A COLLABORATIVE OPTIMIZATION MODEL FOR INTERACTIVE RESPONSE OF COOLING, HEATING, AND ELECTRIC FLEXIBLE LOADS IN NEAR ZERO CARBON PARKS

Liu Guowei, Dai Hao, Wu Jiekang, Kan Dongwang, Deng Hao, and Wang Liming

References

1. [1] K. Majumdar, P.K. Roy, and S. Banerjee, Framework ofhybrid renewable energy with conventional power generationscheduling using novel metaheuristic optimization algorithm,International Journal of Power and Energy Systems, 42(10),2022, 1–11.
2. [2] W. Mao, S. Yang, and X. Gao, Modelling and optimization ofgreen energy systems based on complementary integration ofrenewable energy, International Journal of Power and EnergySystems, 44(10), 2024, 1–9.
3. [3] J. Wang, L. Valentin, C. Bovo, N. Xie, and Y. Wang, Optimalself-scheduling for a multi-energy virtual power plant providingenergy and reserve services under a holistic market framework,Energy, 278, 2023, 127903
4. [4] Y. Li, S. Miao, S. Zhang, B. Yin, X. Luo, M. Dooner, and J.Wang. A reserve capacity model of AA-CAES for power systemoptimal joint energy and reserve scheduling, InternationalJournal of Electrical Power & Energy Systems, 104, 2019,279–290
5. [5] S. Zalzar, E. Bompard, A. Purvins, and M. Masera, Theimpacts of an integrated European adjustment market forelectric under high share of renewables, Energy Policy, 136,2020, 111055
6. [6] Z. Guoguang, Problem identification and key measures tosupport the achievement of carbon peak and carbon neutrality,Electric Power, 56(11), 2023, 1–8
7. [7] Q. Ziqing, Study on the Modeling and Optimization Methodsfor the Selection of Electricity Substitution Technologies,Dissertation Submitted to Shanghai Jiao Tong University,Shanghai, 2016.
8. [8] Z. Haoran, Optimal Configuration of Hybrid Heat-ElectricityCom-Plementary Heating System Oriented to Electricity Sub-stitution, Ph.D. Dissertation, Zhejiang University, Hangzhou,2022.
9. [9] J. Zhang, H. Li, W. Li, H. Zhang, and B. Wang, Discussionon the pathways of China’s electrification polices to pursuethe carbon neutralization target, Electric Power Construction,43(9), 2022, 47–53
10. [10] Y. Liang, Research on potential forecasting and optimisationmanagement of electric energy substitution in Beijing-Tianjin-Hebei Region, Ph.D. dissertation, North China Electric PowerUniversity, Beijing, 2019.
11. [11] H. Chen, S. Liu, and Y. Kuang Decomposition analysis onfactors affecting electric energy replacement in Guangdongprovince, China, IET Cyber-Physical Systems: Theory &Applications, 2023, (in press).
12. [12] W. Meng, G. Kiesewetter, S. Zhang, W. Sch¨opp, P. Rafaj,Z. Klimont, and S. Tao, Costs and benefits of householdfuel policies and alternative strategies in the Jing-Jin-JiRegion, Environmental Science & Technology, 57, 2023,21662–21672.
13. [13] W. Guan, The study on the comprehensive benefits analysis andoptimisation model for electric power alternative consideringgeneration side and customer side, Ph.D. dissertation, NorthChina Electric Power University, Baoding, 2017.
14. [14] J. Shenyu, Research on the impact of emerging electric powersubstitution on power grid, Ph.D. dissertation, North ChinaElectric Power University, Baoding, 2019.
15. [15] W. Yanqing, W. Xiao, and C. Ruochen, Charging guidancestrategy of traveling electric vehicle considering the operationsafety of distribution network, High Voltage Engineering, 49(5),2023, 2131–2139.
16. [16] L. Ran, M. Huizhuo, and Z. Jinyao, Multi-objectiveoptimization for DG integration into distribution system.Electric Power Automation device, 34(1), 2014, 6–13.
17. [17] Y. Xiangwu, W. Qingao, and L. Junda, Microgrid energyscheduling with electric vehicles and flexible loads, PowerSystem Protection and Control, 51(17), 2023, 69–79.
18. [18] M.A. Yue, M. Runquan, and L.I. Tingting, Robust OptimalDispatch of Microgrid Considering Flexible Loads andStep Carbon Trading, Modern Electric Power, 41, 2024,258–268.
19. [19] Z. Xinhe, X. Junjie, and H. Guixiong, Economical andoptimal operation of rural electric heating multi-energy systemconsidering flexible load, Global Energy Interconnection, 6(5),2023, 501–511
20. [20] C. Zhou, J. Zheng, and S. Liu, Operation optimization of multi-district integrated energy system considering flexible demandresponse of electric and heating loads, Energies, 12(20), 2019,3831
21. [21] Z. Xiaoxun, L. Zhantian, and X. Jinfei, Optimal scheduling ofintegrated energy system with flexible load participation, ActaEnergiae Solaris Sinica, 44(9), 2023, 29–38
22. [22] C. Yiming, S. Xuan, and P. Zhiyong, Carbon emissionaccounting and low-carbon path development of typicalindustrial parks in Jiangsu province, The Administration andTechnique of Environmental Monitoring, 35(6), 2023, 1–4
23. [23] L. Yi, X. Wenjun, and T. Linlin, Research on the water networkoptimization of industrial parks under low-carbon constraints,Environmental Engineering, 41(11), 2023, 154–159
24. [24] L. Ronghui, L. Zilin, and Y. Xiu, Optimal dispatch ofcommunity integrated energy system considering user-sideflexible load, Acta Energiae Solaris Sinica, 40(10), 2019,2842–2850
25. [25] Y. Wang, Y. Wang, and Y. Huang, Optimal scheduling ofthe regional integrated energy system considering economyand environment, IEEE Transactions on Sustainable Energy,10(4), 2019, 1939–1949122
26. [26] J. Hu, Y. Wang, and L. Dong, Low carbon-oriented planningof shared energy storage station for multiple integrated energysystems considering energy-carbon flow and carbon emissionreduction, Energy, 290, 2024,1–15
27. [27] H. Wentao, W. Xiaobo, and T. Nengling, An energy cascadeutilization method for microgrid with heat and power system,Proceedings of the CSEE, 40(21), 2020, 6804–6815
28. [28] S. Chuan, W. Longjun, and X. Hailin, An interaction loadmodel and its application in microgrid day-ahead economicscheduling, Power System Technology, 40(7), 2016, 2009–2016
29. [29] M. Farivar and S.H. Low, Branch flow model: Relaxations andconvexification—Part I, IEEE Transactions on Power Systems,28(3), 2013, 2554–2564
30. [30] S. Geng, D. Niu, X. Guo, M. Chen, and C.X. Tan,Multi-objective evolutionary game of micro energy gridconsidering multi-energy flexible load scheduling, ElectricPower Construction, 41(11), 2020, 101–115
31. [31] Z. Zhenyu and L. Xia, Optimal allocation of the flexibleresources for park-level electric heating integrated energysystem considering demand response, Modern Electric Power,41(12), 2023, 1–11
32. [32] Z. Luo, J. Geng, and B. Li, Distributionally robust optimaldispatching for virtual power plants considering carbon-greencertificate trading mechanism, Electric Power Construction,44(10), 2023, 137–148
33. [33] L. Zhao, Energy Optimization Management of CCHPMicrogrid, Ph.D. Dissertation, Southeast University, Dhaka,2017.
34. [34] X. Zhou, S. Yonghui, X. Dongliang, W. Jianxi, and Z.Yongjie, Optimal configuration of energy storage for integratedregion energy system considering power/heating flexible load,Automation of Electric Power Systems, 44(2), 2020, 53–59
35. [35] W.J. Chen, G.Y. Li, T.C. Zhang, M. Zhou, and J. Wang,A scheduling approach for fuel-cell hybrid electric vehiclefleets considering carbon allowance trading, Power SystemTechnology, 47(8), 2023, 3069–3079
36. [36] L. Hu, Evaluation of Carbon Resources in Shenzhen City,Master’s Thesis,. Jilin University, Changchun, 2017
37. [37] Shenzhen Graduate School of Harbin Institute of Technology,Cushman&Wakefield Real Estate Consulting Co., Ltd.,Shenzhen Urban Planning and Design Institute (2011) Outlineof the Overall Development Plan for Shenzhen InternationalLow Carbon City. China Opening Journal, (S1):70-95

Important Links:

• Abstract
• DOI: 10.2316/J.2025.203-0556
• From Journal (203) International Journal of Power and Energy Systems - 2025

Go Back