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Collaborative Research: Stability, security and emergency control for reconfigurable networked microgrids

合作研究：可重构网络微电网的稳定性、安全性和应急控制

基本信息

批准号：
1809314
负责人：
Jean-Jacques Slotine
金额：
$ 20万
依托单位：
Massachusetts Institute of Technology
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2018
资助国家：
美国
起止时间：
2018-09-01 至 2021-08-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1809314&HistoricalAwards=false
关键词：
Collaborative Research Stability security emergency

项目摘要

Networked microgrids (NMG, e.g., interconnections of house or district level microgrids powered by a solar panel or wind turbine) are increasingly utilized for sharing resources among microgrids, which can offer significant economic benefits. However, there is a poorly understood trade-off between robustness and fragility in this network setting. On one hand, the interconnection of multiple individual microgrids can improve the robustness of the microgrid network since the increased aggregate inertia will allow for better rejection of relatively small disturbances like load and renewable generation changes or minor load/generator outages. On the other hand, the interconnection will also extend the electrical and operational couplings between individual microgrids and lead to more routes of cascading failures (for example, a local failure of any microgrid can propagate throughout the network and threaten the whole network fragility). The project will make contributions in: (i) development of high-fidelity models of networked microgrids, bringing a new application domain to dynamics analysis and controls; (ii) development of computationally tractable optimization algorithms to solve the stability constrained optimal power flow problems involved in the analysis of the control actions; (iii) introduction of innovative network reconfiguration and intentional islanding algorithms to enhance networked microgrids resilience, which can inform innovations in risk mitigation of other complex networks. In the broader contexts, this project can help protecting critical infrastructures, e.g., airports, hospitals, buildings, during prolonged power outages due to natural disasters or cyberphysical attacks. Aiming to fill the knowledge gap, this project will investigate intricate aspects of the robustness-fragility trade-off in networked microgrids. This knowledge then allows for the synthesis and validation of integrated preventive-corrective operational strategies that achieve the optimal compromise between overall robustness and fragility. Technically, we will analyze independently two complementary preventive-corrective strategies for ensuring the security of the NMG system with respect to the most common faults. Analyzing the cost-risk tradeoff of these two control actions will then lead to an optimal integration of preventive and corrective strategies into NMG operations.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

网络微电网（NMG，例如，由太阳能电池板或风力涡轮机供电的家庭或地区级微电网的互连）越来越多地用于微电网之间的资源共享，这可以提供显着的经济效益。然而，在这种网络环境中，鲁棒性和脆弱性之间的权衡很难被理解。一方面，多个独立微电网的互连可以提高微电网网络的鲁棒性，因为增加的总惯性将允许更好地拒绝相对较小的干扰，如负载和可再生能源发电变化或较小的负载/发电机停机。另一方面，互联也将扩展单个微电网之间的电气和运行耦合，并导致更多的级联故障路径（例如，任何微电网的局部故障都可能传播到整个网络并威胁到整个网络的脆弱性）。该项目将在以下方面作出贡献：(i)开发网络化微电网的高保真模型，为动态分析和控制带来新的应用领域；（ii）发展计算上易于处理的优化算法，以解决控制行为分析中涉及的稳定约束最优潮流问题；（三）采用创新的网络重新配置和有意孤岛算法，以增强联网微电网的复原力，这可以为其他复杂网络的风险缓解创新提供信息。在更广泛的背景下，该项目可以帮助保护关键基础设施，如机场、医院、建筑物，在因自然灾害或网络物理攻击而导致的长时间停电期间。为了填补知识空白，该项目将研究网络微电网稳健性与脆弱性权衡的复杂方面。然后，这些知识允许综合和验证综合预防纠正操作策略，从而在整体稳健性和脆弱性之间实现最佳折衷。在技术上，我们将独立分析两种互补的预防纠正策略，以确保NMG系统针对最常见故障的安全性。分析这两种控制措施的成本风险权衡，将有助于将预防和纠正策略最佳地整合到NMG作业中。该奖项反映了美国国家科学基金会的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。