On reliability and uptime of IT in contained solution

2016 15th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm) Pub Date : 2016-05-01 DOI:10.1109/ITHERM.2016.7517715

H. Alissa, K. Nemati, B. Sammakia, M. Seymour, Russell Tipton, Tom Wu, Ken Schneebeli

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引用次数: 2

Abstract

In this investigation, we utilize a new method of characterization in which IT airflow systems are ranked from a 1RU ToR switches, xRU servers to 9RU Blade Center. The free delivery (FD) and the critical pressure (Pc) are unique properties of each IT airflow system, satisfying its active flow curve (AFC). Those curves are used in previously validated models to investigate the interaction of IT with different air systems in a confined space. A validated model of containment is studied of a CAC aisle from Binghamton University data center lab. It is shown that reverse flow can take place in an operating piece of IT with weaker air system; this can endanger IT reliability and up time at different data center events. This can also change previous conclusions about the ride through time in well-sealed fully contained systems. Another important finding is that design containment systems based on the assumption of uniform load in the aisle/cabinet is a misconception that can endanger facility operation. In general, the reduction in airflow rate upon events in the data center (DC) is a function of each IT air system. To our knowledge, this is the first time in literature where both recent models of IT active flow curves and black box thermal inertia are combined to yield realistic failure analysis of contained solutions.

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关于IT在包含解决方案中的可靠性和正常运行时间

在这项调查中，我们利用了一种新的表征方法，其中IT气流系统从1RU ToR交换机，xRU服务器到9RU刀片中心进行排名。自由流量(FD)和临界压力(Pc)是每个IT气流系统的独特特性，满足其主动流量曲线(AFC)。这些曲线用于先前验证的模型中，以研究IT与密闭空间中不同空气系统的相互作用。对宾厄姆顿大学数据中心实验室的CAC通道进行了验证的密封模型研究。结果表明，在空气系统较弱的情况下，It的操作部件会发生回流;这可能危及IT可靠性和不同数据中心事件的正常运行时间。这也可以改变之前关于在密封良好的全密封系统中穿越时间的结论。另一个重要的发现是，基于通道/机柜中均匀负载的假设来设计密封系统是一种误解，可能危及设施的运行。通常，数据中心(DC)中发生事件时的气流速率降低是每个IT空气系统的功能。据我们所知，这是文献中第一次将IT活动流动曲线和黑盒热惯性的最新模型结合起来，以产生包含解决方案的实际故障分析。

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

2016 15th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena in Electronic Systems (ITherm)

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