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In recent years, efforts at reducing manufacturing costs for moderate to high strength steel components has provided a major driving force for the development, evaluation and application of high strength low alloy (HSLA) or microalloyed (MA) steels with ferrite-pearlite microstructure. In order to improve or control the final properties of a part forged from MA steels, the effects of thermo-mechanical processing on final properties need to be investigated. Isothermal upset tests were conducted, on two MA steels, TMS-80R (Vanadium MA steel) and TMS-80R+Ti (Titanium modified Vanadium MA steel). The flow behavior as well as preliminary relationships between processing conditions and microstructure were established for these two steels. Further, forging trials were conducted at a forging facility to obtain relationships between processing conditions and mechanical properties.

Medium carbon steels have been traditionally used for high strength forging applications. These steels contain several alloying elements like chromium, nickel and molybdenum which enable them to attain excellent hardenability and toughness upon heat treatment (quenching and tempering). Microalloyed (MA) medium carbon forging steels are gaining acceptance as a replacement for the traditional quenched and tempered grades as they do not require post forging heat treatment and hence represent substantial savings in manufacturing costs. Since the chief advantage of MA steels lies in the savings of heat treatment costs, the post-forging cooling rate is one of the primary parameters for controlling microstructure and toughness of the forged part. This paper investigates the effect of different cooling rates on the microstructure and mechanical properties of MA steels. Experiments were conducted by cooling test billets in different media.