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Year 2018, , 214 - 219, 04.12.2018
https://doi.org/10.5541/ijot.435774

Abstract

References

  • [1] P. Byrne, J. Miriel, Y. Lenat, “Experimental study of an air-source heat pump for simultaneous heating and cooling – Part 2: Dynamic behaviour and two-phase thermosiphon defrosting technique,” Appl. Energy, 88, 3072-3078, 2011.[2] W. J. Hu, Y. Q. Jiang, M. L. Qu, L. Ni, Y. Yao, S. M. Deng, “An experimental study on the operating performance of a novel reverse-cycle hot gas defrosting method for air source heat pumps,” Appl. Therm. Eng., 31, 363-369, 2011.[3] M. L. Qu, L. Xia, S. M. Deng, Y. Q. Jiang, “A study of the reverse cycle defrosting performance on a multi-circuit outdoor coil unit in an air source heat pump – Part I: Experiments,” Appl. Energy, 91, 122-129, 2012.[4] Z. Y. Wang, H. X. Yang, S. Chen, “Study on the operating performance of cross hot-gas bypass defrosting system for air-to-water screw heat pumps,” Appl. Therm. Eng., 59, 398-404, 2013.[5] N. Hoffenbecker, S. A. Klein, D. T. Reindl, “Hot gas defrost model development and validation,” Int. J. Refrig., 28, 605-615, 2005.[6] H. J. Yin, Z. Yang, A. Q. Chen, N. Zhang, “Experimental research on a novel cold storage defrost method based on air bypass circulation and electric heater,” Energy, 37, 623-631, 2012.[7] K. Kwak, C. Bai, “A study on the performance enhancement of heat pump using electric heater under the frosting condition: Heat pump under frosting condition,” Appl. Therm. Eng., 30, 539-543, 2010.[8] S. A. Tassou, D. Datta, D. Marriott, “Frost formation and defrost control parameters for open multideck refrigerated food display cabinets,” Proceedings of the Institution of Mechanical Engineers Part A Journal of Power & Energy, 215, 213-222, 2001.[9] J. Xiao, W. Wang, Y. H. Zhao, F. R. Zhang, “An analysis of the feasibility and characteristics of photoelectric technique applied in defrost-control,” Int. J. Refrig., 32, 1350-1357, 2009.[10] M. H. Kim, K. S. Lee, “Determination method of defrosting start-time based on temperature measurements,” Appl. Energy, 146, 263-269, 2015.[11] Y. Hayashi, A. Aoki, S. Adachi, K. Hori, “Study of frost properties correlating with frost formation types,” J. Heat Transfer, 99, 239, 1977.[12] Y. J. Ge, Y. Y. Sun, W. Wang, J. H. Zhu, L. T. Li, J. D. Liu, “Field test study of a novel defrosting control method for air-source heat pumps by applying tube encircled photoelectric sensors,” Int. J. Refrig., 66, 133-144, 2016.[13] M. J. Song, X. J. Wang, L. Y. Liao, S. M. Deng, “Termination Control Temperature Study for an Air Source Heat Pump Unit During Its Reverse Cycle Defrosting,” Energy Procedia, 105, 335-342, 2017.[14] Y. Q. Jiang, J. K. Dong, M. L. Qu, S. M. Deng, Y. Yao, “A novel defrosting control method based on the degree of refrigerant superheat for air source heat pumps,” Int. J. Refrig., 36, 2278-2288, 2013.[15] H. H. Tan, G. H. Xu, F. T. Tao, X. Q. Sun, W. D. Yao, “Experimental investigation on the defrosting performance of a finned-tube evaporator using intermittent ultrasonic vibration,” Appl. Energy, 158, 220-232, 2015.[16] Y. C. Yoon, H. J. Jeong, K. S. Lee, “Adaptive defrost methods for improving defrosting efficiency of household refrigerator,” Energy Conversion & Management, 157, 511-516, 2018.[17] J. Allard, R. Heinzen, “Adaptive defrost,” IEEE Transactions on Industry Applications, 24, 39-42, 1988.[18] Z. Y. Wang, X. M. Wang, Z. M. Dong, “Defrost improvement by heat pump refrigerant charge compensating,” Appl. Energy, 85, 1050-1059, 2008.[19] J. H. Zhu, Y. Y. Sun, W. Wang, Y. J. Ge, L. T. Li, J. D. Liu, “A novel Temperature–Humidity–Time defrosting control method based on a frosting map for air-source heat pumps,” Intern. J. Refrig., 54, 45-54, 2015.

Investigation of Control Process in Liquid Refrigerant Defrosting System

Year 2018, , 214 - 219, 04.12.2018
https://doi.org/10.5541/ijot.435774

Abstract



The liquid refrigerant defrosting system (LRDS) has the
advantages that the refrigeration process is continuous, the temperature
fluctuation of the cold storage is small, and the cooling energy of the frost
can be recovered effectively. However, the system is too complex to apply and
promote in the modern cold storage. In order to solve the problem of operation
difficulty, the control experiments were carried out, including the beginning
of the defrosting (BD), the end of the defrosting (ED), the draining time (DT)
and the time difference between the two air coolers start-up (TDTACS). The
results showed that the LRDS started to defrost when the air pressure
difference was higher than 0.5mbar. The outlet should be located at the middle
part of the lower 1/3 part of the evaporation surface. The measuring pressure
tube inserted the fin 20mm, and the nozzle was perpendicular to the evaporation
pipe. The experimental ambient temperature was 30
, and the frost mass
was 3kg. The gas return temperature at the ED was 3.0
, 4.0, 5.0, 6.4 and 7.4 respectively when
the cold storage temperature was 0
, 5, 10, 15 and 20 respectively. The DT
was controlled between 140s and 180s, which could prevent the wet compression.
In order to get the TDTACS, the manual control could be adopted for the first
defrosting. Then the air pressure difference control could be used. The two air
coolers could refrigerate and defrost alternately.




References

  • [1] P. Byrne, J. Miriel, Y. Lenat, “Experimental study of an air-source heat pump for simultaneous heating and cooling – Part 2: Dynamic behaviour and two-phase thermosiphon defrosting technique,” Appl. Energy, 88, 3072-3078, 2011.[2] W. J. Hu, Y. Q. Jiang, M. L. Qu, L. Ni, Y. Yao, S. M. Deng, “An experimental study on the operating performance of a novel reverse-cycle hot gas defrosting method for air source heat pumps,” Appl. Therm. Eng., 31, 363-369, 2011.[3] M. L. Qu, L. Xia, S. M. Deng, Y. Q. Jiang, “A study of the reverse cycle defrosting performance on a multi-circuit outdoor coil unit in an air source heat pump – Part I: Experiments,” Appl. Energy, 91, 122-129, 2012.[4] Z. Y. Wang, H. X. Yang, S. Chen, “Study on the operating performance of cross hot-gas bypass defrosting system for air-to-water screw heat pumps,” Appl. Therm. Eng., 59, 398-404, 2013.[5] N. Hoffenbecker, S. A. Klein, D. T. Reindl, “Hot gas defrost model development and validation,” Int. J. Refrig., 28, 605-615, 2005.[6] H. J. Yin, Z. Yang, A. Q. Chen, N. Zhang, “Experimental research on a novel cold storage defrost method based on air bypass circulation and electric heater,” Energy, 37, 623-631, 2012.[7] K. Kwak, C. Bai, “A study on the performance enhancement of heat pump using electric heater under the frosting condition: Heat pump under frosting condition,” Appl. Therm. Eng., 30, 539-543, 2010.[8] S. A. Tassou, D. Datta, D. Marriott, “Frost formation and defrost control parameters for open multideck refrigerated food display cabinets,” Proceedings of the Institution of Mechanical Engineers Part A Journal of Power & Energy, 215, 213-222, 2001.[9] J. Xiao, W. Wang, Y. H. Zhao, F. R. Zhang, “An analysis of the feasibility and characteristics of photoelectric technique applied in defrost-control,” Int. J. Refrig., 32, 1350-1357, 2009.[10] M. H. Kim, K. S. Lee, “Determination method of defrosting start-time based on temperature measurements,” Appl. Energy, 146, 263-269, 2015.[11] Y. Hayashi, A. Aoki, S. Adachi, K. Hori, “Study of frost properties correlating with frost formation types,” J. Heat Transfer, 99, 239, 1977.[12] Y. J. Ge, Y. Y. Sun, W. Wang, J. H. Zhu, L. T. Li, J. D. Liu, “Field test study of a novel defrosting control method for air-source heat pumps by applying tube encircled photoelectric sensors,” Int. J. Refrig., 66, 133-144, 2016.[13] M. J. Song, X. J. Wang, L. Y. Liao, S. M. Deng, “Termination Control Temperature Study for an Air Source Heat Pump Unit During Its Reverse Cycle Defrosting,” Energy Procedia, 105, 335-342, 2017.[14] Y. Q. Jiang, J. K. Dong, M. L. Qu, S. M. Deng, Y. Yao, “A novel defrosting control method based on the degree of refrigerant superheat for air source heat pumps,” Int. J. Refrig., 36, 2278-2288, 2013.[15] H. H. Tan, G. H. Xu, F. T. Tao, X. Q. Sun, W. D. Yao, “Experimental investigation on the defrosting performance of a finned-tube evaporator using intermittent ultrasonic vibration,” Appl. Energy, 158, 220-232, 2015.[16] Y. C. Yoon, H. J. Jeong, K. S. Lee, “Adaptive defrost methods for improving defrosting efficiency of household refrigerator,” Energy Conversion & Management, 157, 511-516, 2018.[17] J. Allard, R. Heinzen, “Adaptive defrost,” IEEE Transactions on Industry Applications, 24, 39-42, 1988.[18] Z. Y. Wang, X. M. Wang, Z. M. Dong, “Defrost improvement by heat pump refrigerant charge compensating,” Appl. Energy, 85, 1050-1059, 2008.[19] J. H. Zhu, Y. Y. Sun, W. Wang, Y. J. Ge, L. T. Li, J. D. Liu, “A novel Temperature–Humidity–Time defrosting control method based on a frosting map for air-source heat pumps,” Intern. J. Refrig., 54, 45-54, 2015.
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Details

Primary Language English
Subjects Engineering
Journal Section Regular Original Research Article
Authors

Meng Wang

Runqing Zang This is me

Yanhe Li This is me

Wenqing Li This is me

Publication Date December 4, 2018
Published in Issue Year 2018

Cite

APA Wang, M., Zang, R., Li, Y., Li, W. (2018). Investigation of Control Process in Liquid Refrigerant Defrosting System. International Journal of Thermodynamics, 21(4), 214-219. https://doi.org/10.5541/ijot.435774
AMA Wang M, Zang R, Li Y, Li W. Investigation of Control Process in Liquid Refrigerant Defrosting System. International Journal of Thermodynamics. December 2018;21(4):214-219. doi:10.5541/ijot.435774
Chicago Wang, Meng, Runqing Zang, Yanhe Li, and Wenqing Li. “Investigation of Control Process in Liquid Refrigerant Defrosting System”. International Journal of Thermodynamics 21, no. 4 (December 2018): 214-19. https://doi.org/10.5541/ijot.435774.
EndNote Wang M, Zang R, Li Y, Li W (December 1, 2018) Investigation of Control Process in Liquid Refrigerant Defrosting System. International Journal of Thermodynamics 21 4 214–219.
IEEE M. Wang, R. Zang, Y. Li, and W. Li, “Investigation of Control Process in Liquid Refrigerant Defrosting System”, International Journal of Thermodynamics, vol. 21, no. 4, pp. 214–219, 2018, doi: 10.5541/ijot.435774.
ISNAD Wang, Meng et al. “Investigation of Control Process in Liquid Refrigerant Defrosting System”. International Journal of Thermodynamics 21/4 (December 2018), 214-219. https://doi.org/10.5541/ijot.435774.
JAMA Wang M, Zang R, Li Y, Li W. Investigation of Control Process in Liquid Refrigerant Defrosting System. International Journal of Thermodynamics. 2018;21:214–219.
MLA Wang, Meng et al. “Investigation of Control Process in Liquid Refrigerant Defrosting System”. International Journal of Thermodynamics, vol. 21, no. 4, 2018, pp. 214-9, doi:10.5541/ijot.435774.
Vancouver Wang M, Zang R, Li Y, Li W. Investigation of Control Process in Liquid Refrigerant Defrosting System. International Journal of Thermodynamics. 2018;21(4):214-9.