Panel Level Packaging for Component Integration of an Energy Harvesting System

2019 International Wafer Level Packaging Conference (IWLPC) Pub Date : 2019-10-01 DOI:10.23919/IWLPC.2019.8914021

T. Braun, K. Lang, R. Kahle, S. Voges, O. Hölck, J. Bauer, K. Becker, R. Aschenbrenner, M. Dreissigacker, M. Schneider-Ramelow

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Abstract

Within the European funded project smart-MEMPHIS the goal was to tackle the main challenge for all smart devices – self-powering. The project was aimed to design, manufacture and test a miniaturized autonomous energy supply based on harvesting vibrational energy with piezo-MEMS energy harvesters. Cost effective packaging was needed for 3D system integration of a MEMS-based multi-axis energy harvester, an ultra-low-power ASIC to manage the variations of the frequency and harvested power, and a miniaturized energy storing supercapacitor. Miniaturization was another key demand as target applications were a leadless pacemaker and a wireless sensor network for structural health monitoring. Panel Level Packaging (PLP) was selected as packaging technology for the harvester components. A basic study on the embedding of piezo-MEMS harvester has been performed as well as the development and proof of concept of a new PLP based supercapacitor housing. For the power management unit an ASIC together with two capacitors have been integrated by Fan-out Panel Level Packaging (FOPLP). Material selection and process development was first done on wafer level size and then transferred to large area 457x305 mm2 panel size. Main focus was here to find a suitable material combination and process parameters for the embedding of SMD capacitors together with bare dies in a fan-out panel level package. A technology study has been performed to analyze the influence of SMD component size and pitch, thermal release tape and epoxy molding compound type during compression molding. Results have used to finally select materials for prototype built. Reliability testing have been performed to prove the overall concept and material selection for PLP.

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能量收集系统组件集成的面板级封装

在欧洲资助的smart- memphis项目中，目标是解决所有智能设备面临的主要挑战——自供电。该项目旨在设计、制造和测试一种基于压电mems能量采集器收集振动能量的小型化自主能源供应。基于mems的多轴能量采集器、用于管理频率和收集功率变化的超低功耗ASIC以及小型化储能超级电容器的3D系统集成需要具有成本效益的封装。小型化是另一个关键需求，因为目标应用是无导线起搏器和用于结构健康监测的无线传感器网络。选择面板级封装(PLP)作为收割机部件的封装技术。对压电- mems收割机的嵌入进行了基础研究，并对一种新的基于PLP的超级电容器外壳进行了开发和概念验证。对于电源管理单元，通过扇出面板级封装(FOPLP)集成了ASIC和两个电容器。材料选择和工艺开发首先在晶圆级尺寸上完成，然后转移到大面积457x305mm2面板尺寸。这里的主要重点是找到合适的材料组合和工艺参数，以便在扇出面板级封装中嵌入SMD电容器和裸晶片。通过工艺研究，分析了SMD元件尺寸和节距、热脱模胶带和环氧树脂成型复合材料类型对压缩成型过程的影响。结果用于最后选择材料进行原型制作。进行了可靠性测试，以证明PLP的整体概念和材料选择。

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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2019 International Wafer Level Packaging Conference (IWLPC)

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