The potential of PM Mn steels has been established in laboratory experiments. This paper deals with sintering of Fe-(2-4)Mn-(0.3/0.7)C, also with 0.85%Mo addition, in an industrial pusher furnace at 1180degreesC in an atmosphere of 25% hydrogen plus 75% nitrogen, obtained from a cryogenic liquid, giving an inlet dewpoint of -55degreesC. Tensile, bend (including fatigue) and miniature Charpy specimens were sintered in flowing gases and in semiclosed containers with a getter of ferromanganese, carbon and alumina. The quenched and tempered state was investigated, as was sinter hardening (cooling rate of 55 K min(-1)), simulated for comparison with slow cooling at 10 K min(-1). As there was no formation of oxide networks at the combination of sintering temperature and dewpoint, in accordance with the Ellingham-Richardson diagram for Mn oxidation/reduction, the use of semiclosed containers was superfluous. The quenched and tempered specimens were brittle. Sinter hardening lead to an improvement in mechanical properties. The reproducibility of tensile and TRS data was high for the sintered materials, characterised by Weibull moduli m of 12-41. All the alloy microstructures were complex and heterogeneous, consisting of, depending on the local manganese and carbon contents, the diffusive and non-diffusive transformation products (pearlite, bainite, martensite) and additionally ferrite and retained austenite. The highest mechanical properties in the entire range of compositions investigated in the furnace cooled state: yield, tensile and bend strengths of 499, 637 and 1280 MPa, respectively, with impact energy of 18 J, and tensile and bend strains of 1.17 and 1.57%, were achieved for the Fe-2Mn-0.85Mo-0.5C alloy, marginally superior to Fe-2Mn-0.7C. For the sinter hardened Fe-4Mn-0.3C alloy yield, tensile and bend strengths were 570, 664 and 1263 MPa, respectively, at an acceptable impact energy of 14 J, with tensile and bend strains of 0.52% and 1.8%. Many of the results compare favourably with the requirements of MPIF standard 35. Mn is a more effective strengthening agent than either Ni or Cu, or their combination, though generally at reduced plasticity.
