Abstract
The integration of energy internet (EI) and electric power system has a profound influence on electric power system planning. Therefore, this paper mainly resolves the EI-oriented multi-stage generation and transmission coordinated planning problem with a modified fireworks algorithm. Firstly, we combined with Stackelberg game theory and focused on subject game theory, system low carbon characteristic and renewable energy generation, a multi-stage generation and transmission coordinated planning model for electric power system is proposed. The model has a main objective function of maximizing the social welfare and two secondary objective functions of maximizing individual profits in the operation stage and maximizing overall profits of generation companies in the planning stage. Then, a modified fireworks algorithm (MFWA) is proposed with good expandability, convergence and adaptability to solve the problem. The MFWA is modified by introducing Gaussian Mutation to improve global search capability. The basic coding method and solution procedure of the MFWA are depicted. Finally, an improved IEEE-24 bus system is used to test the proposed planning method and MFWA. By comparing three scenarios and analysing results, we can verify the validity and feasibility of the proposed method.
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References
Vinasco, G., Rider, M.J., Romero, R.: Multi-stage planning of distribution networks with application of multi-objective algorithm accompanied by DEA considering economical, environmental and technical improvements. J. Circ. Syst. Comput. 25(04), 1650025 (2016)
Vinasco, G., Rider, M.J., Romero, R.: A strategy to solve the multistage transmission expansion planning problem. IEEE Trans. Power Syst. 26(4), 2574–2576 (2011)
Hinojosa, V.H., Galleguillos, N., Nuques, B.: A simulated rebounding algorithm applied to the multi-stage security-constrained transmission expansion planning in power systems. Electr. Power Energy Syst. 47(1), 168–180 (2013)
Kamyab, G.-R., Fotuhi-Firuzabad, M., Rashidinejad, M.: A PSO based approach for multi-stage transmission expansion planning in electricity markets. Electr. Power Energy Syst. 54(1), 91–100 (2014)
Ravadanegh, S.N., Roshanagh, R.G.: On optimal multistage electric power distribution networks expansion planning. Electr. Power Energy Syst. 54(1), 487–497 (2014)
Nejadfard-Jahromi, S., Rashidinejad, M., Abdollahi, A.: Multistage distribution network expansion planning under smart grids environment. Int. J. Electr. Power Energy Syst. 71, 222–230 (2015)
Liu, L., Cheng, H.Z., Yao, L.Z., Ma, Z.L., Bazargan, M.: Multi-objective multi-stage transmission network expansion planning considering life cycle cost and risk value under uncertainties. Int. Trans. Electr. Energy Syst. 23(3), 438–450 (2013)
Maghouli, P., Hosseini, S.H., Buygi, M.O., Shahidehpour, M.: A scenario-based multi-objective model for multi-stage transmission expansion planning. IEEE Trans. Power Syst. 26(1), 470–478 (2011)
Saboori, H., Hemmati, R., Abbasi, V.: Multistage distribution network expansion planning considering the emerging energy storage systems. Energy Convers. Manag. 105, 938–945 (2015)
Shen, X., Shahidehpour, M., Zhu, S., Han, Y., Zhen, J.: Multi-stage planning of active distribution networks considering the co-optimization of operation strategies. IEEE Trans. Smart Grid 99, 1–1 (2017)
Zhang, X., Li, J., Fu, H.: Distribution power & energy internet: from virtual power plants to virtual power system. Proc. CSEE 35(14), 3532–3540 (2015)
Shiming, T., Wenpeng, L., Dongxia, Z., et al.: Technical forms and key technologies on energy internet. Proc. CSEE 35(14), 3482–3494 (2015)
You, S., Lin, J., Hu, J., et al.: The danish perspective of energy internet: from service-oriented flexibility trading to integrated design, planning and operation of multiple cross-sectoral energy systems. Proc. CSEE 35(14), 3470–3481 (2015)
Ming, Z., Yongqi, Y., Dunnan, L., et al.: “Generation-grid-load-storage” coordinative optimal operation mode of energy internet and key technologies. Power Syst. Technol. 40(1), 114–124 (2016)
Arefifar, S.A., Mohamed, Y.A.I., El-Fouly, T.H.M.: Supply-adequacy-based optimal construction of microgrids in smart distribution systems. IEEE Trans. Smart Grid 3(3), 1491–1502 (2012)
He, Z., Jianyun, X.: Wind farm output forecast based on combined GM-WEIBULL wind speed distribution models. East China Electr. Power 36(11), 144–146 (2008)
Tan, Y., Zheng, S.: Recent advances in fireworks algorithm. CAAI Trans. Intell. Syst. 9(5), 515–528 (2014). (in Chinese)
Romero, R., Rochac, C., Mantovani, J.R.S.: Constructive heuristic algorithm for the DC model in network transmission expansion planning. IEE Proc. 152(2), 277–282 (2005)
Zeng, M., Chunquan, L., Qiu, L., Tian, K.: A demand-side response-based transmission planning model with grid-connected wind farms. Power Syst. Technol. 35(4), 129–134 (2011)
Gao, C., Wu, T., He, Y., Hu, R.: Generation and transmission coordinated planning considering wind power integration. Autom. Electr. Power Syst. 36(22), 30–35 (2012)
Liu, Y., Xiao, X., Liu, X., Wang, Y.: Optimal configuration of DVR in premium power park considering customers’ quantitative demand. Power Syst. Technol. 39(3), 823–828 (2015)
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The work described in this paper was supported by National Natural Science Foundation of China (71401055), Beijing Social Science Fund (15JDJGB034).
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Liu, D., Ouyang, S., Ge, R. et al. Multi-stage generation and transmission coordinated planning method with a modified fireworks algorithm facing to energy internet. Cluster Comput 22 (Suppl 4), 8985–8997 (2019). https://doi.org/10.1007/s10586-018-2034-1
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DOI: https://doi.org/10.1007/s10586-018-2034-1