Modeling and optimal dispatch of a carbon-cycle integrated energy system for low-carbon and economic operation

Modeling and optimal dispatch of a carbon-cycle integrated energy system for low-carbon and economic operation

Energy efficiency and greenhouse gas emissions mitigation are important topics in modern energy systems research. In this study, power-to-gas (P2G), carbon capture, supercritical CO2 (S–CO2) cycle systems are integrated into a carbon cycle system, and the role of the carbon cycle system in the elect...

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Veröffentlicht in:Energy (Oxford) 2022-02, Vol.240, p.122795, Article 122795
Hauptverfasser: Zhang, Guangming, Wang, Wei, Chen, Zhenyu, Li, Ruilian, Niu, Yuguang
Format: Artikel
Sprache:eng
Schlagworte:
Carbon capture
Carbon cycle
Carbon dioxide
Carbon sequestration
Electricity-heat integrated energy system
Electrolysis
Emissions
Energy and exergy analysis
Energy efficiency
Exergy
Greenhouse gases
Heat
Integrated energy systems
Mitigation
Optimization
Photovoltaic cells
Photovoltaics
Power management
Power-to-gas
Subsystems
Supercritical CO2 cycle
Wind power
Working fluids
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creator Zhang, Guangming
Wang, Wei
Chen, Zhenyu
Li, Ruilian
Niu, Yuguang
description Energy efficiency and greenhouse gas emissions mitigation are important topics in modern energy systems research. In this study, power-to-gas (P2G), carbon capture, supercritical CO2 (S–CO2) cycle systems are integrated into a carbon cycle system, and the role of the carbon cycle system in the electricity-heat integrated energy system (IES) is explored. The carbon capture system collects the CO2 produced by coal-fired and gas-fired units, which can be recycled in two ways. One is sent to P2G device to react with the hydrogen produced by electrolysis of water. The other part is sent to the S–CO2 unit as the supplementary working fluid. In addition, the waste heat of the gas-fired unit and the heat released in P2G are collected as additional heat supply. This work focuses on the optimal dispatch in an IES with carbon cycle system connection. The optimization results show that with the orderly regulation of the carbon cycle subsystem, the wind power and photovoltaics' curtailment rates can be reduced by 3.1% and 10.8%, respectively. And the system's carbon emissions are reduced by 89.5%. Besides, IES's energy and exergy efficiencies increase by 1% and 0.9% after applying the carbon cycle system. •P2G, carbon capture, and S–CO2 systems are integrated into a carbon cycle system.•Model of the carbon cycle system from electricity and heat perspective is established.•Renewable energy penetration is promoted by introducing the carbon cycle system.•The carbon emissions of IES are reduced by 89.5% with the carbon cycle system.•The energy and exergy efficiencies are increased by 1% and 0.9%, respectively.
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subjects Carbon capture
Carbon cycle
Carbon dioxide
Carbon sequestration
Electricity-heat integrated energy system
Electrolysis
Emissions
Energy and exergy analysis
Energy efficiency
Exergy
Greenhouse gases
Heat
Integrated energy systems
Mitigation
Optimization
Photovoltaic cells
Photovoltaics
Power management
Power-to-gas
Subsystems
Supercritical CO2 cycle
Wind power
Working fluids
title Modeling and optimal dispatch of a carbon-cycle integrated energy system for low-carbon and economic operation
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