[1]赵海谦,何明祺,刘景雯,等.制冷工质的应用与研究进展[J].徐州工程学院学报(自然科学版),2020,(03):41-46.
 ZHAO Haiqian,HE Mingqi,LIU Jingwen,et al.Application and Research Progress of Refrigerants[J].Journal of Xuzhou Institute of Technology(Natural Sciences Edition),2020,(03):41-46.
点击复制

制冷工质的应用与研究进展()
分享到:

《徐州工程学院学报》(自然科学版)[ISSN:1674-358X/CN:32-1789/N]

卷:
期数:
2020年03期
页码:
41-46
栏目:
教授论坛
出版日期:
2020-09-30

文章信息/Info

Title:
Application and Research Progress of Refrigerants
文章编号:
1674-358X(2020)03-0041-06
作者:
赵海谦何明祺刘景雯杨雪尹新元
(东北石油大学 土木建筑工程学院,黑龙江 大庆163000)
Author(s):
ZHAO HaiqianHE MingqiLIU JingwenYANG XueYIN Xinyuan
(Northeast Petroleum University,School of Civil Engineering & Architecture,Daqing 163000,China)
关键词:
制冷工质 压缩式制冷 吸收式制冷 吸附式制冷 制冷系统
Keywords:
refrigerant compression refrigeration absorption refrigeration adsorption refrigeration refrigeration system
分类号:
TB64
文献标志码:
A
摘要:
随着制冷技术的进一步优化和发展,人们对于制冷系统效率的要求也愈来愈高,而制冷工质的作用在制冷系统中占据着重要的地位,其性能的优劣直接决定了制冷系数(COP)的高低,所以对制冷工质的开发与研制一直以来都被制冷行业研究人员所关注.该文综述了压缩式制冷、吸收式制冷和吸附式制冷三大制冷循环系统所常用的制冷工质及其发展历程,并对比分析了它们各自的理化特性,指出开发和研制绿色、经济、高效的制冷工质是一项长久而意义深远的工作.
Abstract:
With the further optimization and development of refrigeration technology,people have higher requirements for the efficiency of refrigeration system,and the selection of refrigerant plays an important role in the refrigeration system,whose performance directly determines the coefficient of refrigeration(COP).Therefore,the research and development of refrigerant has always been concerned by researchers in refrigeration industry.In this paper,the development history of the three commonly used refrigerants of compression refrigeration,absorption refrigeration and adsorption refrigeration was reviewed,and then their physical and chemical characteristics are compared and analyzed.It is pointed out that developing and producing the green,economical and efficient refrigerants is still a long|term and far|reaching work.

参考文献/References:

[1] NAJJARAN A,FREEMAN J,RAMOS A,et al.Experimental investigation of an ammonia|water|hydrogen diffusion absorption refrigerator[J].Applied Energy,2019,256:113899.
[2] HIGA M,YAMAMOTO E Y,DEOLIVEIRA J C D,et al.Evaluation of the integration of an ammonia|water power cycle in an absorption refrigeration system of an industrial plant[J].Energy Conversion and Management,2018,178:265|276.
[3] SHANMUGAM S K G,MITAL M.An ultra|low ammonia charge system for industrial refrigeration[J].International Journal of Refrigeration,2019,107:344|354.
[4] 邵亚伟,邓帅,苏文,等.制冷工质流动沸腾数值模拟中源项模型的研究进展[J].化工进展,2018,37(8):2892|2903.
[5] MURTHY A,SUBIANTORO A,NORRIS S,et al.A review on expanders and their performance in vapour compression refrigeration systems[J/OL].International Journal of Refrigeration,2019,[ 2019|10|23].https://doi.org/10.1002/er.1736.DO:10.1016/j.ijrefrig.2019.06.019.
[6] NTEP T J M,REINSCH H,HÜGENELL P C,et al.Designing a new aluminium muconate metal|organic framework(MIL|53|muc)as a methanol adsorbent for sub|zero temperature heat transformation applications[J].Journal of Materials Chemistry A,2019,7(43):24973|24981.
[7] HENG Z,FEIPENG C,YANG L,et al.The performance analysis of a LCPV/T assisted absorption refrigeration system[J].Renewable Energy,2019,143:1852|1864.
[8] JIA Y,ZHAO X,LIU X,et al.Magnetic properties and magnetocaloric performances in amorphousized RE55Ni18Al27(RE= Ho,Er and Tm)ribbons[J].Journal of Alloys and Compounds,2019,813:152177.
[9] 张垚,朱山杉,王晓坡,等.采用R1234ze(E)/离子液体工质对的吸收式制冷循环性能分析[J].西安交通大学学报,2019,53(5):9|15.)
[10] 杨梦,张华,秦延斌,等.混合制冷工质R134a/R1234yf(R513A)与R134a热力学性能对比及实验[J].化工进展,2019,38(3):1182|1189.
[11] 杨婧烨,陆冰清,陈江平.新型R1233zde制冷工质的高效节能环保性能分析[J].汽车工程,2018,40(8):892|896.
[12] 李梦丹.R1234yf的pvT性质实验研究及其混合物在热泵系统中的理论循环性能分析[D].太原:太原理工大学,2019.
[13] GILL J,SINGH J.Energy analysis of vapor compression refrigeration system using mixture of R134a and LPG as refrigerant[J].International Journal of Refrigeration,2017,84:287|299.
[14] 刘岩,梁荣光,巫江虹,等.新型汽车空调制冷工质CMR|O2与R12、R134a性能比较[J].环境科学与技术,2007(10):23|24.
[15] 魏文建,丁国良,胡海涛,等.R410A制冷工质和POEVG68润滑油混合物热物性模型[J].制冷学报,2007(1):37|44.
[16] ARORA A,KAUSHIK S C.Theoretical analysis of a vapour compression refrigeration system with R502,R404A and R507A[J].International Journal of Refrigeration,2008,31(6):998|1005.
[17] 申江,张于峰,李林,等.氨制冷技术研究进展[J].化工学报,2008,59(S2):29|36.
[18] 杨一凡.氨制冷技术的应用现状及发展趋势[J].制冷学报,2007(4):12|19.
[19] 曹文胜,鲁雪生.CO2|NH3复叠与NH3制冷系统的流程参数比较[J].化工学报,2010,61(S2):178|182.
[20] 王栋,姜敬德,任红梅,等.充注量对小型CO2制冷系统影响的实验研究[J].低温工程,2013(1):56|59.
[21] 郭贵林,黎立新.跨临界CO2制冷系统气体冷却器分布参数仿真[J].船舶工程,2005(3):29|33.
[22] 王松岭,论立勇,谢英柏,等.碳氢化合物在制冷工质替代过程中的应用[J].天然气工业,2005(12):121|124.
[23] BHATKAR V W,KRIPLANI V M,AWARI G K.Alternative refrigerants in vapour compression refrigeration cycle for sustainable environment:a review of recent research[J].International Journal of Environmental Science and Technology,2013,10(4):871|880.
[24] 王向岩,马伟斌,龚宇烈,等.氟化醚类共沸混合物HFE|143a/HFE|218作为制冷工质与其他几类HCFC|22替代物的分析比较[J].制冷学报,2004(4):35|39.
[25] 周启瑾.丙烷/异丁烷混合工质在小型蒸气压缩制冷系统中的应用研究[J].流体机械,1996(2):56|58.
[26] STEIU S,SALAVERA D,BRUNO J C,et al.A basis for the development of new ammonia|water|sodium hydroxide absorption chillers[J].International Journal of Refrigeration,2009,32(4):577|587.
[27] GAO Y,HE G,CHEN P,et al.Energy and exergy analysis of an air|cooled waste heat|driven absorption refrigeration cycle using R290/oil as working fluid[J].Energy,2019,173:820|832.
[28] 陈光明,陈曙辉.国外吸收制冷研究进展[J].制冷,1998(4):21|27.
[29] 张婕.吸收式制冷技术之工质对的选择应用及技术发展[J].马钢职工大学学报,2001,11(3):55|57.
[30] TOTLA N B,AROTE S,GAIKWAD S V,et al.Comparison of the performances of NH3|H2O and LiBr|H2O vapour absorption refrigeration cycles[J].International Journal of Applied Research in Veterinary Medicine,2016(6):8|13.
[31] 卞宜峰,何国庚,蔡德华,等.吸收式制冷工质对的研究进展[J].制冷学报,2015,36(6):17|26.
[32] 陈光明,陈曙辉.国外吸收制冷研究进展[J].制冷,1998(4):21|27.
[33] HEARRIZETAL J.Thermophysical properties of 2,2,2|trifluoroethnaol+tetraethylene glyeol dimehtyl ether[J].Journal of Chemical and Engineering Data,1999,44(4):750|756.
[34] NOWACZYK U,STEIMLE F.Thermophysical properties of new working fluid systems for absorption processes[J].International Journal of Refrigeration,1992,15(1):10|15.
[35] SHAIK S V,BABU T P A.Theoretical performance investigation of vapour compression refrigeration system using HFC and HC refrigerant mixtures as alternatives to replace R22[J].Energy Procedia,2017,109:235|242.
[36] 崔群,陶刚,姚虎卿.固体吸附制冷吸附剂的研究进展[J].南京化工大学学报(自然科学版),1999(6):102|107.
[37] 严爱珍,鲍书林,颜贻春,等.沸石分子筛吸附式制冷 Ⅰ.沸石分子筛体系的选择[J].制冷学报,1982(4):24|33.
[38] 严爱珍,鲍书林,颜贻春,等.沸石分子筛吸附式制冷 Ⅱ.吸附式制冷的循环系统[J].制冷学报,1983(1):32|37.
[39] 朱日昭,秦正浩,邱里.水|蒸汽|硅胶制冷系统的研究[J].太阳能学报,1984(4):445|450.
[40] KORHAMMER K,NEUMANN K,OPEL O,et al.Thermodynamic and kinetic study of CaCl2|CH3OH adducts for solid sorption refrigeration by TGA/DSC[J].Applied Energy,2018,230:1255|1278.
[41] AZIZ A,HATAB S I,MOAWED M,et al.Experimental study on the effect of adsorber with three shapes of conductive material on performance of adsorption refrigeration tube using activated carbon/ethanol pair[J].Applied Thermal Engineering,2018,131:897|909.

备注/Memo

备注/Memo:
收稿日期:2019-10-23
作者简介:赵海谦(1981-),男,教授,博士,博士生导师,主要从事能源利用过程污染控制以及基于功能材料制备的节能技术研究.
更新日期/Last Update: 2020-09-30