Automotive Silicon Carbide Power Module Cooling With A Novel Modular Manifold And Embedded Heat Sink

IF 2.2 4区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Electronic Packaging Pub Date : 2023-06-29 DOI:10.1115/1.4062869

A. Osman, G. Moreno, Steve Myers, J. Major, Xuhui Feng, S. Narumanchi, Y. Joshi

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引用次数: 0

Abstract

The next generation of integrated power electronics packages will implement wide-bandgap devices with ultrahigh device heat fluxes. Although jet impingement has received attention for power electronics thermal management, it is not used in commercial electric vehicles (EVs) because of the associated pressure drop and reliability concerns. In this paper, we present a modular thermal management system designed for automotive power electronics. The system achieves superior thermal performance to benchmarked EVs, while adhering to reliability standards and with low pumping power. The system utilizes a low-cost and lightweight plastic manifold to generate jets over an optimized heat sink, which is embedded in the direct-bonded-copper (DBC) substrate. The embedded heat sink concept leverages additive manufacturing to add elliptical pin fins to the DBC substrate. The heat sink geometry is optimized for submerged jet impingement using a unit-cell model and an exhaustive search algorithm. The model predictions are validated using unit-cell experiments. A full-scale power module model is then used to compare the DBC-embedded heat sink against direct DBC cooling and baseplate-integrated heat sinks for single-sided (SS) and double-sided (DS) cooling concepts. Using the SS and DS DBC-embedded cooling concepts, the models predict a thermal resistance that represents a reduction of 75% and 85% compared to the 2015 BMW i3, respectively, for the same water-ethylene glycol inverter flow rate. We have shown that an inverter with a 100-kilo-Watt-per-liter power density is achievable with the proposed design.

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汽车碳化硅功率模块冷却与一个新的模块化歧管和嵌入式散热器

下一代集成电力电子封装将实现具有超高器件热通量的宽带隙器件。尽管射流冲击在电力电子热管理方面受到了广泛关注，但由于相关的压力降和可靠性问题，它并未应用于商用电动汽车(ev)。本文提出了一种用于汽车电力电子器件的模块化热管理系统。该系统的热性能优于基准电动汽车，同时符合可靠性标准，泵送功率低。该系统采用低成本、轻质的塑料歧管，通过优化的散热器产生射流，该散热器嵌入直接键合铜(DBC)基板中。嵌入式散热器概念利用增材制造在DBC基板上添加椭圆引脚鳍。采用单元格模型和穷极搜索算法对水下射流冲击散热器的几何结构进行了优化。通过单元实验验证了模型的预测结果。然后使用全尺寸功率模块模型来比较DBC嵌入式散热器与直接DBC冷却以及单面(SS)和双面(DS)冷却概念的底板集成散热器。使用SS和DS dbc嵌入式冷却概念，模型预测，在相同的水-乙二醇逆变器流量下，与2015款宝马i3相比，热阻分别降低了75%和85%。我们已经表明，逆变器与100千瓦每升的功率密度是可以实现与提出的设计。

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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来源期刊

Journal of Electronic Packaging 工程技术-工程：电子与电气

CiteScore

4.90

自引率

6.20%

发文量

审稿时长

3 months

期刊介绍： The Journal of Electronic Packaging publishes papers that use experimental and theoretical (analytical and computer-aided) methods, approaches, and techniques to address and solve various mechanical, materials, and reliability problems encountered in the analysis, design, manufacturing, testing, and operation of electronic and photonics components, devices, and systems. Scope: Microsystems packaging; Systems integration; Flexible electronics; Materials with nano structures and in general small scale systems.