Design and Realization of Integrated Energy System Dynamic Stability Simulation and Steady-state Simulation System

被引：0

作者：

He, Guixiong ^{[1
]}

Jia, Xiaoqiang ^{[1
]}

Dong, Shufeng ^{[2
]}

Han, Yonglu ^{[3
]}

Chen, Yonghua ^{[4
]}

Zheng, Yiming ^{[2
]}

机构：

[1] China Electric Power Research Institute, Beijing

[2] Zhejiang University, Hangzhou

[3] State Grid Hebei Electric Power Co., Ltd., Marketing Service Center, Nanjing

[4] Nanrui Group Research Institute, Nanjing

来源：

Xitong Fangzhen Xuebao / Journal of System Simulation | 2025年 / 37卷 / 05期

关键词：

communication interface; digital-physical hybrid; energy flow optimization; integrated energy; online access; simulation platform;

D O I：

10.16182/j.issn1004731x.joss.24-0701

中图分类号：

学科分类号：

摘要：

Aiming for “carbon peak”and “carbon neutrality”, the energy sector is undergoing significant reform. To address energy flow and planning optimization in integrated energy systems, a comprehensive simulation platform is developed. This platform combines physical and digital simulations with real-world validation and is modular in design, It includes an integrated energy model library, energy flow optimization, modeling management, real-time simulation, and energy monitoring. The platform enhances system safety, stability, and economic efficiency, While also improving planning and energy management. The paper analyzes the platform′s functional and physical architecture, introduces key modules, establishes dynamic and steady-state model libraries, and optimizes energy flow using multi-objective particle swarm optimization. Simulations conducted for typical campus scenarios validate the system model′s effectiveness. © 2025 Acta Simulata Systematica Sinica. All rights reserved.

引用

页码：1103 / 1115

页数：12

共 23 条

[1]

Zhu Han, Study on Operational Strategy Optimization of Distributed Energy System Based on the Development of DER-CAM, (2015)

[2]

Sun Hongbin, Guo Qinglai, Pan Zhaoguang, Et al., Energy Internet: Driving Force, Review and Outlook, Power System Technology, 39, 11, pp. 3005-3013, (2015)

[3]

Peng Ke, Zhang Cong, Xu Bingyin, Et al., Status and Prospect of Pilot Projects of Integrated Energy System with Multi-energy Collaboration, Electric Power Automation Equipment, 37, 6, pp. 3-10, (2017)

[4]

Hou Furui, Wang Xiuli, Suo Tao, Et al., Capacity Market Design in the United Kingdom and Revelation to China's Electricity Market Reform, Automation of Electric Power Systems, 39, 24, pp. 1-7, (2015)

[5]

Shi Shanshan, Su Yirong, Gai Chuanyue, Scheme for Low-carbon Energy Management System in Intelligent Community, East China Electric Power, 42, 12, pp. 2918-2921, (2014)

[6]

Jia Hongjie, Mu Yunfei, Yu Xiaodan, Thought About the Integrated Energy System in China, Electric Power Construction, 36, 1, pp. 16-25, (2015)

[7]

Wu Jianzhong, Drivers and State-of-the-art of Integrated Energy Systems in Europe, Automation of Electric Power Systems, 40, 5, pp. 1-7, (2016)

[8]

Wang Yudong, Hu Junjie, Peer-to-peer Energy-carbon Management Method of Multiple Integrated Energy Systems Considering Multi-agent Interaction Strategy, Journal of System Simulation, 36, 10, pp. 2488-2502, (2024)

[9]

Ma Lixin, Cheng Ying, Optimal Operation for Park Integrated Energy System Considering Interruptible Loads, Journal of System Simulation, 34, 4, pp. 817-825, (2022)

[10]

He Li, Research on Energy Optimization Dispatching of Grid-connected Microgrid Based on Demand Side Response, (2019)

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