集成喷射器-吸附再压缩和改良有机郎肯循环的太阳能三联供系统的热经济分析

Shubham Kumar Mishra, Amrit Rehalia, Ashutosh Kumar Verma, Laxmikant Yadav
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摘要

本研究对 ORC 和混合吸收再压缩循环进行了改进,增加了带再生和喷射器的涡轮渗流,使其成为一个独特的太阳能三联供系统。通过这种改进,由于质量流量增加,有用电功率增加了 65 千瓦,总效率提高了近 0.7%,而且随着 DNI 的增加,这一差异也在扩大。在确定了这些改进之后,又进行了参数研究,以确定这些运行变量的最佳值,如直接法线辐照、冷凝器压力、涡轮机入口温度和压力比,这些都是基于所建议的改进系统的理想输出和效率。结果表明,建议的系统能够同时产生 315.3 千瓦的电力、1588 千瓦的加热输出和 501.6 千瓦的冷却输出,能量效率和放能效率分别为 80.8% 和 25.36%。此外,就能量而言,我们可以得出这样的结论:仅有 19.2% 的可用总能量被浪费,但实际上,约有 75% 的输入放能的工作潜能被浪费。最大的能量损失在太阳能集热器上,在 HRVG 上被破坏,因此需要精心设计以提高其性能。最后,还对拟议系统进行了经济分析,发现投资回收期为 2.33 年,这确保了其经济可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thermo-Economic Analysis of Solar-Powered Trigeneration System with Integrated Ejector-Absorption Recompression and Modified Organic Rankine Cycle
In this study, the ORC and hybrid absorption recompression cycle have been modified by the addition of turbine bleeding with regeneration and ejector, making it a unique solar-powered trigeneration system. With this modification, the useful electric power increases by 65 kW due to increased mass flow rate and overall efficiency nearly by 0.7%, and this difference grows as DNI rises. After identifying these improvements, a parametric study was conducted to determine the optimum value of these operating variables, such as direct normal irradiation, condenser pressure, turbine inlet temperature, and pressure ratio, based on the desired outputs and efficiencies of the proposed modified systems. The results indicate that the proposed system is capable of simultaneously generating 315.3 kW of electric power, 1588 kW of heating output, and 501.6 kW of cooling at energy and exergy efficiencies of 80.8% and 25.36%, respectively. Further, in terms of energy one could conclude that only 19.2 % of total available energy is getting wasted, but in reality, around 75% of the work potential of the input exergy is getting wasted. The maximum exergy is lost at the solar collector and destructed at HRVG, hence requiring careful design to improve their performance. Lastly, an economic analysis of the proposed system has also been conducted, and the payback period is found to be 2.33 years, which ensures its economic viability.
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