Fe (Si) solid solution being selected as a model material, the single crystal growth of solid solution has been achieved by melting zone of different compositions (MZDC) technique in this study.
Selecting Ni(5)Zr compound as a model object, the single crystal growth of peritectic reaction induced phases has been achieved by 'melting zone of different composition' technique in this study.
The total stress response of material is decomposed into a sum of an equilibrium stress response and a non-equilibrium overstress response. Correspondingly, the rate-independent intrinsic time and the rate-dependent i...The total stress response of material is decomposed into a sum of an equilibrium stress response and a non-equilibrium overstress response. Correspondingly, the rate-independent intrinsic time and the rate-dependent intrinsic time are defined respectively. Additional hardening functions for describing the isotropic and anisotropic nonproportional effects are assumed to be related to the accumulation of plastic strain component along the normal of equilibrium stress trajectory, in which the effects of geometry of the loading path are included. An endochronic constitutive model for rate-dependent, nonproportional cyclic plasticity is formulated and applied to simulate the stress responses of stainless steel XCrNil8. 9 for some typical loading programs at different loading rates. A comparison between predicted results and experimental ones by Haupt and Lion shows that the former are in agreement with the latter.展开更多
文摘Fe (Si) solid solution being selected as a model material, the single crystal growth of solid solution has been achieved by melting zone of different compositions (MZDC) technique in this study.
文摘Selecting Ni(5)Zr compound as a model object, the single crystal growth of peritectic reaction induced phases has been achieved by 'melting zone of different composition' technique in this study.
基金the National Natural Science Foundationthe Science Foundation of the Overseas Chinese Affairs Office of China.
文摘The total stress response of material is decomposed into a sum of an equilibrium stress response and a non-equilibrium overstress response. Correspondingly, the rate-independent intrinsic time and the rate-dependent intrinsic time are defined respectively. Additional hardening functions for describing the isotropic and anisotropic nonproportional effects are assumed to be related to the accumulation of plastic strain component along the normal of equilibrium stress trajectory, in which the effects of geometry of the loading path are included. An endochronic constitutive model for rate-dependent, nonproportional cyclic plasticity is formulated and applied to simulate the stress responses of stainless steel XCrNil8. 9 for some typical loading programs at different loading rates. A comparison between predicted results and experimental ones by Haupt and Lion shows that the former are in agreement with the latter.