Study on the Manifold Cover Lagrangian Integral Point Method Based on Barycentric Interpolation

Abstract EN

To achieve numerical simulation of large deformation evolution processes in underground engineering, the barycentric interpolation test function is established in this paper based on the manifold cover idea.

A large-deformation numerical simulation method is proposed by the double discrete method with the fixed Euler background mesh and moving material points, with discontinuous damage processes implemented by continuous simulation.

The material particles are also the integration points.

This method is called the manifold cover Lagrangian integral point method based on barycentric interpolation.

The method uses the Euler mesh as the background integral mesh and describes the deformation behavior of macroscopic objects through the motion of particles between meshes.

Therefore, this method can avoid the problem of computation termination caused by the distortion of the mesh in the calculation process.

In addition, this method can keep material particles moving without limits in the set region, which makes it suitable for simulating large deformation and collapse problems in geotechnical engineering.

Taking a typical slope as an example, the results of a slope slip surface obtained using the manifold cover Lagrangian integral point method based on barycentric interpolation proposed in this paper were basically consistent with the theoretical analytical method.

Hence, the correctness of the method was verified.

The method was then applied for simulating the collapse process of the side slope, thereby confirming the feasibility of the method for computing large deformations.