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Soot is a typical byproduct of the diesel fuel combustion process, and a portion of the soot inevitably enters an engine's crankcase. A key functionality of a diesel engine lubricant is to disperse and suspend soot so that larger-particle agglomerations are prevented. The role of soot agglomeration in abrasive engine wear and lubricant viscosity increase is the subject of a continuing investigation; however, what is generally known is that once an engine lubricant loses its ability to control soot and a rapid viscosity increase begins, the lubricant has reached the end of its useful life and should be changed to maximize engine performance and life. This issue of soot related viscosity increase is of such importance that the Mack T-11 engine test was developed as a laboratory tool to evaluate lubricants. The newly proposed Mack EO-N Premium Plus - 03 specification includes a T-11 performance requirement.

Two prominent trends are facing diesel engine builders and their customers, environmental regulations and cost containment. Increasingly stringent exhaust emissions regulations have necessitated major changes in diesel engine design. Combustion temperatures and fuel injection pressures continue to rise. This and other factors, such as lower oil consumption for exhaust particulate reduction, place greater demands on crankcase lubricating oils. Another prominent environmentally related cost factor facing fleet operators is that of waste oil management. The inventory and disposal of used lubricants must now be handled in accordance with regulated guidelines and their associated costs. To compensate, new lubricant categories have been designed in both North America and Europe, such that 1994 and later emission controlled engines will perform as reliably as their earlier counterparts.

For a diesel lubricant to meet the new Mack EO-K/2 specification, it must be effective in preventing excessive viscosity increase during the 150-hour Mack T-7 test. The severity of this test is shown to be highly dependent upon fuel chemistry and injection timing. A comparison of various lubricant formulations in the Mack T-7 engine run with a given fuel suggests that nitrogen-containing succinimide dispersants, dispersant viscosity improvers, and supplemental ash in the form of overbased sulfonate detergents are effective in controlling viscosity increase. Crankcase oil thickening follows a modified form of Brinkman’s equation and can be predicted from measured values of soot particle size and concentration. Basic lubricant additives are shown to prevent particle size growth by adsorption on to the acidic soot surface, thereby interrupting soot aggregation and retarding oil thickening.