Investigation of the effect and optimization of material properties on the printed circuit board

Bilbay Fahri Berk, Arslan Erhan, Ediz Barış, Mustafa Cemal Çakır
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Abstract

Printed circuit boards (PCBs) have a sandwich structure consisting of an insulating composite layer between conductive copper layers. The material property of the PCB cannot be defined as isotropic due to this special structure. In addition, variables such as the types of hundreds of components on the PCB, material properties, types of solder leads, and thickness of the sandwich structure make it very difficult to create and verify the finite element model of the PCB. The aim of this study is to perform a sensitivity analysis by defining the strain values measured from three points on the PCB with the help of strain gauges as responses and to find the best design variables that correlate with the physical test. The effect of each design parameter on the response function was examined, and the results were obtained with statistical data. The objective function and constraints were determined to find the best correlated finite element model with a physical test, and the best design was obtained by running the optimization model. In this way, the finite element model was calibrated by taking into account the thermal stresses resulting from the heat generated by the transistors and by using optimization methods.
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材料性能对印刷电路板的影响及优化研究
印刷电路板(pcb)具有由导电铜层之间的绝缘复合层组成的夹层结构。由于这种特殊的结构,PCB的材料性质不能被定义为各向同性。此外,诸如PCB上数百个组件的类型、材料属性、焊锡引线类型和夹层结构厚度等变量使得创建和验证PCB的有限元模型非常困难。本研究的目的是通过定义在应变片的帮助下从PCB上的三个点测量的应变值作为响应来进行灵敏度分析,并找到与物理测试相关的最佳设计变量。考察了各设计参数对响应函数的影响,得到了具有统计数据的结果。确定目标函数和约束条件,寻找与实物试验相关联的最佳有限元模型,运行优化模型得到最佳设计方案。这样,通过考虑晶体管发热产生的热应力并采用优化方法对有限元模型进行了校准。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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