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蒸汽喷射-压缩循环制冷系统的数值研究 被引量:2

Numerical study on steam injection/compression cycle refrigeration system
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摘要 将喷射器作为压缩机辅助升压装置引入单级蒸气压缩制冷系统,通过建立喷射器一维数学模型和蒸汽喷射-压缩循环制冷系统模型,研究了喷射器工作压力和引射压力、蒸发温度和冷凝温度对蒸汽喷射-压缩混合制冷循环系统性能的影响。结果表明:冷凝温度从25℃增加到43℃,蒸发温度Te=-20、-25和-30℃时,系统COP分别减小了32. 5%、42. 9%和56. 8%。当冷凝温度Tc=31、34℃时,蒸发温度从-35℃升高到-5℃,系统COP分别增加了32. 5%和28. 6%。 The ejector was introduced into the single stage vapor compression refrigeration system as an auxiliary booster for the compressor. By establishing a one-dimensional mathematical model of the ejector and a model of a steam injection/compression cycle refrigeration system,the effects of the ejector working pressure,eject pressure,evaporating temperature and condensing temperature on the performance of the steam injection-compression hybrid refrigeration cycle system were theoretically studied.The results show that the condensing temperature increases from 25℃ to 43℃. When evaporation temperature Teequals-20,-25 and-30℃,the system COP is reduced by 32. 5%,42. 9% and 56. 8% respectively. When the condensation temperature Tcequals 31℃ and 34℃,the evaporation temperature increases from-35℃ to-5℃,and the system COP increases by 32. 5%and 28. 6% respectively. When the condensation temperature is 31℃ and 34℃,the evaporation temperature increases from-35℃ to-5℃,and the COP of the system increases by 32. 5% and 28. 6% respectively.
作者 张晨旭 臧润清 巩庆霞 Zhang Chenxu;Zang Runqing;Gong Qingxia(Tianjin Key Laboratory of Refrigeration Technology,Refrigeration Engineering Research Center of Ministry of Education of P.R.C,Tianjin Refrigeration Engineering Technology Center,Tianjin University of Commerce,Tianjin 300134,China)
机构地区 天津市制冷技术重点实验室冷冻冷藏技术教育部工程研究中心天津市制冷技术工程中心天津商业大学
出处 《低温与超导》 CAS 北大核心 2019年第2期85-90,共6页 Cryogenics and Superconductivity
关键词 喷射器 制冷量 COP 蒸汽喷射-压缩循环制冷系统 Ejector Refrigerating capacity COP Steam injection/compression cycle refrigeration system
分类号 TB657 [一般工业技术—制冷工程]
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低温与超导
2019年 第2期

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