使用跨临界二氧化碳动力循环的自过热联合闪蒸二元地热循环,以液化天然气散热器作为二次循环

IF 9 1区 工程技术 Q1 ENERGY & FUELS
Subha Mondal , Sudipta De
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引用次数: 0

摘要

联合闪蒸二元地热循环(CFBGC)是一种高效的地热能转换技术。天然气(NG)是当前能源领域的首选燃料。液化天然气气化是向终端用户输送天然气的必要步骤。本研究将自过热单闪蒸地热蒸汽循环、跨临界二氧化碳发电循环和液化天然气气化装置集成到 CFBGC 中。研究表明,通过提高蒸汽轮机进口压力,可同时提高液化天然气气化率和功率输出。在较高的蒸汽轮机入口压力下,通过蒸汽的自过热,蒸汽轮机出口处可保持理想的蒸汽品质(即 0.9)。据观察,15 °C 的蒸汽自过热可使 CFBGC 在蒸汽轮机入口压力下运行,从而大幅提高输出功率,而不会明显增加平准化电力成本(LEC)。在此条件下运行的 CFBGC 与在蒸汽轮机进口压力下运行的 CFBGC 相比,输出功率高出 9.97%。由于地热发电厂的二氧化碳排放量极低,拟议的能源系统可能成为未来的可持续能源选择。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Self-superheated combined flash binary geothermal cycle using transcritical-CO2 power cycle with LNG heat sink as the secondary cycle
Combined flash binary geothermal cycle (CFBGC) is an efficient geothermal energy conversion technology. Natural gas (NG) is a preferred fuel in the current energy scenario. LNG gasification is a needed step for delivering NG among the end users. In the present study, a self-superheated single-flash geothermal steam cycle, a transcritical CO2 power cycle and an LNG gasification unit are integrated into a CFBGC. This study shows that the LNG gasification rate and power output can be increased simultaneously by increasing the steam turbine inlet pressure. At a higher steam turbine inlet pressure, desirable steam quality (i.e., 0.9) at the steam turbine exit is maintained by implementing self superheating of the steam. It is observed that 15 °C DSH of steam enables the CFBGC to operate at a steam turbine inlet pressure that substantially enhances the output power without a noticeable increase in levelized electricity cost (LEC). The CFBGC operating at this condition yields 9.97 % higher power output compared to that of the CFBGC operating at steam turbine inlet pressure requiring no DSH of steam. As a geothermal-based power plant emits very low CO2, the proposed energy system may emerge as a future sustainable energy option.
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来源期刊
Energy
Energy 工程技术-能源与燃料
CiteScore
15.30
自引率
14.40%
发文量
0
审稿时长
14.2 weeks
期刊介绍: Energy is a multidisciplinary, international journal that publishes research and analysis in the field of energy engineering. Our aim is to become a leading peer-reviewed platform and a trusted source of information for energy-related topics. The journal covers a range of areas including mechanical engineering, thermal sciences, and energy analysis. We are particularly interested in research on energy modelling, prediction, integrated energy systems, planning, and management. Additionally, we welcome papers on energy conservation, efficiency, biomass and bioenergy, renewable energy, electricity supply and demand, energy storage, buildings, and economic and policy issues. These topics should align with our broader multidisciplinary focus.
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