跨临界CO2空气源热泵系统性能研究

本文针对空气源跨临界CO2热泵系统,采用效率分析法建立了压缩机的数学模型,采用结构分析法建立了膨胀阀的数学模型,采用分布参数法建立了气体冷却器、蒸发器和中间换热器的数学模型,并将其耦合为整个系统的数学模型,并通过实验验证了数学模型的计算结果。结果表明:机组输人功率的计算值与实测值的偏差小于4.4%;制热量的平均偏差为5.76%;最优排气压力的偏差小于0.1MPa。综上所述,在确定的运行工况下,通过数学模拟计算某确定配置系统的性能参数是可行的。...

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Published in	制冷学报 Vol. 39; no. 2; pp. 22 - 30
Main Author	赵宗彬;宋昱龙;包继虎;陆磊;李宏哲;郭扬;朱丰雷
Format	Journal Article
Language	Chinese
Published	合肥通用机械研究院合肥230031%西安交通大学能源与动力工程学院西安710049 2018
Subjects	CO2热泵系统;稳态数学模型;最优排气压力;不确定度;性能系数 coefficient of performance 性能系数 CO2 heat pump system 最优排气压力 steady state mathematical model 不确定度 CO2热泵系统稳态数学模型 uncertainty optimal discharge pressure
Online Access	Get full text
ISSN	0253-4339
DOI	10.3969/j.issn.0253-4339.2018.02.022

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Abstract	本文针对空气源跨临界CO2热泵系统,采用效率分析法建立了压缩机的数学模型,采用结构分析法建立了膨胀阀的数学模型,采用分布参数法建立了气体冷却器、蒸发器和中间换热器的数学模型,并将其耦合为整个系统的数学模型,并通过实验验证了数学模型的计算结果。结果表明:机组输人功率的计算值与实测值的偏差小于4.4%;制热量的平均偏差为5.76%;最优排气压力的偏差小于0.1MPa。综上所述,在确定的运行工况下,通过数学模拟计算某确定配置系统的性能参数是可行的。
AbstractList	TB61+1%TQ051.5; 本文针对空气源跨临界CO2热泵系统,采用效率分析法建立了压缩机的数学模型,采用结构分析法建立了膨胀阀的数学模型,采用分布参数法建立了气体冷却器、蒸发器和中间换热器的数学模型,并将其耦合为整个系统的数学模型,并通过实验验证了数学模型的计算结果.结果表明:机组输入功率的计算值与实测值的偏差小于4.4％;制热量的平均偏差为5.76％;最优排气压力的偏差小于0.1 MPa.综上所述,在确定的运行工况下,通过数学模拟计算某确定配置系统的性能参数是可行的. 本文针对空气源跨临界CO2热泵系统,采用效率分析法建立了压缩机的数学模型,采用结构分析法建立了膨胀阀的数学模型,采用分布参数法建立了气体冷却器、蒸发器和中间换热器的数学模型,并将其耦合为整个系统的数学模型,并通过实验验证了数学模型的计算结果。结果表明:机组输人功率的计算值与实测值的偏差小于4.4%;制热量的平均偏差为5.76%;最优排气压力的偏差小于0.1MPa。综上所述,在确定的运行工况下,通过数学模拟计算某确定配置系统的性能参数是可行的。
Abstract_FL	Based on a theoretical analysis of an air-source transcritical CO2 heat pump system,a mathematical model for the compressor was eveloped using an efficiency analysis in this study.In addition,a mathematical model for the expansion valve was built using a structural analysis;and mathematical models for the gas-cooler,evaporator,and regenerator were developed using the distributed parameter method.Moreover,a mathematical model for the entire system was built by combining these models.The accuracy of the system model was verified by an experimental test,which showed that the deviation in the unit's input power between the calculated value and measured value was less than 4.4％,the mean deviation in the heating capacity was 5.76％,and the deviation in the optimal discharge pressure was less than 0.1 MPa.Thus,it was possible to calculate the system performance by employing the mathematical simulation method.
Author	赵宗彬;宋昱龙;包继虎;陆磊;李宏哲;郭扬;朱丰雷
AuthorAffiliation	合肥通用机械研究院合肥230031;西安交通大学能源与动力工程学院西安710049
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Author_FL	Guo Yang Bao Jihu Lu Lei Li Hongzhe Zhu Fenglei Song Yulong Zhao Zongbin
Author_FL_xml	– sequence: 1 fullname: Zhao Zongbin – sequence: 2 fullname: Song Yulong – sequence: 3 fullname: Bao Jihu – sequence: 4 fullname: Lu Lei – sequence: 5 fullname: Li Hongzhe – sequence: 6 fullname: Guo Yang – sequence: 7 fullname: Zhu Fenglei
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Keywords	coefficient of performance 性能系数 CO2 heat pump system 最优排气压力 steady state mathematical model 不确定度 CO2热泵系统稳态数学模型 uncertainty optimal discharge pressure
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Notes	11-2182/TB C02 heat pump system; steady state mathematical model; optimal discharge pressure; uncertainty; coefficient of performance Based on a theoretical analysis of an air-source transcritical C02heat pump system,a mathematical model for the compressor was eveloped using an efficiency analysis in this study.In addition,a mathematical model for the expansion valve was built using a structural analysis;and mathematical models for the gas-cooler,evaporator,and regenerator were developed using the distributed parameter method.Moreover,a mathematical model for the entire system was built by combining these models.The accuracy of the system model was verified by an experimental test,which showed that the deviation in the unit^input power between the calculated value and measured value was less than4.4%,the mean deviation in the heating capacity was5.76%,and the deviation in the optimal discharge pressure was less than0.1MPa.Thus,it was possible to calculate the system performance by employing the mathematical sim
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SubjectTerms	CO2热泵系统;稳态数学模型;最优排气压力;不确定度;性能系数
Title	跨临界CO2空气源热泵系统性能研究
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