A rigid finite element method for upper bound limit analysis of soil slopes subjected to pore water pressure;

Comparing with the results gotten from ANSYS, it is confirmed that the rigid finite element method including its modify version are simple but efficient method for the present purpose.

In this paper,the rigid finite element method is employed,in both the general and modified forms.

The formulations of the rigid finite element and traditional constant stress element.

Based on the stress-strain data gaining from experiment of isothermal compression 58SiMn steel, using rigid-plastic finite element method, the isothermal-extrusion deformation of 58SiMn double-cup part was simulated, the deformation force and metal flowing law in the course of isothermal-extrusion deformation was discussed.

According to the stress-strain data gaining from isothermal compression experiment,and using rigid-plastic finite element method,the magnesium alloy isothermal-extrusion forming was simulated.

The constrained superplastic bulging process is investigated by a large rigid-plastic finite element method.

The validity of the new model has been examined by the bar rolling experiment and the rigid-plastic FEM simulation.

The model of cutting process is established based on the rigid-plastic FEM,and the transient stress distribution of cutting tool in cutting process is obtained through the simulation.

Lagrange method for the static large deformation analysis is used to establish a rigid-plastic FEM(RPFEM) analysis model based on the orthogonal cutting process of 2D plain strain hypothesis.