Multi-objective optimization design and multi-attribute decision-making method of a distributed energy system based on nearly zero-energy community load forecasting

Currently, many scholars have researched distributed energy systems (DES) from different dimensions. However, the load forecasting on both source-side and load-side, the optimal design of DES, and the multi-attribute decision making need further research. Therefore, a novel DES combining solar photo...

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Bibliographic Details
Published in:Energy (Oxford) 2022-01, Vol.239, p.122124, Article 122124
Main Authors: Guo, Jiacheng, Zhang, Peiwen, Wu, Di, Liu, Zhijian, Liu, Xuan, Zhang, Shicong, Yang, Xinyan, Ge, Hua
Format: Article
Language:English
Subjects:
Cluster analysis
Clustering
Decision making
Decision theory
Design
Design optimization
Distributed energy system
Economic forecasting
Electrical loads
Energy
Energy storage
Energy utilization
Entropy
External energy dependence
Forecasting
Hybrid energy storage
Load forecasting
Monte Carlo simulation
Multiple objective analysis
Photovoltaics
Solar energy
Solar fraction
Solar photovoltaic
Vector quantization
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Summary:Currently, many scholars have researched distributed energy systems (DES) from different dimensions. However, the load forecasting on both source-side and load-side, the optimal design of DES, and the multi-attribute decision making need further research. Therefore, a novel DES combining solar photovoltaic and hybrid energy storage is proposed. Combining the Monte Carlo method and improved K-means clustering is presented to predict the load on the source-side and load-side. Then, an optimal design method considering system independence and solar energy utilization scale is proposed, and the novel system is optimized. The entropy method and TOPSIS method are combined to make the multi-attribute decision on the optimization results of the system. The novel system is used to supply energy to nearly zero-energy communities (NZEC) in different scenarios. The research results show that the proposed load forecasting method can more accurately reflect the actual load demand of users. When “cost - external energy dependence - solar fraction” is taken as the target, the comprehensive energy import rate with nearly zero-energy office communities is only 36.7%, showing excellent independence. Finally, this paper can provide a method for load forecasting of NZECs, and provide certain theories for the optimization and decision-making of DESs. •A load forecasting method considering the source-side and load-side was proposed.•A DES considering solar PV, HES, and EV was proposed.•An optimization method considering different optimization objectives was proposed.•A decision-making method combining the entropy method and the TOPSIS method was proposed.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2021.122124