Heat market for interconnected multi-energy microgrids: A distributed optimization approach

IF 8 Q1 ENERGY & FUELS
Alvaro Gonzalez-Castellanos , Aldo Bischi
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引用次数: 0

Abstract

Thermal networks, part of heat-and-power multi-energy microgrids, may face capacity issues, generation and distribution ones, either due to the increase in the requested demand or capacity underused, which is sized for peak hours. Under-capacity issues may be addressed with generation and pipeline capacity expansion, resulting in considerable capital costs and extra maintenance costs. In the case of over-capacity, better usage of the existing assets may bring further revenues and increase the multi-energy microgrid’s overall energy efficiency. In the electricity sector, it is being considered the interconnection of microgrids via the distribution system network, since microgrids can operate in both islanded and network-connected modes. In this work, in a similar fashion, we propose the interconnection of adjacent thermal networks enabling direct heat trading among them to increase the micro-grids’ supply flexibility, help meeting demand peaks, and reduce operational costs. Examples of integrated heat-and-power microgrids that could benefit from thermal interconnections are industrial parks, university campuses, hospitals, and even residential complexes with a shared heat generator.

This paper presents a market model for the optimal heat transfer between thermally interconnected heat-and-power microgrids. The resulting model is a convex quadratic programming model that enables the derivation of heat transfer prices that guarantee a competitive equilibrium. Furthermore, we performed numerical tests to explore the impact of connection topology, thermal power transfer capacity, and interconnection efficiency on transferred energy and prices.

互联多能源微电网的供热市场:分布式优化方法
热网作为热电多能微电网的一部分,可能会面临发电和配电容量问题,原因可能是需求增加,也可能是容量使用不足,只适合高峰时段使用。容量不足的问题可以通过扩大发电和输电容量来解决,这将导致相当大的资本成本和额外的维护成本。在容量过剩的情况下,更好地利用现有资产可带来更多收入,并提高多能源微电网的整体能效。在电力行业,人们正在考虑通过配电系统网络实现微电网的互联,因为微电网既可以以孤岛模式运行,也可以以网络连接模式运行。在这项工作中,我们以类似的方式提出了相邻热网的互联,使它们之间能够直接进行热量交易,从而提高微电网的供应灵活性,帮助满足需求高峰,并降低运营成本。可以从热互联中受益的热电一体化微电网包括工业园区、大学校园、医院,甚至有共享热发电机的住宅小区。由此产生的模型是一个凸二次编程模型,可以推导出保证竞争性均衡的换热价格。此外,我们还进行了数值测试,以探讨连接拓扑结构、热功率传输能力和互联效率对传输能量和价格的影响。
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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来源期刊
Energy nexus
Energy nexus Energy (General), Ecological Modelling, Renewable Energy, Sustainability and the Environment, Water Science and Technology, Agricultural and Biological Sciences (General)
CiteScore
7.70
自引率
0.00%
发文量
0
审稿时长
109 days
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