Methodology for EBSILON simulation studies of on-site generation CHP systems for data centre

2016 International Energy and Sustainability Conference (IESC) Pub Date : 2016-06-01 DOI:10.1109/IESC.2016.7569490

V. Rudolf, Nirendra Lal Shrestha, T. Urbaneck, N. Pflugradt, B. Platzer, Òscar Càmara, A. Carrera, J. Salom, E. Oro, Albert García, M. Timmerman, Hans Trapman

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引用次数: 1

Abstract

The use of information technology services is increasing and causes a rising energy demand of data centres. In order to cover the requirements linked to this effect and respond to the energetic and environmental goals, fossil fuels need to be replaced by renewable energy sources, and methods to increase the efficiency of the processes have to be developed. Regarding the energy supply of data centres, the complex integration of different energy systems into the technical infrastructure of the data centres is challenging. Within the RenewIT project [1], fourteen thermal and electrical power supply concepts for data centres have been investigated [2]. Regarding intermediate results of the project, the four concepts with combined heat and power production (CHP) provide the most promising solutions. One of the concepts with CHP, the system biogas-fed solid oxide fuel cell (SOFC), is presented to show the methodology of modelling and simulating the CHP subsystem including non-series products with EBSILON [3]. The complex part load behaviour of the subsystem is identified and the information is transferred into TRNSYS [4] to increase data processing and minimize computing time.

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数据中心现场发电热电联产系统的EBSILON模拟研究方法

信息技术服务的使用越来越多，导致数据中心的能源需求不断上升。为了满足与这一影响有关的需要和对能源和环境目标作出反应，必须用可再生能源取代矿物燃料，并必须发展提高这一过程效率的方法。关于数据中心的能源供应，将不同的能源系统复杂地集成到数据中心的技术基础设施中是一项挑战。在RenewIT项目[1]中，研究了数据中心的14种热力和电力供应概念[2]。从项目的中期结果来看，热电联产(CHP)的四个概念提供了最有前途的解决方案。热电联产的概念之一，系统沼气固体氧化物燃料电池(SOFC)，展示了建模和模拟热电联产子系统的方法，包括EBSILON的非系列产品[3]。识别子系统的复杂零件载荷行为，并将信息传输到TRNSYS[4]中，以增加数据处理并最小化计算时间。

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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2016 International Energy and Sustainability Conference (IESC)

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