基于几何造型的有限元网格的自适应生成

介绍一个基于几何造型系统的有限元分析的前处理系统。该系统可对几何造型的二维任意形体进行快速可靠的Ｄｅｌａｕｎａｙ三角剖分，提出网格自动生成的网格密度的控制和基于误差估计的自适应有限元网格生成算法，并给出了应用实例。     

基于几何造型的有限元前处理技术

本文在综述了有限元网格生成技术的基础上,着重介绍一个基于几何造型系统的有限元分析的前处理系统。这个系统作为几何造型系统与有限元分析程序之间的接口,主要功能是对几何造型系统的二维任意形体进行有限元网格的划分,并能够进行局部加密,自动节点编号,交互划分定义单元组,定义单元节点信息、载荷信息、边界条件等,最终生成有限元分析程序所需的输入文件。同时,还能够处理平移扫描体和旋转扫描体等二维半形体。本文主要算法可以推广到三维形体的网格生成,实现对更广泛的三维结构的有限元网格生成。     

基于几何造型的有限元网络自适应生成

介绍一个基于几何造型系统的有限元分析的前处理系统。该系统可对几何造型的二维任意形体进行快速可靠的Ｄｅｌａｕｎａｙ三角剖分，提出网络自动生成的网络密度的控制和基于误差估计的自适应有限元网格生成算法，并给出了应用实例。     

三维实体有限元可视化前处理系统开发

可视化前处理系统是有限元软件的重要组成部分。文章介绍了利用Visual C++和OpenGL图形库开发简易实用的三维实体有限元前处理系统的方法,实现了快速建立三维几何模型并划分网格的功能。另外,该系统具备视图操作功能,用户可方便地查看几何模型和有限元模型。     

有限元建模系统AutoFEM

AutoFEM是基于流行的CAD程序包AutoCAD（R13,R14）的集成化有限元建模程序, 可在Windows95/NT操作系统平台上运行。本文着重论述了三维实体几何信息的提取方法,三维实体网格全自动生成方法及图形用户界面（GUI）的快速开发方法。一、引 言有限元分析方法已广泛应用于固体力学、流体力学、生物力学、传热学、电磁学及其相关的工程领域。但是,在产品与工程结构的有限元分析中,有限元前置处理,即建立有限元分析模型的工作量非常大,这成为有限元法实际应用的主要困难之一。有限元前置处理主要包括三个部分：建立几何模型、网格剖…     

八节点六面体有限元网格自动消隐技术

文章基于图形消隐技术,利用C语言,开发了一套有限元网格与AutoCAD之间进行图形交换的软件系统,并利用该系统将三维有限元网格数据以3D表面的数据格式生成DXF文件.通过AutoCAD直接打开该DXF文件,然后利用AutoCAD提供的消隐功能对三维有限元网格进行自动消隐,从而提高了大量数据的显示能力,并且省去了消隐的复杂编程工作.     

JIFEX--有限元分析与优化设计软件系统

JIFEX是大连理工大学工程力学系/工程力学研究所/工业装备结构分析国家重点实验室联合研制开发的具有自主版权的新一代有限元软件.它在MS Windows9X/NT平台上将有限元分析和优化设计与前后置处理集成一体,具有全新的图形交互式用户界面和实时的计算可视化,利用AutoCAD建立有限元模型并实现了全自动的网格和数据生成,是我国有限元软件研制开发和应用的新成果.     

自动分网中的几何模型处理方法

自动分网是有限元分析中最常用的网格划分方法。几何模型是自动分网的基础,其尺寸和形状直接影响网格形式。为了划分出预期的网格,网格划分前必须对几何模型进行适当处理。本文介绍几何模型的各种处理方法。     

以STL为接口的CAD/CAE集成应用

提出了以STL为接口实现CAD/CAE系统的多对多集成方案,通过对原始STL的分析,检查,纠正以及整合处理,实现了基于STL的三维实体网格自动剖分,生成了可被CAE系统接受的有限元网格数据,实例表明,文中方法简单实用,效果良好。     

机械结构多机分布式优化的集成策略研究

为了解决复杂机械结构的优化集成问题,提出了跨广义优化平台与有限元分析平台的多计算机分布式优化的集成策略及系统总体框架,详细探讨了实现集成的一些关键技术,包括在有限元前处理中的边界载荷条件的自动施加、网格自动修改、数据通讯问题、远程控制技术等,提出了相应的解决方案,并已有效地用于求解液压挖掘机的广义优化模型。     

有限元建模与AutoCAD平台的集成方法

本文讨论了有限元建模与ＡｕｔｏＣＡＤ平台集成中的特殊技术问题与实施方案，重点述了ＡｕｔｏＣＡＤ的ＡＤＳ开发环境，底层数据结构，扩展实体数据接口方法以及有限元分析模的表示方法。     

三维渗流有限元软件GWSS开发与应用

针对复杂地质条件的三维地质建模、复杂建筑物的几何建模和复杂防渗排水系统作用下渗流场精细模拟等三维渗流场有限元分析的难点问题,采用IDL开发面向水工结构和岩土工程的渗流有限元分析软件GWSS（Ground Water Simulation System）.该软件包括系统控制模块、数据管理模块、前处理模块、计算模块、后处理模块和制图输出模块等六大模块.前处理模块具有基于钻孔和钻孔剖面的三维地质建模、几何建模与有限元网格生成等功能;计算模块主要用于各种闸坝、堤防、隧道和地下洞室等渗流问题的计算分析等;后处理模块可显示各渗流要素的三维云图和任意截面的二维云图等.GWSS已经在国内四十多个工程的渗流计算中得到应用和检验.     

A truly meshless pre- and post-processor for meshless analysis methods

In recent years, meshless methods have been developed to eliminate the known drawbacks in finite element methods. Generating the input file for a meshless method and interpreting the output obtained can be difficult without graphical pre-processing and post-processing support. Unfortunately, most existing pre- and post-processing techniques are based on using an underlying finite element mesh or finite difference grid. Since meshless methods have neither, new approaches are required for providing this support for meshless methods. In this paper, a pre-processor and a post-processor are presented for the meshless method using node-based and pixel-based approaches as opposed to an element-based approach. Pre-processing supports for automated generation of nodes, support domains, and sub-domains along with local refining are also included. An extensive example is presented to demonstrate the effectiveness of the given pre-processor and post-processor.     

A three-dimensional shape optimization system—shop3D

A modular approach for shape optimization of three-dimensional solid structures is described. A major consideration in the development of this capability is the desire to use a commercially available finite element program, such as NASTRAN, for analysis. Since NASTRAN cannot be called as a subroutine, a system architecture was developed of independently executable modules in which sequential execution is controlled by job control language. Also, shape sensitivities are not commonly available in commercial programs. A hybrid approach which is based on the material derivative concept is developed to obtain shape sensitivities by post processing finite element results stored on files. A quick generation of a good optimization model combined with an efficient optimization system will result in a drastic design time saving. In this paper, different modeling approaches for shape optimization are discussed. Emphasis will be placed upon a special modeling technique which overlays the design model onto an already existing finite element model. Several automotive related examples are used to evaluate the program's effectiveness.     

注塑模具CAE前后处理系统的设计与实现

本文详细分析了塑料模具计算机辅助工程（ＣＡＥ）前、后处理系统的功能及特点，针对有限元和边界元方法解决塑料模具设计仿真分析的特点，设计并实现了塑料模具ＣＡＥ前、后处理系统。该系统不仅能很好满足注塑模具ＣＡＥ的需求，而且具有通用性，建立、修改模型高效简单，可应用于其它领域ＣＡＥ系统的前、后处理系统。     

An object-oriented blackboard based approach for automated finite element modeling and analysis of multichip modules

This paper addresses the application of the blackboard system architecture and object-oriented data abstraction techniques to the domain of finite element modeling and analysis. Specifically, a hierarchical object-oriented database was used to represent the physical system at different levels of abstraction including the user-defined physical system level, a computer-generated, simplified physical model level, and the finite element model level. Object link relationships within a given abstraction level and across different abstraction levels resulted in seamless bidirectional information exchange. The blackboard system architecture employed provided a framework for distributed cooperative problem solving, for the application of simplifying domain-specific modeling assumptions, and for integrating the various software modules that are involved in the entire finite element modeling and analysis process. These methodologies were implemented in a prototype computational tool calledIMCMA theIntelligentMultichipModuleAnalyzer. An example illustrates howIMCMA automates finite element thermal analysis of small integrated circuit features in multichip modules through a two-step finite element submodeling process.     

A generalized computational interface for combined thermodynamic and kinetic modeling

The computational interface developed by Huang et al. (2008) [Z. Huang, P.P. Conway, R.C. Thomson, A.T. Dinsdale, J.A.J. Robinson, CALPHAD 32 (2008) 129-134] has been extended and generalized in different programming and modeling environments, which includes C, Fortran, Python and Java besides MATLAB and COMSOL Multiphysics. The generalized computational interface can be used to integrate various software packages for materials and process modeling into one programming platform, within which complicated modeling processes beyond the capability of these software packages can be achieved, such as combined thermodynamic and kinetic modeling, microstructural morphology evolution modeling for systems with arbitrary geometries and microstructure-based property prediction. The interface is applicable to all software packages that provide a dynamic-link library or DLL and the incorporation of Thermo-Calc and MTDATA are introduced in this paper. Several application examples utilizing the thermodynamic data of a Cu-Sn binary alloy system and an Fe-Cr-C ternary system are presented. In addition, modeling of solidification, using both a phase field and a phase field crystal models with the finite element method, are conducted within the integrated platform.     

SUT-DAM: An integrated software environment for multi-disciplinary geotechnical engineering

As computer simulation increasingly supports engineering design, the requirement for a computer software environment providing an integration platform for computational engineering software increases. A key component of an integrated environment is the use of computational engineering to assist and support solutions for complex design. In the present paper, an integrated software environment is demonstrated for multi-disciplinary computational modeling of structural and geotechnical problems. The SUT-DAM is designed in both popularity and functionality with the development of user-friendly pre- and post-processing software. Pre-processing software is used to create the model, generate an appropriate finite element grid, apply the appropriate boundary conditions, and view the total model. Post-processing provides visualization of the computed results. In SUT-DAM, a numerical model is developed based on a Lagrangian finite element formulation for large deformation dynamic analysis of saturated and unsaturated soils. An adaptive FEM strategy is used into the large displacement finite element formulation by employing an error estimator, adaptive mesh refinement, and data transfer operator. This consists in defining new appropriate finite element mesh within the updated, deformed geometry and interpolating (mapping) the pertinent variables from one mesh to another in order to continue the analysis. The SUT-DAM supports different yield criteria, including classical and advanced constitutive models, such as the Pastor–Zienkiewicz and cap plasticity models. The paper presents details of the environment and includes several examples of the integration of application software.     

面向集成化CAE软件开发的SiPESC研发工作进展

针对我国自主CAE软件发展缓慢的事实,根据现代工程领域的科学研究和产品研发对CAE建模、分析和设计能力提出的需求,研发自主的面向CAE工程与科学计算集成化软件平台SiPESC（Software Integration Platform for Engineering and Scientific Computation...     

GridMol系统中蛋白质可视化与建模的性能优化

基于网格计算思想开发一个具有计算化学前、后处理功能的系统GridMol,其主要功能包括分子可视化、分子建模和计算作业提交。针对GridMol系统中蛋白质大分子显示和建模遇到的性能问题,给出调整Java 3D场景图进行性能优化的方法,通过GridMol和其他分子可视化软件的性能比较以及自身优化前后的性能比较,证明优化方法取得了良好的效果。