Performance Investigation of Solar Organic Rankine Cycle Systems With and Without Regeneration and With Zeotropic Working Fluid Mixtures for Use in Micro-Cogeneration

W. Yaïci, E. Entchev, P. Sardari
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Abstract

Globally there are several viable sources of renewable, low-temperature heat (below 130°C) particularly solar energy, geothermal energy, and energy generated from industrial wastes. Increased exploitation of these low-temperature options has the definite potential of reducing fossil fuel consumption with its attendant very harmful greenhouse gas emissions. Researchers have universally identified the organic Rankine cycle (ORC) as a practicable and promising system to generate electrical power from renewable sources based on its beneficial use of volatile organic fluids as working fluids (WFs). In recent times, researchers have also shown a preference for/an inclination towards deployment of zeotropic mixtures as ORC WFs because of their capacity to improve thermodynamic performance of ORC systems, a feat enabled by better matches of the temperature profiles of the WF and the heat source/sink. This paper demonstrates both the technical feasibility and the notable advantages of using zeotropic mixtures as WFs through a simulation study of an ORC system. The study examines the thermodynamic performance of ORC systems using zeotropic WF mixtures to generate electricity driven by low-temperature solar heat source for building applications. A thermodynamic model is developed with an ORC system both with and excluding a regenerator. Five zeotropic mixtures with varying compositions of R245fa/propane, R245fa/hexane, R245fa/heptane, pentane/hexane and isopentane/hexane are evaluated and compared to identify the best combinations of WF mixtures that can yield high efficiency in their system cycles. The study also investigates the effects of the volumetric flow ratio, and evaporation and condensation temperature glides on the ORC’s thermodynamic performance. Following a detailed analysis of each mixture, R245fa/propane is selected for parametric study to examine the effects of operating parameters on the system’s efficiency and sustainability index. For zeotropic mixtures, results showed that there is an optimal composition range within which binary mixtures are inclined to perform more efficiently than the component pure fluids. In addition, a significant increase in cycle efficiency can be achieved with a regenerative ORC, with cycle efficiency ranging between 3.1–9.8% and 8.6–17.4% for ORC both without and with regeneration, respectively. Results also showed that exploiting zeotropic mixtures could enlarge the limitation experienced in selecting WFs for low-temperature solar organic Rankine cycles.
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微热电联产用太阳能有机朗肯循环系统的性能研究
全球有几种可行的可再生低温热源(低于130°C),特别是太阳能、地热能和工业废物产生的能源。增加对这些低温选择的开发,具有减少化石燃料消耗及其伴随的非常有害的温室气体排放的明确潜力。研究人员普遍认为有机朗肯循环(ORC)是一种可行的、有前途的可再生能源发电系统,因为它有益地利用挥发性有机流体作为工作流体(WFs)。近年来,研究人员也表现出对使用共沸水混合材料作为ORC WFs的偏好/倾向,因为它们能够改善ORC系统的热力学性能,这是由于WF和热源/汇的温度分布更好地匹配而实现的。本文通过ORC系统的模拟研究,论证了采用共沸混合物作为WFs的技术可行性和显著的优点。该研究考察了使用共向WF混合物的ORC系统的热力学性能,该系统由低温太阳能热源驱动,用于建筑应用。建立了含蓄热器和不含蓄热器的ORC系统的热力学模型。对R245fa/丙烷、R245fa/己烷、R245fa/庚烷、戊烷/己烷和异戊烷/己烷五种不同组成的共沸混合物进行了评价和比较,以确定能在系统循环中产生高效率的WF混合物的最佳组合。研究了体积流量比、蒸发和冷凝温度对ORC热力学性能的影响。在对每种混合物进行详细分析后,选择R245fa/丙烷进行参数研究,以考察运行参数对系统效率和可持续性指标的影响。对于共沸混合物,结果表明存在一个最佳组成范围,在该范围内二元混合物倾向于比组分纯流体更有效地发挥作用。此外,再生ORC的循环效率显著提高,无再生ORC的循环效率为3.1-9.8%,有再生ORC的循环效率为8.6-17.4%。结果还表明,开发共沸混合物可以扩大低温太阳有机朗肯循环WFs选择的局限性。
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