Dynamic environmental economic dispatch of power system containing wind farms based on MO-APSO

被引：0

作者：

Tian B. ^{[1
]}

Qi H. ^{[1
]}

Zhang X. ^{[2
]}

He F. ^{[1
]}

Peng J. ^{[1
]}

Chang X. ^{[1
]}

机构：

[1] State Grid Urumqi Power Supply Company, Urumqi

[2] College of Electrical Engineering, Xinjiang University, Urumqi

来源：

Dianli Xitong Baohu yu Kongzhi/Power System Protection and Control | 2019年 / 47卷 / 24期

基金：

中国国家自然科学基金;

关键词：

Dispatching model; Dynamic environmental economic dispatch; MO-APSO; Multi-objective optimization; Optimal compromise solution; Wind power;

D O I：

10.19783/j.cnki.pspc.190139

中图分类号：

学科分类号：

摘要：

In order to comprehensively consider the impact of carbon emissions trading on wind-fire co-generation model, and based on the constraints of energy saving and emission reduction, power generation efficiency and unit operation, the carbon emission trading cost function is introduced. A multi-objective Dynamic Environmental Economic Dispatch (DEED) model of wind-fire combined power system considering generation cost, carbon trading cost and environmental cost is constructed. A multi-objective adaptive particle swarm optimization algorithm is proposed to solve the DEED problem. According to the current fitness function of particles in the optimization process, the inertia weight and learning factor are adaptively modified to further improve the premature defects and enhance the global search ability. The simulation results of 10-machine power systems with wind farms show that the proposed method can simultaneously optimize the two conflicting objectives of cost and emission, and obtain a wider and more uniform Pareto frontier than other algorithms, which can effectively reduce the carbon emissions and integrated operation costs of the combined generation system. © 2019, Power System Protection and Control Press. All right reserved.

引用

页码：57 / 64

页数：7

共 22 条

[1] Shu Y., Zhang Z., Guo J., Et al., Analysis of key factors of new energy consumption and Solutions, Proceedings of the CSEE, 37, 1, pp. 1-8, (2017)
[2] Zhao J., Hu J., Wang K., Et al., A joint optimal model of day-ahead generation dispatch and day-ahead time-sharing price, Power System Protection and Control, 47, 9, pp. 56-63, (2019)
[3] Huang Y., Xu Q., Jiang X., Et al., Low carbon power dispatching method for regional power grid with new energy access, Automation of Electric Power Systems, 42, 12, pp. 25-32, (2018)
[4] Wang Z., Liu M., Decentralized dynamic economic dispatch of microgrid using distributed simplex method, Power System Protection and Control, 46, 15, pp. 1-8, (2018)
[5] Zheng Y., Zhao J., Meng K., Et al., Stochastic optimal dispatch of power system considering carbon trading mechanism, Electric Power Construction, 38, 6, pp. 21-27, (2017)
[6] Wang T., Xu K., Zhu Y., Economic dispatching strategy of active distribution network based on source-network-load multilayer game, Power System Protection and Control, 46, 4, pp. 10-19, (2018)
[7] Xu J., Low carbon economic dispatch of wind power system based on green certificate transaction, Electric Power, 49, 7, pp. 145-150, (2016)
[8] Shan Q., Ding Y., Energy-saving dispatching optimization model of thermal power plants considering carbon trading and its response model, Electric Power Automation Equipment, 38, 7, pp. 180-186, (2018)
[9] Jiang Y., Zhang Y., Energy-saving dispatching optimization model of thermal power plants considering carbon trading and its response model, Electric Power Automation Equipment, 37, 11, pp. 20-27, (2017)
[10] Jiang X., Dynamic environmental economic dispatch using multiobjective differential evolution algorithm with expanded double selection and adaptive random restart, International Journal of Electrical Power & Energy Systems, 49, 1, pp. 399-407, (2013)

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