Impact of surface enhancements upon boiling heat transfer in a liquid immersion cooled high performance small form factor server model

Fourteenth Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) Pub Date : 2014-05-27 DOI:10.1109/ITHERM.2014.6892314

J. Gess, S. Bhavnani, Bharath Ramakrishnan, R. Johnson, D. Harris, R. Knight, M. Hamilton, C. Ellis, J. Gess

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引用次数: 10

Abstract

The impact of increasing power consumption trends on a global economy with limited resources to sustain them cannot be understated. As worldwide communication requirements expand, data centers will need to be designed more efficiently to not only keep operation costs down for a business' bottom line, but also to be mindful of the world's power availability and resource supply. Therefore, the importance of designing data centers efficiently, but also compactly grows in step with society's power demands. To integrate into this new smarter data center, work has been completed on a small form factor, modular, high performance liquid immersion cooled server model with heat dissipations of over 700 Watts. These high power dissipations were achieved by the integration of enhanced surfaces affixed to the bare silicon die to promote increased boiling performance. The two surfaces tested were a sintered copper microporous heat sink and one that contained a dense array of microscale fins.

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表面增强对液体浸没冷却高性能小尺寸服务器模型沸腾传热的影响

在资源有限的情况下，日益增长的电力消费趋势对全球经济的影响不容低估。随着全球通信需求的扩大，数据中心将需要更有效地设计，不仅要降低业务底线的运营成本，还要注意全球的电力可用性和资源供应。因此，设计高效而紧凑的数据中心的重要性随着社会的电力需求而增长。为了集成到这个新的智能数据中心，已经完成了一个小尺寸、模块化、高性能的液体浸入式冷却服务器模型的工作，其散热超过700瓦。这些高功耗是通过集成附加在裸硅芯片上的增强表面来实现的，以提高沸腾性能。测试的两个表面是烧结铜微孔散热片和包含密集微尺度翅片阵列的表面。

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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Fourteenth Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm)

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