Bharath Nagendran, S. Nagaraj, J. Fernandes, R. Eiland, D. Agonafer, V. Mulay
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引用次数: 9
Abstract
As a common practice in the data center industry, chassis fans are used to direct air flow independent from neighboring servers. In general, smaller fans are less efficient compared to geometrically similar larger fans. In this study, a novel approach is proposed whereby chassis enclosed fans are replaced with a smaller number of larger fans installed behind a stacked array of servers which share airflow. As a baseline study, a CPU dominated 1.5U Open Compute server with four 60mm fans installed within its chassis is characterized experimentally for its flow impedance, fan speed dependent flow rate, effect on die temperature and power consumption at various compute utilization levels. Larger fans with a square frame size of 80mm and 120mm are selected and individually characterized for their air moving capacity and power consumption. Primary emphasis is placed on the 80mm fan case, with discussion of the 120mm fans included. CFD is used to simulate a system of stacked servers serviced by larger fans to obtain its flow characteristics and operating points. The fan power consumption of the larger fans is determined experimentally at these operating points replicated in an air flow bench. Comparing with the base line experiments, replacing smaller fans with larger units results in a significant decrease in fan power consumption without conceding flow rate and static pressure requirements.
作为数据中心行业的一种常见做法,机箱风扇用于引导空气流动,而不依赖于相邻的服务器。一般来说,与几何形状相似的大型风扇相比,较小的风扇效率较低。在本研究中,提出了一种新颖的方法,即将机箱封闭的风扇替换为安装在堆叠服务器阵列后面的数量较少的较大风扇,从而共享气流。作为基线研究,以CPU为主的1.5U Open Compute服务器为例,在机箱内安装4个60mm风扇,实验表征了不同计算利用率下的流阻抗、风扇转速相关的流量、对芯片温度和功耗的影响。选择方形框架尺寸为80mm和120mm的大型风扇,并根据其空气移动能力和功耗进行单独表征。主要重点放在80mm风扇机箱上,包括对120mm风扇的讨论。利用CFD模拟了一个由大型风扇服务的堆叠服务器系统,以获得其流动特性和工作点。在空气流动实验台上复制这些工作点,实验确定了较大风扇的风扇功耗。与基线实验相比,在不降低流量和静压要求的情况下,用大风机代替小风机可以显著降低风机功耗。