Performance of R744 commercial centralized refrigeration systems

doi:10.11949/j.issn.0438-1157.20181127

CIESC Journal ›› 2018, Vol. 69 ›› Issue (S2): 394-401.DOI: 10.11949/j.issn.0438-1157.20181127

Previous Articles Next Articles

Performance of R744 commercial centralized refrigeration systems

LIN Liguan¹, DAI Yanjun¹, HAFNER Armin²

1 Institute of Refrigeration and Cryogenies, Shanghai Jiao Tong University, Shanghai 200240, China;
2 Norwegian University of Science and Technology, Trondheim 7049, Norway

Received:2018-10-08 Revised:2018-10-16 Online:2018-12-31 Published:2018-12-31
Supported by:
supported by the National Natural Science Foundation of China (51736006).

两级R744超市中央制冷系统节能特性

林励冠¹, 代彦军¹, Hafner Armin²

1 上海交通大学制冷与低温研究所, 上海 200240;
2 挪威科技大学, 特隆赫姆 7049

通讯作者: 代彦军
基金资助:
国家自然科学基金重点项目（51736006）。

Abstract

Abstract:

Three R744 supermarket refrigeration systems are compared, including conventional booster system (CB), booster system with parallel compression (PC) and multi-ejector booster system with parallel compression (EJ). The parallel compressors in PC and EJ systems work under lower pressure ratio and consequently the energy of compressors decreases. In EJ systems, expansion valves are substituted by ejectors, so that the irreversible loss in the system could be lower. The air-conditioning system integrated with PC and EJ system are also discussed respectively. The optimal high side pressure of each system is confirmed. The value of high side pressure becomes larger when the outdoor temperature increases. When the ambient temperature is fixed, the multi-ejector system features the lowest high side pressure. The power consumption of each system is obtained by the simulation models. The results indicate that the power consumption of PC could be decreased, ranging from 6.8% to 12.3% compared to CB. And for EJ, the power consumption is even smaller, where the gap is 6.3% to 17.5%. Compared with HFC (hydrofluorocarbon), such as R404a, the R744 supermarket refrigeration system is of great energy saving potential in warm climates.

摘要：

比较了以二氧化碳（R744）为工质的超市中央制冷系统制冷技术方案，包括普通两级制冷（CB）、旁通压缩两级制冷（PC）和多引射器-旁通压缩耦合两级制冷（EJ），讨论了配置空调系统（AC）之后的功耗变化。根据计算得到，在环境温度20℃以上，相较于CB系统，PC系统的功耗减少了6.8%～12.3%；EJ系统功耗降低了6.3%～17.5%。在耦合了AC系统之后，相较于PC-AC系统，EJ-AC系统的功耗降低了4.9%～6.5%。与R404a系统相比，超市两级R744系统都有明显的节能效果。

CLC Number:

TB657.4

LIN Liguan, DAI Yanjun, HAFNER Armin. Performance of R744 commercial centralized refrigeration systems[J]. CIESC Journal, 2018, 69(S2): 394-401.

林励冠, 代彦军, Hafner Armin. 两级R744超市中央制冷系统节能特性[J]. 化工学报, 2018, 69(S2): 394-401.

References 23

[1]	PARLIAMENT E, COTE U.Regulation (EU) No 517/2014 of the European parliament and of the council of 16 April 2014 on fluorinated greenhouse gases and repealing regulation (EC) No 842/2006 Text with EEA relevance[J].Official J.Eur.Union, 2014, 57(L150):195-230.
[2]	LORENTZEN G, PETTERSEN J.A new, efficient and environ-mentally benign system for car air-conditioning[J].International Journal of Refrigeration, 1993, 16(1):4-12.
[3]	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.
[4]	CHOI K I, PAMITRAN A S, OH J T.Two-phase flow heat transfer of CO2 vaporization in smooth horizontal minichannels[J].International Journal of Refrigeration, 2007, 30(5):767-777.
[5]	POTTKER G, HRNJAK P.Effect of the condenser subcooling on the performance of vapor compression systems[J].International Journal of Refrigeration, 2015, 50:156-164.
[6]	LLOPIS R, CABELLO R, SANCHEZ D, et al.Energy improvements of CO2 transcritical refrigeration cycles using dedicated mechanical subcooling[J].International Journal of Refrigeration, 2015, 55:129-141.
[7]	LLOPIS R, NEBOT-ANDRÉS L, CABELLO R, et al.Experimental evaluation of a CO2 transcritical refrigeration plant with dedicated mechanical subcooling[J].International Journal of Refrigeration, 2016, 69:361-368.
[8]	DAI B, LIU S, LI H, et al.Energetic performance of transcritical CO2 refrigeration cycles with mechanical subcooling using zeotropic mixture as refrigerant[J].Energy, 2018, 150:205-221.
[9]	代宝民,刘圣春,孙志利,等.机械过冷CO2跨临界制冷循环性能理论分析[J].制冷学报, 2018, 39(1):13-19.DAI B M, LIU S C, SUN Z L, et al.Theoretical performance analysis of CO2 transcritical refrigeraion cycle with mechanical subcooling[J].Journal of Refrigeration, 2018, 39(1):13-19.
[10]	CHESI A, ESPOSITO F, FERRARA G, et al.Experimental analysis of R744 parallel compression cycle[J].Applied Energy, 2014, 135:274-285.
[11]	GULLO P, ELMEGAARD B, CORTELLA G.Advanced exergy analysis of a R744 booster refrigeration system with parallel compression[J].Energy, 2016, 107:562-571.
[12]	SARKAR J, AGRAWAL N.Performance optimization of transcritical CO2 cycle with parallel compression economization[J].International Journal of Thermal Sciences, 2010, 49(5):838-843.
[13]	TSAMOS K M, GE Y T, SANTOSA I, et al.Energy analysis of alternative CO2 refrigeration system configurations for retail food applications in moderate and warm climates[J].Energy Conversion and Management, 2017, 150:822-829.
[14]	HAFNER A, FöRSTERLING S, BANASIAK K.Multi-ejector concept for R-744 supermarket refrigeration[J].International Journal of Refrigeration, 2014, 43:1-13.
[15]	HAIDA M, BANASIAK K, SMOLKA J, et al.Experimental analysis of the R744 vapour compression rack equipped with the multi-ejector expansion work recovery module[J].International Journal of Refrige-ration, 2016, 64:93-107.
[16]	MINETTO S, BRIGNOLI R, ZILIO C, et al.Experimental analysis of a new method for overfeeding multiple evaporators in refrigeration systems[J].International Journal of Refrigeration, 2014, 38:1-9.
[17]	PARDIñAS Á Á, HAFNER A, BANASIAK K.Novel integrated CO2 vapour compression racks for supermarkets.Thermodynamic analysis of possible system configurations and influence of operational conditions[J].Applied Thermal Engineering, 2018, 131:1008.
[18]	CECCHINATO L, CORRADI M, MINETTO S.Energy performance of supermarket refrigeration and air conditioning integrated systems[J].Applied Thermal Engineering, 2010, 30(14):1946.
[19]	CECCHINATO L, CORRADI M, MINETTO S.Energy performance of supermarket refrigeration and air conditioning integrated systems working with natural refrigerants[J].Applied Thermal Engineering, 2012, 48:378.
[20]	ELBEL S, HRNJAK P.Experimental validation of a prototype ejector designed to reduce throttling losses encountered in transcritical R744 system operation[J].International Journal of Refrigeration, 2008, 31(3):411.
[21]	ZHANG M.Energy analysis of various supermarket refrigeration systems[C]//Proceedings of the 11th International Refrigeration and Air Conditioning Conference.2006:Paper 856.
[22]	GULLO P, HAFNER A, CORTELLA G.Multi-ejector R744 booster refrigerating plant and air conditioning system integration-a theore-tical evaluation of energy benefits for supermarket applications[J].International Journal of Refrigeration, 2017, 75:164.
[23]	CAVALLINI A, ZILIO C.Carbon dioxide as a natural refrigerant[J].International Journal of Low-Carbon Technologies, 2007, 2(2):225.

Performance of R744 commercial centralized refrigeration systems

两级R744超市中央制冷系统节能特性

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References 23

Related Articles 1

Recommended Articles

Metrics

Comments