A graph theory-based optimal planning method for energy supply networks in an integrated energy system
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F. Luo | Jizhong Zhu | Chen He | Yun Liu | Yanjiang Li | Linying Huang
[1] Qiuwei Wu,et al. Optimal planning of local biomass-based integrated energy system considering anaerobic co-digestion , 2022, Applied Energy.
[2] W. Yao,et al. A low-carbon planning method for joint regional-district multi-energy systems: From the perspective of privacy protection , 2022, Applied Energy.
[3] Wei Sun,et al. Low-carbon economic planning of integrated electricity-gas energy systems , 2022, Energy.
[4] Fugui Dong,et al. Multi-objective planning of regional integrated energy system aiming at exergy efficiency and economy , 2022, Applied Energy.
[5] Lei Wu,et al. A multi-agent game based joint planning approach for electricity-gas integrated energy systems considering wind power uncertainty , 2021, Electric Power Systems Research.
[6] Yongli Wang,et al. Multi-objective synergy planning for regional integrated energy stations and networks considering energy interaction and equipment selection , 2021, Energy Conversion and Management.
[7] Hongjie Jia,et al. Multi-stage stochastic planning of regional integrated energy system based on scenario tree path optimization under long-term multiple uncertainties , 2021 .
[8] A. R. Ghahnavieh,et al. A comprehensive framework for optimal planning of competing energy hubs based on the game theory , 2021 .
[9] J. Qiu,et al. Carbon Emission Flow Oriented Tri-Level Planning of Integrated Electricity–Hydrogen–Gas System with Hydrogen Vehicles , 2021, IEEE Transactions on Industry Applications.
[10] Amin Safari,et al. A multi-objective mixed integer linear programming model for integrated electricity-gas network expansion planning considering the impact of photovoltaic generation , 2021 .
[11] Zhongfu Tan,et al. Cost-based siting and sizing of energy stations and pipeline networks in integrated energy system , 2021 .
[12] Qinglai Guo,et al. A Conditional Value-at-Risk Based Planning Model for Integrated Energy System with Energy Storage and Renewables , 2021, Applied Energy.
[13] Zhaohong Bie,et al. Co-optimization planning of integrated electricity and district heating systems based on improved quadratic convex relaxation , 2021 .
[14] Nan Zheng,et al. Synergy planning for integrated energy stations and pipe networks based on station network interactions , 2021 .
[15] Yunfei Mu,et al. A double-layer planning method for integrated community energy systems with varying energy conversion efficiencies , 2020 .
[16] Yunfei Zheng,et al. The optimal configuration planning of energy hubs in urban integrated energy system using a two-layered optimization method , 2020 .
[17] Fuwei Zhang,et al. Research on capacity planning and optimization of regional integrated energy system based on hybrid energy storage system , 2020 .
[18] Lin Lu,et al. A novel optimal configuration model for a zero-carbon multi-energy system (ZC-MES) integrated with financial constraints , 2020 .
[19] Xiaoou Liu,et al. Energy stations and pipe network collaborative planning of integrated energy system based on load complementary characteristics , 2020 .
[20] Yang Lei,et al. Multi-objective stochastic expansion planning based on multi-dimensional correlation scenario generation method for regional integrated energy system integrated renewable energy , 2020, Applied Energy.
[21] Xu Wang,et al. Bi-level planning for integrated electricity and natural gas systems with wind power and natural gas storage , 2020 .
[22] Heng Zhang,et al. Multi-objective planning for integrated energy systems considering both exergy efficiency and economy , 2020 .
[23] Sitong Zhu,et al. Novel planning methodology for energy stations and networks in regional integrated energy systems , 2020 .
[24] Wei Gu,et al. Optimal Planning for Electricity-Hydrogen Integrated Energy System Considering Power to Hydrogen and Heat and Seasonal Storage , 2020, IEEE Transactions on Sustainable Energy.
[25] Shengwei Mei,et al. Capacity Planning of Energy Hub in Multi-Carrier Energy Networks: A Data-Driven Robust Stochastic Programming Approach , 2020, IEEE Transactions on Sustainable Energy.
[26] Yingying Chen,et al. A Graph Theory-Based Method for Regional Integrated Energy Network Planning: A Case Study of a China–U.S. Low-Carbon Demonstration City , 2019 .
[27] Jiefeng Hu,et al. Game-theoretic planning for integrated energy system with independent participants considering ancillary services of power-to-gas stations , 2019, Energy.
[28] Zuomin Dong,et al. Bi-level planning for integrated energy systems incorporating demand response and energy storage under uncertain environments using novel metamodel , 2018, CSEE Journal of Power and Energy Systems.
[29] Carlos A. Saldarriaga,et al. An integrated expansion planning model of electric and natural gas distribution systems considering demand uncertainty , 2015, 2015 IEEE Power & Energy Society General Meeting.
[30] Francesco Bonchi,et al. Scalable Online Betweenness Centrality in Evolving Graphs , 2014, IEEE Transactions on Knowledge and Data Engineering.
[31] Jiangfeng Zhang,et al. Low-carbon optimal planning of an integrated energy station considering combined power-to-gas and gas-fired units equipped with carbon capture systems , 2022, International Journal of Electrical Power & Energy Systems.
[32] Zifa Liu,et al. A Planning Method of Regional Integrated Energy System Based on the Energy Hub Zoning Model , 2021, IEEE Access.
[33] Amin Safari,et al. Stochastic planning of integrated power and natural gas networks with simplified system frequency constraints , 2021 .
[34] Z. Lou,et al. Coordinated planning of multi-area multi-energy systems by a novel routing algorithm based on random scenarios , 2021 .
[35] Shiwei Xie,et al. Coupled Planning of Suburban Integrated Energy System With Electric-Biogas-Traffic Considering Fast Charging Station Equalization , 2020, IEEE Access.