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An Extended Smooth Meshless Galerkin Method

A Galerkin method and gridless technology, which is applied in the field of crack growth analysis, can solve problems such as low calculation efficiency, affecting calculation efficiency of gridless Galerkin, calculation oscillation, etc.

Active Publication Date: 2021-04-23
SICHUAN UNIV
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Problems solved by technology

However, this method has obvious disadvantages: 1) the calculation is oscillating, the calculation accuracy is unstable, and the number of nodes in the node calculation domain is too large, which will reduce its calculation accuracy; 2) the accuracy is low
Collocation method is a strong form of balanced differential equation, its accuracy is lower than conventional Galerkin method; 3) low computational efficiency
The conventional meshless Galerkin method requires Gaussian integration. In order to ensure the calculation accuracy, a large number of integration points are usually arranged in the background integration cell, and the partial derivatives of the shape functions of these integration points are calculated, which greatly affects the gridless The calculation efficiency of Galerkin has become the biggest difficulty in engineering practice

Method used

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  • An Extended Smooth Meshless Galerkin Method
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Embodiment Construction

[0068] The present invention will be further described in detail below in conjunction with specific embodiments, which are explanations of the present invention rather than limitations.

[0069] An extended smooth meshless Galerkin method that includes the following operations:

[0070] Step 1: Discretize the continuum body into a series of nodes, such as figure 1 shown;

[0071] Step 2: After applying the stress and displacement boundary conditions, use the smooth integration scheme combined with the traditional meshless Galerkin method (smooth meshless Galerkin method) to calculate the stress and strain of each node to determine the initial position of the crack; The criterion used is the maximum principal strain method: if the equivalent principal strain of the node is >10- 3 , the node is the crack node, and the connection of each crack node forms the initial crack.

[0072] The analysis process of the smooth meshless Galerkin method is as follows:

[0073] ① The field...

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Abstract

The invention discloses an extended smooth gridless Galerkin method, which combines extended finite element, gridless Galerkin and smooth integration techniques, wherein the traditional gridless Galerkin method is transformed, Using triangles with stronger topology adaptability as background integral cells makes the discretization process of geometry more concise and easy; abandoning the traditional Gaussian integral method and introducing smooth integral technology avoids the tedious process of derivation of shape functions, making The calculation accuracy has been improved to a certain extent; the improved meshless method is used in the simulation of the development of concrete crack growth, and the simulation effect is closer to the real situation than the traditional extended finite element method.

Description

technical field [0001] The invention belongs to the technical field of crack extension analysis and relates to an extended smooth gridless Galerkin method. Background technique [0002] Crack growth refers to the dynamic process of crack nucleation and growth in materials under the action of external factors. For the problem of crack propagation in continuum media, the most common method at present is the extended finite element method (XFEM) meshless method, etc. The problems of these methods are: [0003] 1. XFEM is based on the traditional finite element, developed from the unknown variables of cracks and crack propagation. For the triangular element with the strongest topology adaptability, its simulation accuracy is low, and it is necessary to improve its calculation by subdividing the grid. Accuracy, low computational efficiency. [0004] 2. The most commonly used method for simulating crack growth without mesh is the collocation method, that is, the geometry and cra...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): G06F30/23G06F119/14
CPCG06F30/23
Inventor 黄哲聪周家文
Owner SICHUAN UNIV
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