A Novel Statistical Framework for Optimal Sizing of Grid-Connected Photovoltaic–Battery Systems for Peak Demand Reduction to Flatten Daily Load Profiles

Solar Pub Date : 2024-03-14 DOI:10.3390/solar4010008

Reza Nematirad, Anil Pahwa, Balasubramaniam Natarajan

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Abstract

Integrating photovoltaic (PV) systems plays a pivotal role in the global shift toward renewable energy, offering significant environmental benefits. However, the PV installation should provide financial benefits for the utilities. Considering that the utility companies often incur costs for both energy and peak demand, PV installations should aim to reduce both energy and peak demand charges. Although PV systems can reduce energy needs during the day, their effectiveness in reducing peak demand, particularly in the early morning and late evening, is limited, as PV generation is zero or negligible at those times. To address this limitation, battery storage systems are utilized for storing energy during off-peak hours and releasing it during peak times. However, finding the optimal size of PV and the accompanying battery remains a challenge. While valuable optimization models have been developed to determine the optimal size of PV–battery systems, a certain gap remains where peak demand reduction has not been sufficiently addressed in the optimization process. Recognizing this gap, this study proposes a novel statistical model to optimize PV–battery system size for peak demand reduction. The model aims to flatten 95% of daily peak demands up to a certain demand threshold, ensuring consistent energy supply and financial benefit for utility companies. A straightforward and effective search methodology is employed to determine the optimal system sizes. Additionally, the model’s effectiveness is rigorously tested through a modified Monte Carlo simulation coupled with time series clustering to generate various scenarios to assess performance under different conditions. The results indicate that the optimal PV–battery system successfully flattens 95% of daily peak demand with a selected threshold of 2000 kW, yielding a financial benefit of USD 812,648 over 20 years.

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一种新的统计框架，用于优化并网光伏电池系统的规模，以减少峰值需求，平缓日负荷曲线

光伏（PV）系统的集成在全球向可再生能源转变的过程中发挥着举足轻重的作用，并带来显著的环境效益。不过，光伏系统的安装也应为公用事业公司带来经济效益。考虑到公用事业公司通常需要为能源和高峰需求承担费用，光伏系统的安装应旨在减少能源和高峰需求费用。虽然光伏系统可以减少白天的能源需求，但其在减少高峰需求方面的效果有限，尤其是在清晨和傍晚，因为光伏发电量在这些时间段为零或可以忽略不计。为解决这一限制，可利用电池储能系统在非高峰时段储存能量，并在高峰时段释放能量。然而，找到光伏发电和配套电池的最佳规模仍然是一项挑战。虽然已经开发出有价值的优化模型来确定光伏电池系统的最佳规模，但仍存在一定的差距，即在优化过程中没有充分考虑减少峰值需求的问题。认识到这一差距后，本研究提出了一种新型统计模型，用于优化光伏电池系统规模，以减少峰值需求。该模型旨在将 95% 的日峰值需求平抑到一定的需求阈值，从而确保能源供应的稳定性，并为公用事业公司带来经济效益。该模型采用直接有效的搜索方法来确定最佳系统规模。此外，还通过改进的蒙特卡罗模拟和时间序列聚类对模型的有效性进行了严格测试，以生成各种情景，评估不同条件下的性能。结果表明，在选定的 2000 千瓦阈值下，最佳光伏电池系统可成功平抑 95% 的日峰值需求，在 20 年内产生 812,648 美元的经济效益。

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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