147 research outputs found
Grain and phase stress criteria for behaviour and cleavage in duplex and bainitic steels
Stress analyses by X-ray diffraction are performed on a cast duplex (32% ferrite) stainless steel elbow and a bainitic (95% ferrite) pressure vessel steel. During an in situ tensile test, micrographic observations are made (visible glides and microcracks) and related to the stress state determined in the individual ferritic grains (aged duplex) and the ferritic phase (bainite loaded at low temperatures). Several material parameters have been identified at different scales, as for example, the critical resolved shear stress of 245 MPa for the aged ferritic grain (duplex) or 275 MPa for bainite (–60 ◦C), a crystallographic cleavage propagation criterion of 465 MPa (stress normal to {100} planes), and a fracture stress of approximately 700 MPa in the ferritic phase. Even though the two steels are different in many respects, the macroscopic fracture strains and stresses are well predicted by the polycrystalline model developed for bainite, whatever the temperatures tested (considering 7% of the grains reaching the local criterion)
A review of the changes of internal state related to high temperature creep of polycrystalline metals and alloys
When polycrystalline metals and their alloys are used at high temperature, creep deformation leads to changes in their internal state. The change in internal state manifests itself in many ways, but the two ways that concern us in this review are (i) the creation of internal stress arising from the strain incompatibility between grains and/or the formation of cell/sub-grain structures and (ii) a change in the material resistance. This review aims to provide a clear separation of these two concepts by exploring the origin of each term and how it is associated with the creep deformation mechanism. Experimental techniques used to measure the internal stress and internal resistance over different length-scales are critically reviewed. It is demonstrated that the interpretation of the measured values requires knowledge of the dominant creep deformation mechanism. Finally, the concluding comments provide a summary of the key messages delivered in this review and highlight the challenges that remain to be addressed
Determination of inhomogeneous residual stress states in surface layers of machined engineering ceramics by synchrotron X-rays
Ceramic components for engineering applications must in most cases be ground after sintering in order to achieve a sufficient precision of the final dimensions as well as a sufficient surface quality. Since the surface layers influenced by grinding are very shallow, the determination of near-surface grinding residual stresses and their gradients within the penetration depth of the X-rays is difficult. In this paper, a procedure is applied which allows the investigation of residual stress states in ground ceramic surfaces by X-ray diffraction using synchrotron radiation and parallel beam optics. Three different ceramics were examined. In all cases, compressive residual stresses were found in the surface layers of the materials investigated. The magnitudes and gradients of the grinding residual stresses markedly depend on the grinding parameters and on the resulting mechanism of materials removal
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