Data Center as a Key Player of a District Electric Power and Heat Network System: A Comparison in Urban and Suburb Regions
Data Center as a Key Player of a District Electric Power and Heat Network System: A Comparison in Urban and Suburb Regions
摘要
A DC (data center) demands air-conditioning power as large as the 1/3-1/2 of total electricity consumption. Thus, energy saving of cooling power of DC yields considerable effect on both economic and environmental views. PV (Photovoltaic) and absorption refrigerator with CGS (cogeneration systems) or gas boiler are possible power saving options. The waste warm air from DC would be utilized for greenhouse heating when DC and greenhouse locate near in the suburbs. In this study, the authors develop an energy network model to assess the potential contribution of DC as a major electric power and chilled air consumer as well as the warm air supplier in a district to the energy efficiency improvement. The evaporation heat of LNG (liquefied natural gas) utilization is also considered as well as PV, CGS. This model is applied to the cases of the urban area in Tokyo which involves athletic center, shops and hospital and the suburbs including greenhouse and then compared.
参考文献12
-
1Ministry of Internal Affairs and Communications (MIC), Report of the Task Force on IT policy in the global era, Global Problems Subgroup, 20 I O.
-
2B.D. Elieson, Ambient air cooling, The Data Center Journal[Online], June I\. 2012, http://www.datacenterjournal.com/facilities/ambient-air-c ooling/ (accessed Dec. 26, 2013).
-
3D. Magnusson, Swedish district heating-A system in stagnation: Current and future trends in the district heating sector, Energy Policy 48 (2012) 449-459.
-
41. Schmidt, M. Schoenhart, M. Biberacherm T. Guggenberger, S. Hausl, G. Kalt, et al, Regional energy autarky: Potential, costs and consequences for an Austrian region, Energy Policy 47 (2012) 211-221.
-
5K. Holmgren, S. Arniri, Internalizing external costs of electricity and heat production in a municipal energy system, Energy Policy 35 (2007) 5242-5253.
-
6M. Beercpoot, N. Beerepoot, Government regulation as an impetus for innovation: Evidence from energy performance regulation in the Dutch residential building sector, Energy Policy 35 (2007) 4812-4825.
-
71. Baker, New technology and possible advances in energy storage, Energy Policy 36 (2008) 4368-4873.
-
8V2G, Energy Policy 36 (2008) 3578-3587.
-
9M. Welsch, M. Howells, M. Bazilian, J.F. DeCarolis, S. Hermann, H.H. Regner, Modeling elements of Smart Grids-Enhancing the OSeMOSYS (Open Source Energy Modelling System) code, Energy 46 (2012) 337-350.
-
10T. Isida, S. Mori, Integrated assessment model for urban energy network system, in: Proceeding of 22th International Conference on Informatics for Environmental Protection, Shaker Verlag, Germany, 2008, pp.132-141.
-
1王新元,程瑞端,沈炳耘,李时东.多路温度采集仪器的标定与数据分析[J].仪器仪表与分析监测,2006(4):26-28. 被引量:3
-
2曹会会,曹燕燕.165MW机组热网系统改造及逻辑设计[J].制造业自动化,2015,37(21):107-110.
-
3洪元柏.冷热电联产模式及制冷机的选择[J].广东土木与建筑,2005,12(8):18-19.
-
4Yao Huannian,Cao Meiyue(Xiamen Electric Power Administration, Xiamen).The Optimization on Operation Characteristicsof Urban Medium Voltage Network[J].Electricity,1998(3):27-29.
-
5曹宇,田思庆,樊爽,郑家风.GPRS技术在城市热网远程监控系统的研究与应用[J].山西电子技术,2017(1):90-92.
-
6孟涛.热电冷联产的可行性[J].中国电力企业管理,2002(7):67-67. 被引量:2
-
7赵立.热力管道热损失的控制[J].节能,1997(10):32-35. 被引量:1
-
8高明.智能化监控与分布式变频技术在大型热网系统中的应用与研究[J].电子技术与软件工程,2015(23):125-125. 被引量:1
-
9彭长青,李鸣,王寒栋,候志坚,曾小红.基于虚拟仪器技术的冷热复合机测控系统的设计研究[J].南昌大学学报(工科版),2007,29(2):113-117. 被引量:5
-
10王长庆,贾捷燕.神经网络在燃气溴化锂吸收式机组性能模拟中的应用[J].制冷与空调,2008,8(1):49-52. 被引量:1
