液冷3D多核处理器的有效热控制技术

Yue Hu, Shaoming Chen, Lu Peng, Edward Song, Jin-Woo Choi
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引用次数: 6

摘要

微通道液体冷却在冷却3D处理器方面显示出巨大的潜力。然而,由于设计时和运行时的挑战,3D处理器的冷却受到限制。此外,在新技术中,处理器功率密度不断提高,这将给液冷带来更严峻的挑战。本文提出了两种热控制技术:1)核心垂直放置(CVP)技术。根据处理器核心的结构,给出了两种将核心垂直放置在多层上的方案。采用CVP技术的3D处理器可以更好地冷却,因为其单独的热点块与较冷的环境有更大的总接触面积。2)热电冷却(TEC)技术。我们建议将TEC技术整合到液冷3D处理器中,以增强热点的冷却。实验表明,与基线设计相比,CVP技术可将最高温度降低29.58°C,平均降低16.64°C。此外,TEC技术有效地将热点从96.86°C冷却到78.60°C。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effective thermal control techniques for liquid-cooled 3D multi-core processors
Microchannel liquid cooling shows great potential in cooling 3D processors. However, the cooling of 3D processors is limited due to design-time and run-time challenges. Moreover, in new technologies, the processor power density is continually increasing and this will bring more serious challenges to liquid cooling. In this paper, we propose two thermal control techniques: 1) Core Vertically Placed (CVP) technique. According to the architecture of a processor core, two schemes are given for placing a core vertically onto multilayers. The 3D processor with the CVP technique can be better cooled since its separate hotspot blocks have a larger total contact area with the cooler surroundings. 2) Thermoelectric cooling (TEC) technique. We propose to incorporate the TEC technique into the liquid-cooled 3D processor to enhance the cooling of hotspots. Our experiments show the CVP technique reduces the maximum temperature up to 29.58 °C, and 16.64 °C on average compared with the baseline design. Moreover, the TEC technique effectively cools down a hotspot from 96.86 °C to 78.60 °C.
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