This paper presents the application of response surface method in finite element model updating, as an approach for improving the accuracy and efficiency of the finite element model of a laser spot welded structure, to reflect the physical responses of the structure. The procedures of implementation for response surface in model updating such as sampling method, selecting the significant updating parameters and constructing a quadratic polynomial response surface are discussed. Initially, the finite element model of the structure was developed using CQUAD4 shell element alongside CWELD element connectors to represent laser spot weld joints. Then, NASTRAN SOL 103 was used to calculate the dynamic behaviour of the model (natural frequencies and mode shapes). The experimental modal analysis was then conducted under free-free boundary conditions via LMS SCADAS to obtain experimental data. The minimisation of the discrepancies of the finite element model was based on objective function that was formed by the residuals between finite element and experimental natural frequencies. Results show that response surface method was efficient to be used in finite element model updating since it is capable to improve the accuracy of the finite element model.
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机译:本文介绍了响应面法在有限元模型更新中的应用,作为提高激光点焊结构有限元模型的准确度和效率的方法,反映结构的物理响应。讨论了诸如采样方法的模型更新中的响应表面的实现程序,选择了显着的更新参数和构建二次多项式响应表面。最初,使用CudAd4壳元件开发了结构的有限元模型,沿着CWELD元件连接器来表示激光点焊接头。然后,Nastran Sol 103用于计算模型的动态行为(自然频率和模式形状)。然后通过LMS SCADA在自由边界条件下进行实验模态分析以获得实验数据。有限元模型的差异的最小化基于由有限元和实验自然频率之间的残差形成的目标函数。结果表明,响应面方法有效地用于有限元模型更新,因为它能够提高有限元模型的准确性。
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