Abstract

The need for maintaining a lower specific engine oil temperature is essential in enhancing the longevity of the oil and of the engine and its components. By decreasing the engine oil temperature the oil is able to perform its job more efficiently. It is proposed to use the carbon foam, with its exceptional thermal management capabilities, to aid in reducing and stabilizing the engine oil temperature during steady state operation. Also, it is possible to use the carbon foam to heat the engine oil during startup to reduce emissions and possibly engine wear. The mesophase pitch derived carbon foam, developed at Oak Ridge National Laboratory, is a material that offers excellent thermal management capability. The foam has an open cell structure (0.98 fraction open porosity) with graphitic ligaments aligned parallel to the cell walls. The alignment of the graphitic ligaments in a three dimensional array gives the foam homogeneous thermal properties, unlike graphite fibers. The bulk thermal conductivity of the foam has been measured to be 175 W/m{center_dot}K, placing it on the level of 6061 aluminum, which has a bulk thermal conductivity of 180 W/m{center_dot}K. Copper has a bulk thermal conductivity over two times higher, at 400 W/m{center_dot}K. The proposed research will entail using the carbon foam, with its excellent thermal management capabilities, as a cooling and heating medium for engine oil, or in other words an oil temperature regulator. The foam will aid in maintaining a specific oil temperature during steady state operation and in heating of the engine oil at startup. Being able to maintain a consistent oil temperature will ensure better operation of engine oil, by extending the life of the oil and engine. All Parties will conduct research efforts in order to determine the best utilization of the carbon foam in managing engine oil temperatures.

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