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The as-sintered and the sintered and tempered transverse rupture and tensile properties of seven recently developed high performance PM compositions are reviewed. Two are improved versions of the well known diffusion alloyed grades according to MPIF Standard 35. Two others are likewise improved versions of more highly alloyed analogs of the latter that have only recently been introduced. The remaining three are all new compositions that take advantage of the powerful alloying effects of silicon. The silicon is added by a proprietary method that greatly reduces its susceptibility to oxidation during sintering, an effect that has heretofore limited its use.

Due to recent developments in ferrous powder metallurgy, production of high performance parts has become more cost competitive. Advances in high performance materials have provided high strength in as-sintered components. With recent technological developments, high density parts (>7.3 g/cm3) can be fabricated with a single compaction process that also provides green strengths significantly higher than obtained with traditional processes. Properties obtained with these materials are described and the use of Mn and Cr as alloying elements are reviewed. Machining high performance P/M materials is difficult. A method of green machining P/M components by taking advantage of the material's high green strength is introduced.

The advent of stainless steel automotive exhaust systems presents a significant opportunity for powder metallurgy (P/M) parts and the inherent economic advantages of this near net shape metalworking technology. A study was performed to determine the viability of ferritic P/M stainless steel parts for exhaust applications such as coupling flanges and hot exhaust gas oxygen sensor (HEGOS) bosses. In order to help achieve the automotive industry's stated goal of extending the functional life of exhaust components while remaining competitive, the authors developed a program to develop a database of the mechanical properties and performance characteristics of several grades of P/M stainless steel. Among the data generated and analyzed for these ferritic alloy systems are room temperature, tensile stress-strain curves, fatigue and endurance properties, hardness levels, and corrosion resistance.

Water-atomized nickel-molybdenum alloy (0.5 Ni-0.5 Mo) powder was blended with graphite for 0.4% carbon, then pressed into preforms (1.5 X 2 X 5 in). The preforms were hot formed to full density via a variety of processing conditions (various degrees of flow, sintering temperature, and sintering atmosphere). Impact specimens were excised and tested over a range of temperatures to determine the ductile-to-brittle transition temperature. All impact specimens had ductile failure at room temperature. In general, increased deformation increased the room-temperature and low-temperature impact strengths by eliminating particle boundaries and elongating the inclusions. High temperature sintering reduced the oxygen content and improved the impact strength by reducing the number of crack-initiating inclusions. Jominy hardenability test results were unaffected by various sintering conditions because the amount of easily oxidizable alloying elements was kept to a minimum.