action Required
Oxidation - UFM |
|
Cat DEO CI-4 | 13 | 23 | 33 |
Cat DEO-ULS CJ-4 | 16 | 26 | 36 |
Cat DEO-ULS CK-4 | 21 | 31 | 41 |
Commercial CI-4 or CJ-4 or CK-4 | X | X+10 | X+20 |
Common Chemical Wear Factors | |||
---|---|---|---|
Item | No Action Required | Monitor | Action Required |
Oxidation(1) | ≤ 23 UFM | 24-33 UFM | ≥ 34 UFM |
Sulfation | ≤ 27 UFM | 28-33 UFM | ≥ 34 UFM |
Viscosity | < ± 2 cSt | ± 2 cSt | ≥ ± 3 cSt |
(1) | Use these Oxidation guidelines if the new oil Oxidation value is unknown. |
Table 4 lists factors related to the proper chemistry of diesel engine oil and certain guidelines for monitoring those factors.
Illustration 9 | g06216468 |
Oil deterioration can also be caused by deposits and wear in the cylinder packs. Badly worn cylinder packs may exhibit: heavy deposits, broken piston rings, and polished cylinder liners. These cylinder pack issues will increase blowby. Oil samples from worn cylinder packs will show high oxidation, high soot, and increased viscosity.
Resolve and Proceed
Quick Reference Troubleshooting Guide | |||
---|---|---|---|
Oil Analysis Result | Probable Cause | Notes and References | Recommended Action |
High Pb and high Si, Al | Mechanical Wear : Dirt/Debris Introduced Through Service or Operations | Review service and maintenance practices. Inspection of magnetic plugs and oil filter elements are recommended.
Check the cleanliness of the fill oil. Check the cleanliness of the repair facility and repair parts. |
Alter service or maintenance practices to eliminate dirt/debris introduction. Resample oil to confirm wear metal concentrations return to acceptable levels. Consider bearing replacement if the dirt/debris introduction was severe (high concentration, long duration, and so on) and/or if the engine is not close to PCR target. |
High Pb and high Si, Al, Fe, Cr | Mechanical Wear : Dirt Ingestion Through the Air System | Refer to Service Magazine, SEPD0712, "Procedure to Test Air Induction System". | Repair source of dirt ingestion and resample oil to confirm wear metal concentrations return to acceptable levels. Consider bearing replacement if the dirt ingestion was severe (high concentration, long duration, and so on) and/or if the engine is not close to PCR target. |
High Pb and high Cu | Mechanical Wear : Bronze Thrust Bearings or Bronze Bushings | Bushings, bearings, and thrust washers in rear gear train and air compressors are common sources. Larger particles can often be observed in filter media. | Check filter media and magnetic plugs for presence of larger particles. Replace worn components and resample oil to confirm wear metal concentrations have returned to acceptable levels. |
High Pb Only | Mechanical wear or an incorrect oil sample. | Elevated Pb may occur if the surface finish on the crankshaft is too rough or uneven. This usually occurs after a crankshaft replacement.
Abnormal internal component wear could produce large particles. If these particles are not filtered out, the debris can damage bearing surfaces. Sometimes the oil test results are in error. |
Make sure that replacement crankshafts meet all the requirements for surface finish and surface profile.
If debris wear is suspected, inspect the engine oil filters for visible debris. Resample the engine oil at the earliest possible time. |
Very low viscosity and wear metals increasing | Engine near failure from fuel dilution. | Watch for viscosity decrease of > 2cSt versus trend. Refer to Troubleshooting, RENR5622, "Fuel Dilution of Engine Oil". | Repair source of fuel dilution. Consider bearing replacement if the fuel dilution was severe (high concentration, long duration, and so on) and/or if the engine is not close to PCR target. |
High Pb and high Na or K | Chemical Wear : Coolant Leak | Watch for concentrations of Na or K ≥ 25 ppm. Refer to Troubleshooting, RENR5622, "Oil Contains Coolant". | Repair the coolant leak. Resample oil to confirm that wear metal concentrations return to acceptable levels. Consider bearing replacement if the coolant leak was severe (high concentration, long duration, and so on) and/or if the engine is not close to PCR target. |
High Pb and high Na or K and one or more of the following: high viscosity, positive water, positive glycol | Chemical Wear : Coolant Leak | Watch for concentrations of Na or K ≥ 25 ppm. Watch for viscosity increase of greater than 2 cSt versus trend. Refer to Troubleshooting, RENR5622, "Oil Contains Coolant". | Repair the coolant leak. Resample oil to confirm that wear metal concentrations return to acceptable levels. Consider bearing replacement if the coolant leak was severe (high concentration, long duration, and so on) and/or if the engine is not close to PCR target. |
High Pb, high oxidation, and high viscosity | Chemical Wear : Degraded Oil | Refer to product Operation and Maintenance Manual or Special Instruction, SEBD0640, "Oil and Your Engine". | Reduce oil change interval and resample oil to confirm that wear metal concentrations return to acceptable levels. |
High Pb and high soot, high iron, and high viscosity | Chemical Wear : Degraded Oil | Refer to product Operation and Maintenance Manual or Special Instruction, SEBD0640, "Oil and Your Engine". | Reduce oil change interval and resample oil to confirm that wear metal concentrations return to acceptable levels. |