通过太阳能驱动的布雷顿和跨临界二氧化碳循环一体化实现可持续发电:全面的 3E(能量、放热和放热环境)评估

IF 4.4 4区 综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES
Yunis Khan, Roshan Raman, Zafar Said, Hakan Caliskan, Hiki Hong
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引用次数: 0

摘要

在其他集中式太阳能发电技术中,太阳能发电塔技术在大型发电方面具有很强的潜力。因此,有必要为利用太阳能发电塔系统开发一种新型高效的电力转换系统。本研究提出了一种新型联合循环发电系统,用于太阳能发电塔的应用。布雷顿循环的预压缩配置被用作顶循环,其中氦气被用作工作流体。跨临界二氧化碳循环被用作利用余热的底部循环。利用计算技术工程方程求解器,从放热、能量和放热环境的角度对拟议系统进行了研究。此外,还进行了参数分析,以检查不同变量对系统性能的影响。结果表明,在联合循环的最佳温度为 800 ℃、直接正常辐照度为 850 W m-2 和压缩机压力比为 2.278 时,整个发电厂的优化热效率和能效分别为 31.59% 和 33.12%。然而,外部能效稳定系数和外部环境影响指数分别为 0.5952 和 0.6801。与之前的研究相比,本系统的组件更少,性能更好。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Sustainable Power Generation Through Solar-Driven Integration of Brayton and Transcritical CO2 Cycles: A Comprehensive 3E (Energy, Exergy, and Exergoenvironmental) Evaluation

Sustainable Power Generation Through Solar-Driven Integration of Brayton and Transcritical CO2 Cycles: A Comprehensive 3E (Energy, Exergy, and Exergoenvironmental) Evaluation

Sustainable Power Generation Through Solar-Driven Integration of Brayton and Transcritical CO2 Cycles: A Comprehensive 3E (Energy, Exergy, and Exergoenvironmental) Evaluation

Solar power tower technology has strong potential among the other concentration solar power techniques for large power generation. Therefore, it is necessary to make a new and efficient power conversion system for utilizing the solar power tower system. In present research, a novel combined cycle is proposed to generate power for the application of the solar power tower. The pre-compression configuration of the Brayton cycle is used as a topping cycle in which helium is taken as the working fluid. The transcritical CO2 cycle is used as bottoming cycle for using the waste heat. The proposed system is investigated based on exergy, energy, and exergoenvironmental point of view using computational technique engineering equation solver. Also, the parametric analysis is carried out to check the impact of the different variables on the system performance. It is concluded that the overall plant's optimized thermal and exergy efficiencies are obtained as 31.59% and 33.12%, respectively, at 800 °C optimum temperature of combined cycle and 850 W m−2 of direct normal irradiation and 2.278 of compressor pressure ratio. However, exergetic stability factor and exergoenvironmental impact index are observed as 0.5952 and 0.6801 respectively. The present proposed system performs better than the previous studies with fewer components.

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来源期刊
Global Challenges
Global Challenges MULTIDISCIPLINARY SCIENCES-
CiteScore
8.70
自引率
0.00%
发文量
79
审稿时长
16 weeks
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