基于改进NSGA-II算法的电热耦合综合能源系统两阶段多目标优化协调

Na Zhang, Taozhu Feng
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引用次数: 0

摘要

随着清洁能源在综合能源系统中所占比重的不断提高,能源供应的不确定性和时空分散性日益突出。系统建模和优化调度面临着更大的挑战。针对上述问题,本文对非支配排序遗传算法(NSGA-II)进行了改进,提出了电热耦合综合能源系统的两阶段多目标效益均衡优化协调。首先,对电-热耦合能源系统的设备部件进行了热力学特性分析,反映了系统的结构特点,各设备在不同任务条件下的性能,以及系统的机理;在上述特性分析的基础上,提出了电热耦合系统优化协调的两阶段多目标优化,建立目标函数并进行各目标平衡约束;对NSGA-II算法进行了改进。根据运行阶段,通过动态调整运行阶段演化个体的运行参数、运行生成和当前临时种群中未支配个体的数量,对运行生成和NSGA-II算法进行改进。通过对算法进行自适应,提高进化算子的自适应能力,求解两步模型,得到各能源设备的Pareto最优前沿。综上所述,电力系统和热力系统耦合下的IES分析结果表明,所构建的模型和所提出的算法可以有效地提高可再生能源系统和优化决策的准确性。研究结果进一步体现了所提出的多目标优化方案在兼顾经济性、可再生能源性和复杂运行约束方面的优势,保证了系统的经济稳定运行以及最优调度的鲁棒性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Two-stage Multi-objective Optimization Coordination of Electro-thermal Coupled Integrated Energy System Based on Improved NSGA-II Algorithm
With the growing proportion of clean energy in integrated energy systems (IES), energy supply uncertainty and spatial-temporal dispersion are becoming increasingly prevalent. System modeling and optimal scheduling are facing greater challenges. In this paper, we improve the non-dominated sorting genetic algorithm (NSGA-II) to address the above problems and propose a two-stage multi-objective benefit-equilibrium optimization coordination of the electric-thermal coupled integrated energy system. Firstly, this paper carries out the thermodynamic characteristics analysis of the equipment components of the electro-thermal coupled energy system, which reflects the structural features of the system, the performance of each equipment under different task conditions, and the mechanism of the system; based on the above characteristic analysis, a two-stage multi-objective optimization of electro-thermal coupled system optimization coordination is proposed to establish the objective function and carry out each objective balance constraint; the NSGA-II algorithm is as well as improved. According to the operation stage, operation generation and the NSGA-II algorithm are improved by dynamically adjusting the operating parameters of evolving individuals of the operation stage, operational generation, and the number of undominated individuals in the current temporary population. By making the algorithm adaptation to improve the adaptive capacity of the evolution operator, we solve the two-step model and obtain the Pareto optimal front for each energy device. In summary, the results of the analysis of the IES under the coupling of power system and thermal system show that the constructed model and the proposed algorithm can effectively improve the accuracy of the renewable energy system and the optimization decision. The results of the research further reflect the benefits of the proposed multi-objective optimization scheme in accounting for economic, renewable energy, and complex operating constraints which ensure the economical and stable operation of the system, as well as the robustness of optimal scheduling.
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