Modelling and valuing multi-energy flexibility from community energy systems

2017 Australasian Universities Power Engineering Conference (AUPEC) Pub Date : 2017-11-01 DOI:10.1109/AUPEC.2017.8282399

Han Wang, N. Good, P. Mancarella

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引用次数: 6

Abstract

Demand side response is seen as an important resource to provide flexibility into to the grid. This paper presents a smart community optimization model, implemented using a mixed integer linear programming technique, which is based upon physical models of the building, battery energy storage, thermal energy storage, and energy conversion devices. Various sources of flexibility, including battery energy storage, thermal energy storage, and building thermal storage, have been assessed applying different objectives. Analyses of community operational behavior and of annual cash flows are carried out to understand the benefit and feasibility of different flexibility options under both cost minimization and electricity self-sufficiency objectives. Among all the flexibility options, battery energy storage can bring the greatest operational revenue to the community, under a cost minimization objective. In contrast, electricity self-sufficiency might not be attractive to consumers and communities who would like to ‘leave the grid’, as it may lead to significant revenue losses.

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建模和评估社区能源系统的多能源灵活性

需求侧响应被视为为电网提供灵活性的重要资源。本文提出了一个基于建筑、电池储能、热能存储和能量转换设备的物理模型，采用混合整数线性规划技术实现的智能社区优化模型。各种灵活性的来源，包括电池储能、热能存储和建筑热存储，已经应用不同的目标进行了评估。对社区运营行为和年度现金流进行分析，以了解在成本最小化和电力自给自足目标下不同灵活性方案的效益和可行性。在所有灵活性选项中，在成本最小化的目标下，电池储能可以为社区带来最大的运营收入。相比之下，电力自给自足可能对那些想要“离开电网”的消费者和社区没有吸引力，因为它可能导致重大的收入损失。

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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2017 Australasian Universities Power Engineering Conference (AUPEC)

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