{"title":"采用各种太阳能集热器的亚热带气候高效太阳能辅助空调系统的瞬态分析","authors":"Ghulam Qadar Chaudhary , Muhammad Waheed Azam , Fabio Bozzoli , Uzair Sajjad , Pamela Vocale , Luca Cattani , Rasoul Fallahzadeh","doi":"10.1016/j.ecmx.2024.100634","DOIUrl":null,"url":null,"abstract":"<div><p>The air conditioning demand of the world is largely fulfilled by vapor compression systems; however, these systems are also responsible for depleting ozone layer due to the nature of refrigerants. Desiccant cooling systems integrated with solar thermal energy technologies could be an attractive alternative with some performance enhancement techniques. In this study, transient seasonal performance investigation is performed for an innovative solar integrated desiccant cooling system that uses regenerative evaporative cooler known as solar assisted desiccant integrated Maisotsenko cycle cooler for better cooling performance. Furthermore, transient annual performance analysis of solar system for meeting thermal energy requirement for regenerating the desiccant wheel in summer season and handling heating load of the building in winter season is also carried out with three different solar thermal collector technologies for finding out more efficient technology. The key performance indicators in this study are useful energy gain, solar source efficiency, auxiliary energy sharing, coefficient of performance, and solar fraction. The results of the key performance parameters are reported as monthly average values. The proposed integrated system resulted to be very efficient with a maximum COP value of 1.13 in April when latent cooling loads are low and 0.78 in August when latent cooling loads are higher. The system’s maximum cooling capacity is 24 kW in April corresponding to a sensible heat factor of 0.720. Furthermore, the regeneration temperature requirements ranged from 50 °C to 78 °C, respectively that makes it favorable to use low grade thermal energy through non concentrating solar thermal collectors. The regeneration thermal energy requirement for desiccant wheel fluctuates throughout the year, maximizing in August due to higher dehumidification requirements. The study also revealed that the evacuated tube collector technology is most suitable with average annual efficiency of around 36 %.</p></div>","PeriodicalId":37131,"journal":{"name":"Energy Conversion and Management-X","volume":null,"pages":null},"PeriodicalIF":7.1000,"publicationDate":"2024-05-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S2590174524001120/pdfft?md5=ab040f1c4222d3bfe49b0150dc607f97&pid=1-s2.0-S2590174524001120-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Transient analysis of an efficient solar assisted air-conditioning system for subtropical climate with various solar thermal collectors\",\"authors\":\"Ghulam Qadar Chaudhary , Muhammad Waheed Azam , Fabio Bozzoli , Uzair Sajjad , Pamela Vocale , Luca Cattani , Rasoul Fallahzadeh\",\"doi\":\"10.1016/j.ecmx.2024.100634\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>The air conditioning demand of the world is largely fulfilled by vapor compression systems; however, these systems are also responsible for depleting ozone layer due to the nature of refrigerants. 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The results of the key performance parameters are reported as monthly average values. The proposed integrated system resulted to be very efficient with a maximum COP value of 1.13 in April when latent cooling loads are low and 0.78 in August when latent cooling loads are higher. The system’s maximum cooling capacity is 24 kW in April corresponding to a sensible heat factor of 0.720. Furthermore, the regeneration temperature requirements ranged from 50 °C to 78 °C, respectively that makes it favorable to use low grade thermal energy through non concentrating solar thermal collectors. The regeneration thermal energy requirement for desiccant wheel fluctuates throughout the year, maximizing in August due to higher dehumidification requirements. 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引用次数: 0
摘要
全世界的空调需求主要由蒸汽压缩系统来满足;然而,由于制冷剂的性质,这些系统也是消耗臭氧层的罪魁祸首。与太阳能热能技术相结合的干燥剂冷却系统可以通过一些性能提升技术成为一种有吸引力的替代方案。在本研究中,对创新的太阳能集成干燥剂冷却系统进行了瞬态季节性能调查,该系统使用再生蒸发冷却器(称为太阳能辅助干燥剂集成麦索岑科循环冷却器),以获得更好的冷却性能。此外,还利用三种不同的太阳能集热器技术,对太阳能系统进行了瞬态年度性能分析,以满足夏季再生干燥剂轮和冬季处理建筑物供热负荷的热能需求,从而找出更高效的技术。这项研究的关键性能指标是有用能量增益、太阳光源效率、辅助能源分担、性能系数和太阳光分量。关键性能参数的结果以月平均值的形式报告。拟议的集成系统非常高效,在潜冷负荷较低的四月,最大 COP 值为 1.13;在潜冷负荷较高的八月,最大 COP 值为 0.78。该系统在四月份的最大制冷量为 24 千瓦,显热系数为 0.720。此外,再生温度要求分别在 50 °C 至 78 °C 之间,这有利于通过非聚光太阳能集热器使用低品位热能。干燥轮的再生热能需求全年波动,8 月份由于除湿需求较高而达到最大。研究还表明,抽真空管集热器技术最合适,年平均效率约为 36%。
Transient analysis of an efficient solar assisted air-conditioning system for subtropical climate with various solar thermal collectors
The air conditioning demand of the world is largely fulfilled by vapor compression systems; however, these systems are also responsible for depleting ozone layer due to the nature of refrigerants. Desiccant cooling systems integrated with solar thermal energy technologies could be an attractive alternative with some performance enhancement techniques. In this study, transient seasonal performance investigation is performed for an innovative solar integrated desiccant cooling system that uses regenerative evaporative cooler known as solar assisted desiccant integrated Maisotsenko cycle cooler for better cooling performance. Furthermore, transient annual performance analysis of solar system for meeting thermal energy requirement for regenerating the desiccant wheel in summer season and handling heating load of the building in winter season is also carried out with three different solar thermal collector technologies for finding out more efficient technology. The key performance indicators in this study are useful energy gain, solar source efficiency, auxiliary energy sharing, coefficient of performance, and solar fraction. The results of the key performance parameters are reported as monthly average values. The proposed integrated system resulted to be very efficient with a maximum COP value of 1.13 in April when latent cooling loads are low and 0.78 in August when latent cooling loads are higher. The system’s maximum cooling capacity is 24 kW in April corresponding to a sensible heat factor of 0.720. Furthermore, the regeneration temperature requirements ranged from 50 °C to 78 °C, respectively that makes it favorable to use low grade thermal energy through non concentrating solar thermal collectors. The regeneration thermal energy requirement for desiccant wheel fluctuates throughout the year, maximizing in August due to higher dehumidification requirements. The study also revealed that the evacuated tube collector technology is most suitable with average annual efficiency of around 36 %.
期刊介绍:
Energy Conversion and Management: X is the open access extension of the reputable journal Energy Conversion and Management, serving as a platform for interdisciplinary research on a wide array of critical energy subjects. The journal is dedicated to publishing original contributions and in-depth technical review articles that present groundbreaking research on topics spanning energy generation, utilization, conversion, storage, transmission, conservation, management, and sustainability.
The scope of Energy Conversion and Management: X encompasses various forms of energy, including mechanical, thermal, nuclear, chemical, electromagnetic, magnetic, and electric energy. It addresses all known energy resources, highlighting both conventional sources like fossil fuels and nuclear power, as well as renewable resources such as solar, biomass, hydro, wind, geothermal, and ocean energy.