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Significant headway has recently been achieved in advanced high-temperature component design. Progress has been made in selecting a highly effective thermal insulating design composed of a titanium alloy piston with 1.0 mm thermal barrier coating which provides the same level of insulating effectiveness as a ductile iron piston with 2.5 mm coating. The low thermal conductivity of Titanium Alloy 6242 inherently provides a significant level of thermal resistance which effectively reduces the required coating thickness, reduces thermal stresses, and nearly eliminates coating thermal expansion mismatch. Other benefits of the titanium alloy piston include low weight and increased high temperature strength. Thermal rig testing has been completed on several plasma-sprayed zirconia coatings and a critical durability threshold thickness of 1.25 mm has been identified. In addition, zirconia coatings and chrome-oxide-densified Eirconia coatings have been screened in a small bore diesel engine.

The development of a practical, reliable, and durable adiabatic engine which will meet all advanced military requirements is still hindered because of available insulating materials and design limitations. The high temperatures and thermal gradients which are associated with a highly insulated low heat rejection engine create monumental challenges to engine designers. Over the past 12 years a wealth of information and experience has been generated. Numerous approaches to insulate the combustion chamber have been explored but none are known to simultaneously meet heat rejection, durability, and performance requirements. This paper will present the first year's results and the future plans of an adiabatic engine component technology development program for high output military engines, sponsored by the U.S. Army Tank-Automotive Command Center.