A new hybrid heat sink with impinging micro-jet arrays and microchannels fabricated using high volume additive manufacturing

2017 33rd Thermal Measurement, Modeling & Management Symposium (SEMI-THERM) Pub Date : 2017-03-13 DOI:10.1109/SEMI-THERM.2017.7896927

A. Robinson, W. Tan, R. Kempers, J. Colenbrander, N. Bushnell, R. Chen

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引用次数: 21

Abstract

This work describes the design of a high-performance water cooled micro heat sink for thermal management of high heat flux microelectronics. The design process leverages advances in additive manufacturing to produce flow channels and composite material structures that are not possible with traditional machining processes. The micro heat sink was designed with microchannels and an array of fins with integrated microjets (FINJET™ architecture). Simulation Driven Design (SDD), using ANSYS Fluent CFD software, was used to design the micro heat exchanger with overall outer dimensions of 4.1mm (length) × 3.2mm (width) × 1mm (thickness). Based on the SDD results, a prototype was fabricated and tested with heat fluxes up to and exceeding 1000 W/cm2. The results show that the numerical and experimental results are in reasonable agreement considering the complexity of the flow and associated conjugate heat transfer within the device. Importantly, experimental performance achieved an estimated overall thermal conductance of ∼300 kW/m2K with an associated pressure drop of 160 kPa (23 psi) for a flow rate of 0.5 L/min. For 20°C water at the inlet, this corresponded to a measured base temperature of 54°C for an applied heat flux of 1000 W/cm2.

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采用大量增材制造技术制造了一种具有撞击微射流阵列和微通道的新型混合散热器

本文介绍了用于高热流密度微电子热管理的高性能水冷微散热器的设计。设计过程利用增材制造的先进技术来生产传统加工工艺无法实现的流道和复合材料结构。该微散热器设计有微通道和带有集成微射流的鳍阵列(FINJET™架构)。利用ANSYS Fluent CFD软件，采用仿真驱动设计(SDD)方法，设计了外形尺寸为4.1mm(长)× 3.2mm(宽)× 1mm(厚)的微型换热器。基于SDD的结果，制作了一个原型并进行了热流高达或超过1000 W/cm2的测试。结果表明，考虑到装置内部流动和相关的共轭传热的复杂性，数值计算结果与实验结果吻合较好。重要的是，在0.5 L/min的流速下，实验性能达到了约300 kW/m2K的总热导率，相关压降为160 kPa (23 psi)。对于入口温度为20°C的水，在施加热流密度为1000 W/cm2的情况下，这相当于测量到的基础温度为54°C。

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

2017 33rd Thermal Measurement, Modeling & Management Symposium (SEMI-THERM)

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