High Power-Density 3D Integrated Power Supply Module Based on Panel-Level PCB Embedded Technology

2018 IEEE 68th Electronic Components and Technology Conference (ECTC) Pub Date : 2018-05-01 DOI:10.1109/ECTC.2018.00208

Fengze Hou, Xueping Guo, Qidong Wang, Wenbo Wang, Tingyu Lin, Liqiang Cao, G. Zhang, J. Ferreira

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引用次数: 8

Abstract

In this paper, a high power-density 3D integrated synchronous buck converter with dual side cooling structure was designed and analyzed. A novel panel-level PCB embedded package technology for MOSFETs and planar LTCC inductor of the converter was proposed to address parasitic elements, heat dissipation, and reliability issues inherent with aluminum wires used in conventional wire-bonded package. The MOSFETs and LTCC inductor were embedded in the PCB, respectively, interconnected by RDL and PCB vias. Copper-clad BT laminate and BT prepreg with low CTE and high Tg were selected and characterized by TMA. Analysis showed that the selective PCB embedding materials were very ideal for MOSFETs and LTCC inductor packaging. Thermal simulation of the 3D module was performed using ANSYS ICEPAK. To improve accuracy and efficiency of the thermal simulation, equivalent thermal conductivity of a PCB via unit was extracted and equivalent model was built. Effects of PCB vias and heat spreader on the thermal performance of the 3D converter were analyzed. The study showed that PCB vias can improve the thermal performance of the 3D module with cap heat spreader. The highest junction temperature of the optimized 3D converter was limited to about 71.2 °C.

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基于面板级PCB嵌入式技术的高功率密度3D集成电源模块

本文设计并分析了一种双侧冷却结构的高功率密度三维集成同步降压变换器。提出了一种用于mosfet和平面LTCC转换器电感的新型面板级PCB嵌入式封装技术，以解决传统线键合封装中使用的铝线固有的寄生元件，散热和可靠性问题。mosfet和LTCC电感分别嵌入PCB中，通过RDL和PCB过孔互连。选择了低CTE、高Tg的包铜BT层压板和BT预浸料，并用TMA对其进行了表征。分析表明，选择性PCB包埋材料是mosfet和LTCC电感封装的理想材料。利用ANSYS ICEPAK软件对三维模块进行了热仿真。为了提高热模拟的准确性和效率，提取了PCB通孔单元的等效导热系数，并建立了等效模型。分析了PCB通孔和散热片对三维转换器热性能的影响。研究表明，PCB通孔可以改善带帽式散热片的三维模块的散热性能。优化后的三维变换器的最高结温限制在71.2℃左右。

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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2018 IEEE 68th Electronic Components and Technology Conference (ECTC)

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