Comprehensive Experimental and Computational Analysis of a Fully Contained Hybrid Server CabinetSource: Journal of Heat Transfer:;2017:;volume( 139 ):;issue: 008::page 82101Author:Nemati, Kourosh
,
Alissa, Husam A.
,
Murray, Bruce T.
,
Sammakia, Bahgat G.
,
Tipton, Russell
,
Seymour, Mark J.
DOI: 10.1115/1.4036100Publisher: The American Society of Mechanical Engineers (ASME)
Abstract: The rapid growth in the number of data centers combined with the high-density heat dissipation of computer and telecommunications equipment has made energy efficient thermal management of data centers a key research area. Localized hybrid air–water cooling is one approach to more effectively control the cooling when there is wide variation in the amount of dissipation in neighboring racks while the traditional air cooling approach requires overprovisioning. In a closed, hybrid air–water cooled server cabinet, the generated heat is removed by a self-contained system that does not interact with the room level air cooling system. Here, a hybrid-cooled enclosed cabinet and all its internal components were characterized experimentally in steady-state mode (e.g., experimentally determined heat-exchanger effectiveness and IT characterization). Also, a comprehensive numerical model of the cabinet was developed and validated using the experimental data. The computational model employs full numerical modeling of the cabinet geometry and compact models to represent the servers and the air/water heat exchanger. The compact models were developed based on experimental flow and thermal characterization of the internal components. The cabinet level model has been used to simulate a number of operating scenarios relevant to data center applications such as the effect of air leakage within the cabinet. The effect of the air side and the water side failure of the cooling system on the IT performance were investigated experimentally. A comparison was made of the amount of time required to exceed the operating temperature limit for the two scenarios.
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contributor author | Nemati, Kourosh | |
contributor author | Alissa, Husam A. | |
contributor author | Murray, Bruce T. | |
contributor author | Sammakia, Bahgat G. | |
contributor author | Tipton, Russell | |
contributor author | Seymour, Mark J. | |
date accessioned | 2017-11-25T07:16:55Z | |
date available | 2017-11-25T07:16:55Z | |
date copyright | 2017/11/4 | |
date issued | 2017 | |
identifier issn | 0022-1481 | |
identifier other | ht_139_08_082101.pdf | |
identifier uri | http://138.201.223.254:8080/yetl1/handle/yetl/4234299 | |
description abstract | The rapid growth in the number of data centers combined with the high-density heat dissipation of computer and telecommunications equipment has made energy efficient thermal management of data centers a key research area. Localized hybrid air–water cooling is one approach to more effectively control the cooling when there is wide variation in the amount of dissipation in neighboring racks while the traditional air cooling approach requires overprovisioning. In a closed, hybrid air–water cooled server cabinet, the generated heat is removed by a self-contained system that does not interact with the room level air cooling system. Here, a hybrid-cooled enclosed cabinet and all its internal components were characterized experimentally in steady-state mode (e.g., experimentally determined heat-exchanger effectiveness and IT characterization). Also, a comprehensive numerical model of the cabinet was developed and validated using the experimental data. The computational model employs full numerical modeling of the cabinet geometry and compact models to represent the servers and the air/water heat exchanger. The compact models were developed based on experimental flow and thermal characterization of the internal components. The cabinet level model has been used to simulate a number of operating scenarios relevant to data center applications such as the effect of air leakage within the cabinet. The effect of the air side and the water side failure of the cooling system on the IT performance were investigated experimentally. A comparison was made of the amount of time required to exceed the operating temperature limit for the two scenarios. | |
publisher | The American Society of Mechanical Engineers (ASME) | |
title | Comprehensive Experimental and Computational Analysis of a Fully Contained Hybrid Server Cabinet | |
type | Journal Paper | |
journal volume | 139 | |
journal issue | 8 | |
journal title | Journal of Heat Transfer | |
identifier doi | 10.1115/1.4036100 | |
journal fristpage | 82101 | |
journal lastpage | 082101-12 | |
tree | Journal of Heat Transfer:;2017:;volume( 139 ):;issue: 008 | |
contenttype | Fulltext |