Tandem Equipment Arranged Architecture with Exhaust Heat Reuse System for Software-Defined Data Center Infrastructure
Issue No. 02 - April-June (2017 vol. 5)
Yoshiaki Taniguchi , Faculty of Science and Engineering, Kindai University, Osaka, Japan
Koji Suganuma , Graduate School of Information Science, Nara Institute of Technology, Nara, Ikoma, Japan
Takaaki Deguchi , Graduate School of Information Science and Technology, Osaka University, Osaka, Suita, Japan
Go Hasegawa , Cybermedia Center, Osaka University, Osaka, Toyonaka, Japan
Yutaka Nakamura , Graduate School of Engineering Science, Osaka University, Osaka, Toyonaka, Japan
Norimichi Ukita , Graduate School of Information Science, Nara Institute of Technology, Nara, Ikoma, Japan
Naoki Aizawa , Research & Development Center, Takasago Thermal Engineering Corporation, Atsugi, Japan
Katsuhiko Shibata , Research & Development Center, Takasago Thermal Engineering Corporation, Atsugi, Japan
Kazuhiro Matsuda , NTT Advanced Technology Corporation, Tokyo, Mitaka, Japan
Morito Matsuoka , Cybermedia Center, Osaka University, Osaka, Toyonaka, Japan
In this paper, we propose a novel energy-efficient architecture for software-defined data center infrastructures. In our proposed data center architecture, we include an exhaust heat reuse system that utilizes high-temperature exhaust heat from servers in conditioning humidity and air temperature of office space near the data center. To obtain high-temperature exhaust heat, equipment such as server racks and air conditioners are deployed in tandem so that the aisles are divided into three types: cold, hot, and super-hot. In this paper, to investigate the fundamental characteristics of our proposed data center architecture, we consider various types of data center models and conduct numerical simulations that use results obtained by experiments at an actual data center. Through simulation, we show that the total power consumption by a data center with our proposed architecture is 27 percent lower than that by data center with a conventional architecture. In addition, it is also shown that the proposed tandem equipment arrangement is suitable for obtaining high-temperature exhaust heat and decreasing the total power consumption significantly under a wider range of conditions than in the conventional equipment arrangement.
Servers, Heating, Data models, Atmospheric modeling, Computer architecture, Power demand, Computational modeling
Y. Taniguchi et al., "Tandem Equipment Arranged Architecture with Exhaust Heat Reuse System for Software-Defined Data Center Infrastructure," in IEEE Transactions on Cloud Computing, vol. 5, no. 2, pp. 182-192, 2017.