In order to provide a theoretic basis for the research of Ti(C_xN_y) thinfilms, the thermodynamic database of Ti-C-N ternary system is established and the phase diagramsections are calculated. In addition to the assessed thermodynamic properties of Ti-C-N system, theinfluence of the residual strain energy of Ti(C_xN_y) thin films on the phase equilibria isanalyzed. The classical formula for calculating the elastic strain energy is expressed into aRedlich-Kister form in order to perform the thermodynamic and equilibrium calculations using theThermo-Calc software. Isothermal sections at 900 and 1100 K are calculated with this database andcompared with those calculated without considering the residual stress. As a result, with theaddition of strain energy delta-fcc Ti(C_xN_y) phase area shrinks. It is therefore concluded thatwith the influence of the residual stress in Ti(C_xN_y) thin solid film, the precipitation of puredelta film requires more precise control of composition.
A multi-inclusion cell model is used to investigate the effect of deformation temperature and whisker rotation on the hot compressive behavior of metal matrix composites with misaligned whiskers. Numerical results show that deformation temperature influences the work-hardening behavior of the matrix and the rotation behavior of the whiskers. With increasing temperature, the work hardening rate of the matrix decreases, but the whisker rotation angle increases. Both whisker rotation and the increase of deformation temperature can induce reductions in the load supported by whisker and the load transferred from matrix to whisker. Additionally, it is found that during large strain deformation at higher temperatures, the enhancing of deformation temperature can reduce the effect of whisker rotation. Meanwhile, the stress-strain behavior of the composite is rather sensitive to deformation temperature. At a relatively lower temperature (150℃), the composite exhibits work hardening due to the matrix work hardening, but at relatively higher temperatures (300℃ and above), the composite shows strain softening due to whisker rotation. It is also found that during hot compression at higher temperatures, the softening rate of the composite decreases with increasing temperature. The predicted stress-strain behavior of the composite is approximately in agreement with the experimental results.
LI AibinMENG QingyuanGENG LinDENG ChunfengYAN Yiwu
Finite element analysis was used to investigate the effects of whisker misalignment on the hot compressive deformation behavior of whisker-reinforced composites. The simulation provided the evolution of the stress field of the composites and the whisker rotation process. It is found that with increasing the angle of whisker misalignment the whisker rotation angle decreases. Meanwhile, the mechanical behaviors of the composites such as work hardening or strain softening are affected by the whisker orientation and rotation during the hot compressive deformation. The predicted results are in agreement with the experimental results.
