Inverse methods in computational modeling of welding processes

焊接过程计算建模中的逆向方法

基本信息

批准号：
349293-2006
负责人：
Protas, Bartosz
金额：
$ 2.92万
依托单位：
McMaster University
依托单位国家：
加拿大
项目类别：
Collaborative Research and Development Grants
财政年份：
2010
资助国家：
加拿大
起止时间：
2010-01-01 至 2011-12-31
项目状态：
已结题

来源：
https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=459142
关键词：
Inverse methods computational modeling welding

项目摘要

The goal of this project is to continue the development of advanced engineering tools integrating the Optimization Theory with recent progress in mathematical and computational modeling of complex, multi-physics processes involved in industrial welding. We will apply and further elaborate the advances made during an earlier project. In particular, we intend to develop an improved suite of computational tools that will allow research engineers to (i) create optimal input process parameter schedules (speed, current, power, etc.) for the Metal Inert Gas (MIG) welding process; these schedules will also ensure minimal heat input and, consequently, minimal material distortion, (ii) perform estimation of certain unknown parameters of the model (e.g., solution-dependent material properties) based on experimental measurements; actual values of material properties are often difficult to obtain, hence suitably performed parameter estimation will likely improve fidelity of computational modelling. This interdisciplinary research project will be carried out jointly by Dr. Protas' group at McMaster University, which will bring mathematical and computational expertise, and General Motors of Canada (GM) which will contribute engineering expertise. We will also closely interact with physicists from the Commonwealth Scientific and Industrial Research Organisation (CSIRO) in Australia who will be working with GM on a related problem. During the course of the project we will provide interdisciplinary training, involving elements of applied and computational mathematics as well as physics and applied engineering science, to a graduate student and a post-doctoral fellow to be recruited to work full-time on this project. The results of this project may have the generic effect of improving the joining technology used in various sectors of the manufacturing industry and may therefore exert a positive influence on the Canadian economy. For example, the optimization methodology developed in this project could be used by GM to improve the joining technology of its vehicles assembled at the GM plant in Oshawa, ON. This project will also create opportunities for Dr. Protas' group to make contributions at the forefront of academic research.

该项目的目的是继续开发高级工程工具，将优化理论与涉及工业焊接的复杂多物理过程的数学和计算建模的最新进展相结合。我们将申请并进一步详细说明在早期项目中取得的进步。特别是，我们打算开发一套改进的计算工具套件，以使研究工程师（i）为金属惰性气（MIG）焊接过程创建最佳输入过程参数计划（速度，电流，电源等）；这些时间表还将确保最少的热输入，因此，（ii）基于实验测量值对模型的某些未知参数（例如，溶液依赖性材料特性）进行估算；材料属性的实际值通常很难获得，因此适当执行的参数估计可能会提高计算建模的保真度。该跨学科研究项目将由麦克马斯特大学的Protas博士集团共同执行，该小组将带来数学和计算专业知识，以及加拿大的通用汽车（GM），这将促进工程专业知识。我们还将与澳大利亚联邦科学和工业研究组织（CSIRO）的物理学家进行密切互动，他们将与GM合作解决一个相关问题。在项目过程中，我们将提供跨学科培训，涉及应用和计算数学的要素以及物理学和应用工程科学，并向研究生和博士后研究员全职招募。该项目的结果可能具有改善制造业各个领域使用的连接技术的通用效果，因此可能对加拿大经济产生积极影响。例如，通用汽车可以使用该项目中开发的优化方法来改善其在Oshawa的GM工厂组装的车辆的连接技术。该项目还将为Protas博士的小组创造机会，以在学术研究的最前沿做出贡献。