二氧化碳热泵技术的发展及应用案例分析

doi:10.16085/j.issn.1000-6613.2016.s2.074

化工进展 ›› 2016, Vol. 35 ›› Issue (S2): 421-426.DOI: 10.16085/j.issn.1000-6613.2016.s2.074

二氧化碳热泵技术的发展及应用案例分析

李慧, 曹祥, 张春路

同济大学机械与能源工程学院, 上海 201804

收稿日期:2016-06-25 修回日期:2016-07-28 出版日期:2016-12-31 发布日期:2016-12-22
通讯作者: 张春路,博士、教授、博士生导师,主要研究方向为制冷空调系统仿真、优化及控制;先进制冷、热泵、空调系统。E-mail:chunlu.zhang@gmail.com。
作者简介:李慧(1991-),女,硕士研究生,主要从事空气源热泵热水器性能研究。

Developments and application analysis of carbon dioxide heat pump

LI Hui, CAO Xiang, ZHANG Chunlu

School of Mechanical Engineering, Tongji University, Shanghai 201804, China

Received:2016-06-25 Revised:2016-07-28 Online:2016-12-31 Published:2016-12-22

摘要/Abstract

摘要： CO₂跨临界热泵循环，其制冷剂工质为CO₂，不可燃，无毒，无刺激性气味，零臭氧层破坏能力（ODP=0）以及微乎其微的温室效应（GWP=1）而对环境无害，可从工业生产中回收，逐渐成为被广泛应用的热泵技术。本文从国内外CO₂热泵技术的研究现状及应用现状出发，总结概述了目前典型的CO₂热泵循环系统应用案例，如单级压缩供给加用热水系统、双级压缩带中间补气供给家用热水系统、家用供暖及供给热水于一体的双热泵单元家电辅热系统、大型公用建筑用CO₂热泵系统，并从系统层面对影响CO₂热泵循环系统效率的相关热力学参数进行循环分析，如水箱进出水温度、气冷器水流量、系统的制冷剂充注量等参数的控制。以期为未来CO₂热泵技术在中国的发展、进一步研究和应用设计提供一些参考和依据。

关键词: CO₂跨临界循环, 热泵技术, 系统

Abstract: Transcritical CO₂ heat pump cycle becmes one of the popular heat pump technology which was used widely all over the world,for its natural refrigerant,CO₂ has many advantages like low price,non-toxicity,non-flammability,environment friendliness and so on.In this study,we summarized some typical CO₂ heat pump systems,such as one-stage system for heating water,two-stage compressor system with middle gas branch,space heating and water heater system with electrical heaer supply,and water-side reversible CO₂ heat pump for residential application,which were in use and generalize the simulation research.Otherwise,we analysised the primary parameters that influences the system efficiency,such as the outlet temperature of the wate tank,the water mass flow rate of the gas cooler,the system refrigerants and so on.It could provide some worthy guidances for the design and development of carbon dioxide heat-pump system in China.

Key words: transcritical CO₂ cycle, heat pump, system

中图分类号:

TK172

李慧, 曹祥, 张春路. 二氧化碳热泵技术的发展及应用案例分析[J]. 化工进展, 2016, 35(S2): 421-426.

LI Hui, CAO Xiang, ZHANG Chunlu. Developments and application analysis of carbon dioxide heat pump[J]. Chemical Industry and Engineering Progree, 2016, 35(S2): 421-426.

参考文献

[1] IBRAHIM O,FARDOUN F,YOUNES R,et al.Review of water-heating systems:general selection approach based on energy and environmental aspects[J].Building and Environment,2014,72(1):259-286.
[2] VIEIRA A S,BEAL C D,STEWART R A.Residential water heaters in brisbane,australia:thinking beyond technology selection to enhance energy efficiency and level of service[J].Energy and Buildings,2014,82:222-236.
[3] IBRAHIM O,FARDOUN F,YOUNES R,et al.Optimal management proposal for hybrid water heating system[J].Energy and Buildings,2014,75(7):342-357.
[4] PEARSON A.Carbon dioxide-New uses for an old refrigerant[J].International Journal of Refrigeration,2005,28(8):1140-1148.
[5] NEKSÅ P.CO₂ heat pump systems[J].International Journal of Refrigeration,2002,25(4):421-427.
[6] Kim M H,Pettersen J,Bullard C W.Fundamental process and system design issues in CO₂ vapor compression systems[J].Progress in Energy and Combustion Science,2004,30(2):119-174.
[7] CAVALLINI A,CECCHINATO L,CORRADI M,et al. Two-stage transcritical carbon dioxide cycle optimisation:a theoretical and experimental analysis[J].International Journal of Refrigeration,2005,28(8):1274-1283.
[8] LORENTZEN G.Revival of carbon dioxide as a refrigerant[J].International Journal of Refrigeration,1994,17(5):292-301.
[9] ZHANG J F,QIN Y,WANG C C.Review on CO₂ heat pump water heater for residential use in Japan[J].Renewable and Sustainable Energy Reviews,2015,50(1):1383-1391.
[10] Kusakari K.Innovate hot water supply technology conductive to arresting global warming-development and significance of CO₂ heat pump water heate[C]//Proceedings of the 7th International Energy Agency Heat Pump Conference,Beijing,China,2002.
[11] 管海清,马一太,杨俊兰.日本家用CO₂热泵热水器研究开发现状分析[J].家电科技,2004,24(6):59-61.
[12] 梁艳.二氧化碳热泵系统蒸发器动态仿真研究[D].长沙:中南大学,2011.
[13] 陆蕾颖,张华,赵巍.CO₂热泵热水器的应用与发展[J].家电科技,2006,26(7):43-45.
[14] 杨宗凌,陈汝东.CO₂工质在热泵热水器中的应用[J].节能,2007,26(4):37-39.
[15] 陆军亮,钱永康,赵建峰,等.二氧化碳热泵热水器系统运行特性[J].节能,2016,35(1):31-34.
[16] 谌盈盈,廖胜明,黄珍珍.跨临界二氧化碳热泵热水系统气冷器的仿真分析[J].制冷与空调(四川),2007,21(4):26-31.
[17] 华楠楠.海尔自主研发二氧化碳冷媒技术带动行业变革[J].家电科技,2013(6):14-15.
[18] JAN,DUSEK K,SKACANOVA N,et al.Global trends for CO₂ heat pumps-a study of market,technology,and policy drivers in Japan,China,North America and Europe[C]//Proceedings of the ICR,2015.
[19] AUSTIN B T,SUMATHY K.Transcritical carbon dioxide heat pump systems:a review[J].Renewable and Sustainable Energy Reviews,2011,15(8):4013-4029.
[20] 王磊,俞建荣,董晓慧,等.CO₂热泵热水器和热泵压缩机的发展[J].北京石油化工学院学报,2014,22(1):16-19.
[21] SARKAR J,BHATTACHARYYA S,GOPAL M R.Optimization of a transcritical CO₂ heat pump cycle for simultaneous cooling and heating applications[J].International Journal of Refrigeration,2004,27(8):830-838.
[22] NEKSÅ P,REKSTAD H,ZAKERI G R,et al.CO₂-heat hump water heater:characteristics,system design and experimental results[J].International Journal of refrigeration,1998,21(3):172-179.
[23] HASHIMOTO K.Technology and market development of CO₂ heat pump water heaters(EcoCute)in Japan[J].IEA Heat Pump Centre Newsletter,2006,24(3):12-16.
[24] LIN K H,KUO C S,HSIEH W D,et al.Modeling and simulation of the transcritical CO₂ heat pump system[J].International Journal of Refrigeration,2013,36(8):2048-2064.
[25] KOBAYASHI M,KUWABARA O,HOSHINO S,et al. CO₂ heat pump heating and water heater systems for cold areas[J].IEA Heat Pump CENTRE,2008,26(3):70-79.
[26] MERINO S,KOBORI Y,ITO H.The development of the 9kW CO₂ heat pump water heater(3 phase 400V)for the european market[M].2010 International Symposium on Next-generation Air Conditioning and Refrigeration Technology,Tokyo,2010.
[27] SARKAR J,BHATTACHARYYA S,GOPAL M R. Simulation of a transcritical CO₂ heat pump cycle for simultaneous cooling and heating applications[J].International Journal of Refrigeration,2006,29(5):735-743.
[28] BYRNE P,MIRIEL J,LENAT Y.design and simulation of a heat pump for simultaneous heating and cooling using HFC or CO₂ as a working fluid[J].International Journal of Refrigeration,2009,32(7):1711-1723.
[29] MINETTO S,CECCHINATO L,BRIGNOLI R,et al. Water-side reversible CO₂ heat pump for residential application[J].International Journal of Refrigeration,2016,63(1):237-250.
[30] YANG L,LI H,CAI S W,et al.Minimizing COP Loss from optimal high pressure correlation for transcritical CO₂ cycle[J].Applied Thermal Engineering,2015,89(1):656-662.

二氧化碳热泵技术的发展及应用案例分析

Developments and application analysis of carbon dioxide heat pump

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