基于三阶段竞价策略的IGWO-PSO混合优化提高智能微电网弹性和虚拟电厂盈利能力

IF 3.4 3区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Access Pub Date : 2025-04-29 DOI:10.1109/ACCESS.2025.3565460

T. Yuvaraj;T. Sengolrajan;Natarajan Prabaharan;K. R. Devabalaji;Akie Uehara;Tomonobu Senjyu

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引用次数: 0

摘要

不断增长的能源需求和不断上涨的化石燃料价格正在加速向可再生能源的过渡，由于其环境和经济优势，政府倡议支持。然而，诸如容量有限和稳定性限制等挑战阻碍了分布式能源（DERs）的广泛采用。虚拟发电厂（vpp）通过聚合der来提高市场参与度，而电动汽车（ev）通过减少排放来促进环境的可持续性。此外，在vpp中集成配电静态补偿器（DSTATCOMs）可以提高微电网的稳定性和无功支持。本研究提出了一种两阶段优化方法来提高径向配电网（RDN）的网络弹性和VPP盈利能力。第一阶段侧重于在自然灾害期间最大限度地降低与弹性相关的成本和不供应能源（ENS），而第二阶段则使用三阶段投标策略（包括日前市场、实时市场和整体市场）优化VPP利润。针对这一复杂的优化问题，提出了一种改进灰狼优化-粒子群优化（IGWO-PSO）混合算法。为了验证该方法的有效性，将IGWO-PSO算法与其他混合优化算法进行了比较。在修改后的IEEE 33总线RDN上的验证证实，所提出的模型增强了VPP的位置和规模，从而改善了经济、运营和弹性指标。此外，该模型考虑了负荷需求、可再生能源发电、能源价格和设备可用性的不确定性，确保了一个强大且适应性强的能源管理策略。

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Enhancing Smart Microgrid Resilience and Virtual Power Plant Profitability Through Hybrid IGWO-PSO Optimization With a Three-Phase Bidding Strategy

The increasing energy demand and rising fossil fuel prices are accelerating the transition to renewable energy, supported by government initiatives due to their environmental and economic advantages. However, challenges such as limited capacity and stability constraints hinder the widespread adoption of distributed energy resources (DERs). Virtual Power Plants (VPPs) enhance market participation by aggregating DERs, while electric vehicles (EVs) contribute to environmental sustainability by reducing emissions. Additionally, integrating distribution static compensators (DSTATCOMs) within VPPs improves microgrid stability and reactive power support. This study proposes a two-stage optimization approach to enhance network resilience and VPP profitability in a radial distribution network (RDN). The first stage focuses on minimizing resilience-related costs and energy not supplied (ENS) during natural disasters, while the second stage optimizes VPP profit using a three-phase bidding strategy, which includes the day-ahead market, real-time market, and overall market. A hybrid improved grey wolf optimization-particle swarm optimization (IGWO-PSO) algorithm is developed to solve this complex optimization problem. To demonstrate the effectiveness of the proposed approach, IGWO-PSO is compared with other hybrid optimization algorithms. Validation on a modified IEEE 33-bus RDN confirms that the proposed model enhances VPP placement and sizing, leading to improved economic, operational, and resilience metrics. Furthermore, the model accounts for uncertainties in load demand, renewable generation, energy prices, and equipment availability, ensuring a robust and adaptable energy management strategy.

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来源期刊

IEEE Access COMPUTER SCIENCE, INFORMATION SYSTEMSENGIN-ENGINEERING, ELECTRICAL & ELECTRONIC

CiteScore

9.80

自引率

7.70%

发文量

6673

审稿时长

6 weeks

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