Implementation of demand response for a block of buildings for active participation in the electricity market

Proceedings of the 10th ACM/IEEE International Conference on Cyber-Physical Systems Pub Date : 2019-04-16 DOI:10.1145/3302509.3313326

R. Menon, F. Amblard, Jessen Page

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引用次数: 1

Abstract

There has been increased focus on improving the security and efficiency of the electricity grid resources. Many solutions have been proposed. Demand Response (DR) and Demand Side Management (DSM) are popular solutions in studies towards achieving these goals. This paper elucidates on the work being done within a Horizon 2020 (H2020) project, Sim4Blocks, funded by the EU, on the implementation of DR for a group of buildings with thermal and electric demands. The project tackles three issues that are of importance to realization of DR for end-users: (1) What hardware and communication protocols are required to ensure that existing devices (especially thermal devices) can participate in the electricity market? Would it be possible to future-proof the methodology developed? (2) How do we optimise the thermal and electric energy flows such that demand and comfort are satisfied while minimising stress in the electric grid and (3) How do we integrate the optimisation algorithms and associated software with the hardware so that the entire hardware-software framework works seamlessly. With these questions in mind, hardware, communication protocols, Domain Specific Languages (DSL) and optimisation frameworks are utilised and developed such that end-user buildings with thermal and electrical devices can participate in the electricity market. The entire framework developed is validated through demonstration on three pilot sites in three different countries with different sets of devices (Switzerland, Germany and Spain). These sites consisting of end-user buildings that have thermal and electrical devices which are conventionally found in today's market. Thus, through the development and demonstration of such a framework, Sim4Blocks is able to analyse the strengths, weaknesses and bottlenecks existing in today's devices, control methodologies and market constraints and suggest solutions to overcome them.

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对某街区建筑实施需求响应，积极参与电力市场

提高电网资源的安全性和效率受到越来越多的关注。人们提出了许多解决方案。在实现这些目标的研究中，需求响应(DR)和需求侧管理(DSM)是流行的解决方案。本文阐述了地平线2020 (H2020)项目Sim4Blocks正在进行的工作，该项目由欧盟资助，针对一组有热电需求的建筑实施DR。该项目解决了三个对最终用户实现DR至关重要的问题:(1)现有设备(尤其是热设备)能够参与电力市场，需要什么样的硬件和通信协议?是否有可能使所开发的方法经得起未来的考验?(2)我们如何优化热能和电能流动，以满足需求和舒适度，同时最大限度地减少电网中的压力;(3)我们如何将优化算法和相关软件与硬件集成，以便整个硬件-软件框架无缝地工作。考虑到这些问题，硬件、通信协议、领域特定语言(DSL)和优化框架被利用和开发，这样带有热电设备的终端用户建筑就可以参与电力市场。开发的整个框架通过在三个不同国家(瑞士、德国和西班牙)使用不同设备的三个试验点进行演示来验证。这些场所由终端用户建筑组成，这些建筑有热和电气设备，这些设备在今天的市场上通常可以找到。因此，通过这种框架的开发和演示，Sim4Blocks能够分析当今设备，控制方法和市场约束中存在的优势，劣势和瓶颈，并提出克服它们的解决方案。

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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Proceedings of the 10th ACM/IEEE International Conference on Cyber-Physical Systems

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