Development of Flexible Hybrid Electronics Using Reflow Assembly with Stretchable Film

Weifeng Liu, W. Uy, Alex Chan, D. Shangguan, Andy Behr, Takatoshi Abe, Fukao Tomohiro
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引用次数: 2

Abstract

Flexible hybrid electronics (FHE) are manufactured by combining traditional circuit board fabrication and assembly processes with emerging printed electronics technology. By integrating surface mounted electronic components with printed stretchable conductive circuits and compliant/stretchable substrates these hybrid constructions have potential to revolutionize electronic assemblies used for Internet of Things (IOT), wearable, medical, wellness, automotive and aerospace markets. By employing FHE principles, designers can create heterogeneous electronic systems with unique form factors and functionality. These devices can conform to the curves of a human body or even be applied to the surface of or molded within an irregularly shaped mechanical structure. FHEs also offer the promise of light-weight and cost-effectiveness, scalable manufacturing. The FHE industry remains in the early stages of development. A variety of design, material, assembly and reliability issues remain to be addressed. For example, the typical polymer based conductive pastes used for forming FHE circuit structures are not as conductive as the etched copper on traditional printed circuit boards (PCBs.) Additionally, most of these polymer-based conductive pastes are not readily solderable and the electrical interconnections formed with conductive adhesives in current FHE designs may not be as conductive or reliable as those formed with solder. Additionally, commercially available stretchable thermoplastic film substrates have relatively low thermal resistance and cannot withstand the current lead-free surface mount technology (SMT) reflow temperatures. This paper discusses these challenges and presents an FHE manufacturing process utilizing a stretchable thermosetting polymer substrate, a combination of both screen-printed stretchable conductive paste and etched copper structure, and the conventional SMT processes to create a functional proof of concept double-sided device integrating both active and passive components.
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利用可拉伸薄膜回流流组件开发柔性混合电子器件
柔性混合电子(FHE)是将传统的电路板制造和组装工艺与新兴的印刷电子技术相结合而制造出来的。通过将表面安装的电子元件与印刷可拉伸导电电路和兼容/可拉伸基板集成在一起,这些混合结构有可能彻底改变用于物联网(IOT)、可穿戴、医疗、健康、汽车和航空航天市场的电子组件。通过采用FHE原理,设计师可以创建具有独特外形因素和功能的异构电子系统。这些装置可以符合人体的曲线,甚至可以应用于不规则形状的机械结构的表面或成型。FHEs还提供了轻量化、成本效益高、可扩展制造的承诺。FHE行业仍处于发展的早期阶段。各种设计、材料、装配和可靠性问题仍有待解决。例如,用于形成FHE电路结构的典型聚合物导电浆料的导电性不如传统印刷电路板(pcb)上的蚀刻铜。此外,大多数这些基于聚合物的导电浆料不容易焊接,并且在当前的FHE设计中,用导电粘合剂形成的电气互连可能不如用焊料形成的导电或可靠。此外,市售的可拉伸热塑性薄膜基板具有相对较低的热阻,无法承受目前的无铅表面贴装技术(SMT)回流温度。本文讨论了这些挑战,并提出了一种FHE制造工艺,利用可拉伸热固性聚合物衬底,结合丝网印刷可拉伸导电浆料和蚀刻铜结构,以及传统的SMT工艺来创建集成有源和无源组件的功能概念验证双面器件。
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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