Smart Sustainable LV Networks providing Ancillary Services under Uncertainty: A Joint Chance-Constrained Model

2022 IEEE Power & Energy Society General Meeting (PESGM) Pub Date : 2022-07-17 DOI:10.1109/PESGM48719.2022.9916793

Iason I. Avramidis, F. Capitanescu, G. Deconinck

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Abstract

In response to European sustainability directives, a rapid growth of smart sustainable buildings (SSBs) is expected in the coming years, particularly in low voltage (LV) networks. This opens up new pathways towards exploiting SSB-driven flexibility for the provision of upstream ancillary services (AS). However, tapping into these resources is contingent on properly dealing with the inherent end-user uncertainty. In that light, this work proposes a detailed mixed-integer nonlinear, joint chance-constrained optimization framework that coordinates SSBs in order to provide voltage and congestion support AS at the MV-LV interface. The sources of intractability (AS model, network nonlinearity, uncertainty) are linearly re-formulated, comprising a mixed-integer linear optimization model. Building on previous work, the proposed operational planning framework limits the occurrence of technical violations, so as to allow the LV network to dedicate all available resources exclusively towards providing AS support to the MV network, in real-time. The model's validity and performance are evaluated on a real Luxembourgian LV grid, assumed to host a significant number of residential SSBs.

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不确定性下提供辅助服务的智能可持续LV网络:联合机会约束模型

为了响应欧洲的可持续发展指令，智能可持续建筑(SSBs)预计将在未来几年快速增长，特别是在低压(LV)网络中。这为利用ssb驱动的灵活性提供上游辅助服务(AS)开辟了新的途径。然而，能否利用这些资源取决于能否正确处理终端用户固有的不确定性。鉴于此，本工作提出了一个详细的混合整数非线性、联合机会约束优化框架，该框架协调ssb，以便在pv - lv接口提供电压和拥塞支持AS。对难解性的来源(AS模型、网络非线性、不确定性)进行线性重新表述，构成一个混合整数线性优化模型。在之前工作的基础上，拟议的运营规划框架限制了技术违规的发生，从而允许低压网络将所有可用资源专门用于实时向中压网络提供as支持。该模型的有效性和性能在一个真实的卢森堡LV网格上进行了评估，假设该网格拥有大量的住宅ssb。

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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2022 IEEE Power & Energy Society General Meeting (PESGM)

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