Towards In-line Control of Continuous Resistance Welding for Joining Structural Thermoplastic Composites

IF 0.2 4区材料科学 Q4 ENGINEERING, MULTIDISCIPLINARY SAMPE Journal Pub Date : 2023-09-01 DOI:10.33599/sj.v59no5.01

Marc Palardy-Sim, Julieta Barroeta Robles, Marc-André Octeau, Steven Roy, Ali Yousefpour, Stephen Atkinson, Scott Nesbitt, Reza Vaziri, Anoush Poursartip, Manuel Endrass, Lars Larsen, Michael Kupke

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Abstract

The continuous resistance welding (CRW) process consists of an end-effector which moves along the length of a weld seam, heating a conductive implant while compacting the joint locally throughout the melt and solidification stages of the thermoplastic material. The performance of the joint has been shown to be highly dependent on the process temperature at the weld interface; however, this cannot be measured directly during the process in a non-invasive manner. Other parameters such as boundary conditions, substructure properties, or part geometry may vary along the length of the weld. As such, a physics-based simulation is developed founded upon an “MSTEP” framework which defines how the materials (M), shape (S), tooling (T), and equipment (E) interact to determine the process (P). Detailed finite element (FE) models are developed for thermal analysis based on the weld geometry, boundary conditions, and previously developed and validated melt/crystallization models for the thermoplastic matrix. Experimental CRW tests are presented to validate simulations and calibrate suitable control variables.

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结构热塑性复合材料连接连续电阻焊在线控制研究

连续电阻焊(CRW)工艺包括一个末端执行器，它沿着焊缝的长度移动，加热导电植入物，同时在热塑性材料的熔化和凝固阶段局部压实接头。接头的性能高度依赖于焊接界面处的工艺温度;然而，这不能在过程中以非侵入性的方式直接测量。其他参数，如边界条件、子结构特性或零件几何形状可能沿焊缝长度变化。因此，在“MSTEP”框架的基础上开发了基于物理的模拟，该框架定义了材料(M)、形状(S)、工具(T)和设备(E)如何相互作用以确定工艺(P)。基于焊缝几何形状、边界条件以及先前开发和验证的热塑性基体的熔体/结晶模型，开发了详细的有限元(FE)模型，用于热分析。通过CRW实验验证了仿真结果，并标定了合适的控制变量。

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来源期刊

SAMPE Journal 工程技术-材料科学：综合

CiteScore

0.16

自引率

0.00%

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审稿时长

>12 weeks

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