Viktoria Carmen Illyés , Gioele Di Marcoberardino , Andreas Werner , Markus Haider , Giampaolo Manzolini
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引用次数: 0
Abstract
Zeotropic CO2-based mixtures as working fluids in the power block have the potential to enhance concentrated solar power (CSP) plants and other high-temperature heat source applications. One promising working fluid is the CO2/C6F6 mixture, which enables condensation at 50 °C – a necessity when dry cooling with ambient air. Given the many theoretical studies on topics such as potential, optimized performance, or economic assessments, an experimental validation and a reality-check in a facility of significant size is required to vindicate further research. The experimental campaign was performed on pure CO2 and the CO2/C6F6 mixture in two compositions in a test facility (recuperated transcritical cycle). The long-term test (170h) revealed no operational issues, including no signs of thermal degradation. However, a composition shift - an effect previously regarded as an issue in closed cycles with zeotropic mixtures - affected the conditions at the vapor-liquid-equilibrium in the systems tank but also self-stabilizes the system to remain condensing, even at higher ambient air temperatures. The successful proof-of-concept at cycle temperatures of up to 500 °C – significantly higher than earlier studies on mixtures reported (<300 °C) – justifies further research in this area.
各向同性二氧化碳混合物作为动力块中的工作流体,有可能提高聚光太阳能发电厂(CSP)和其他高温热源应用的效率。二氧化碳/C6F6 混合物是一种很有前景的工作流体,它能在 50 °C 温度下凝结,这是用环境空气进行干式冷却时的必要条件。鉴于有许多关于潜力、优化性能或经济评估等主题的理论研究,因此需要在大型设施中进行实验验证和实际检查,以证明进一步的研究是正确的。实验活动是在一个测试设备(换热式跨临界循环)中对纯 CO2 和两种成分的 CO2/C6F6 混合物进行的。长期测试(170 小时)没有发现任何运行问题,包括热降解迹象。然而,成分偏移--以前被认为是各向同性混合物封闭循环中的一个问题--影响了系统罐中的汽液平衡条件,但也使系统自我稳定,即使在较高的环境空气温度下也能保持冷凝。在高达 500 °C 的循环温度下成功进行的概念验证(远高于之前对混合物进行的研究(300 °C ))证明了在该领域开展进一步研究的合理性。
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.