https://sam.ensam.eu:443 The DSpace digital repository system captures, stores, indexes, preserves, and distributes digital research material. Thu, 12 Mar 2026 14:17:35 GMT 2026-03-12T14:17:35Z http://hdl.handle.net/10985/26512 Deformation behaviour of 304 stainless steel - experimental and modelling PETIT, Bertrand; GEY, Nathalie; ABED-MERAIM, Farid; HUMBERT, Michel; BEN ZINEB, Tarak; BOLLE, Bernard; CHERKAOUI, Mohamed The austenitic stainless steels are characterised by remarkable mechanical properties, combining high ductility and high strength. Their plastic deformation involves a wide variety of strain induced deformation mechanisms, strongly related to the alloy stacking fault energy. With increasing SFE, martensitic transformation sequences (gamma to alpha', gamma to epsilon to alpha'), deformation twinning, glide of dissociated or perfect dislocations can occur. A quantitative modelling of such a deformation behaviour, with real predictive capabilities, has been developed recently. It is formulated in terms of finite strains and takes the various inelastic strains encountered in the material into account. In particular, two inelastic deformations are considered, either epsilon martensite transformation strain or twinning strain, depending on the testing temperature, and the alpha' transformation strain. Thermomechanical couplings are realised between these two inelastic deformation modes. The model which uses a self-consistent method for the scale transition, allows us to calculate the global behaviour of the polycrystal. In this contribution, this new model is applied to foresee the behaviour of a 304 stainless steel, tensile tested in a temperature range of -60 degrees Celcius to room temperature. Besides, large experimental investigations were performed on various 304 specimens. In particular, X-ray diffraction was used to quantify the volume fraction of the alpha' and epsilon martensite and to determine the texture evolution of the parent and the product phases. The local microtextures were analysed with the EBSD technique in a SEM FEG. The predictions obtained with the micromechanical model are compared to the different experimental results, notably the mechanical behaviour and associated deformation mechanisms, the transformation kinetic as well as the texture evolution. Thu, 01 Sep 2005 00:00:00 GMT http://hdl.handle.net/10985/26512 2005-09-01T00:00:00Z PETIT, Bertrand GEY, Nathalie ABED-MERAIM, Farid HUMBERT, Michel BEN ZINEB, Tarak BOLLE, Bernard CHERKAOUI, Mohamed The austenitic stainless steels are characterised by remarkable mechanical properties, combining high ductility and high strength. Their plastic deformation involves a wide variety of strain induced deformation mechanisms, strongly related to the alloy stacking fault energy. With increasing SFE, martensitic transformation sequences (gamma to alpha', gamma to epsilon to alpha'), deformation twinning, glide of dissociated or perfect dislocations can occur. A quantitative modelling of such a deformation behaviour, with real predictive capabilities, has been developed recently. It is formulated in terms of finite strains and takes the various inelastic strains encountered in the material into account. In particular, two inelastic deformations are considered, either epsilon martensite transformation strain or twinning strain, depending on the testing temperature, and the alpha' transformation strain. Thermomechanical couplings are realised between these two inelastic deformation modes. The model which uses a self-consistent method for the scale transition, allows us to calculate the global behaviour of the polycrystal. In this contribution, this new model is applied to foresee the behaviour of a 304 stainless steel, tensile tested in a temperature range of -60 degrees Celcius to room temperature. Besides, large experimental investigations were performed on various 304 specimens. In particular, X-ray diffraction was used to quantify the volume fraction of the alpha' and epsilon martensite and to determine the texture evolution of the parent and the product phases. The local microtextures were analysed with the EBSD technique in a SEM FEG. The predictions obtained with the micromechanical model are compared to the different experimental results, notably the mechanical behaviour and associated deformation mechanisms, the transformation kinetic as well as the texture evolution.