Mobile QR Code QR CODE : Korean Journal of Air-Conditioning and Refrigeration Engineering
Korean Journal of Air-Conditioning and Refrigeration Engineering

Korean Journal of Air-Conditioning and Refrigeration Engineering

ISO Journal TitleKorean J. Air-Cond. Refrig. Eng.
  • Open Access, Monthly
Open Access Monthly
  • ISSN : 1229-6422 (Print)
  • ISSN : 2465-7611 (Online)
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  3. 2023-08 (Vol.35 No.08)
  4. 10.6110/KJACR.2023.35.8.371
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References

1 
Peureux, J. L., Sicard, F., and Bobelin, D., 2014, French Industrial Heat Pump Developments Applied to Heat Recovery, 11th IEA Heap Pump Conference.URL
2 
Peureux, J. L., Sapora, E., and Bobelin, D., 2012, Very High-temperature Heat Pumps Applied to Energy Efficiency in Industry, Frankfurt Achema, Application of Industrial Heat Pumps, pp. 1-23.URL
3 
Bobelin, D. and Bourig, A., 2012, Experimental Results of a Newly Developed Very High Temperature Industrial Heat Pump (140℃) Equipped with Scroll Compressors and Working with a New Blend Refrigerant, pp. 1-10.URL
4 
Arpagaus, C., Bless, F., Uhlmann, M., Schiffmann, J., and Bertsch, S. S., 2018, High Temperature Heat Pumps: Market Overview, State of the Art, Research Status, Refrigerants, and Application Potentials, Energy, Vol. 152, pp. 985-1010.DOI
5 
Wang, E., Na, S.-I., Lee, G., Baik, Y.-J., Lee, Y.-S., and Lee, B., 2018, Experimental Study on Heating Performance Characteristic of 100 kW Heat Pump to Generate℃ Steam, Korean Journal of Air-Conditioning and Refrigeration Engineering, Vol. 30, pp. 100-106.DOI
6 
Kang, D. H., Na, S.-I., Yoo, J. W., Lee, J. H., and Kim, M. S., 2019, Experimental Study on the Performance of a Steam Generation Heat Pump with the Internal Heat Exchanging Effect, International Journal of Refrigeration, Vol. 108, pp. 154-162.DOI
7 
Wu, D., Hu, B., Wang, R. Z., Fan, H., and Wang, R. Z., 2020, The Performance Comparison of High Temperature Heat Pump among R718 and other Refrigerants, Renew Energy, Vol. 154, pp. 715-722.DOI
8 
Arpagaus, C. and Bertsch, S., 2021, Experimental Comparison of HCFO and HFO R1224yd (Z), R1233zd (E), R1336mzz (Z), and HFC R245fa in a High Temperature Heat Pump up to 150°C Supply Temperature, International Refrigeration and Air Conditioning Conference, p. 2611.URL
9 
Wang, L., Zhao, J., Teng, J., Dong, S., Wang, Y., Xiang, S., and Sun, X., 2022, Study on an Energy-saving Process for Separation Ethylene elycol mixture through heat-pump, heat-integration and ORC driven by waste-heat, Energy, Vol. 243, p. 122985.DOI
10 
Yang, Z., Feng, B., Ma, H., Zhang, L., Duan, C., Liu, B., Zhang, Y., Chen, S., and Yang, Z., 2021, Analysis of Lower GWP and Flammable Alternative Refrigerants, International Journal of Refrigeration, Vol. 126, pp. 12-22.DOI
11 
Frate, G. F., Ferrari, L., and Desideri, U., 2019, Analysis of Suitability Ranges of High Temperature Heat Pump Working Fluids, Applied Thermal Engineering, Vol. 150, pp. 628-640.DOI
12 
Dai, X., Shi, L., An, Q., and Qian, W., 2018, Thermal Stability of Some Hydrofluorocarbons as Supercritical ORCs Working Fluids, Applied Thermal Engineering, Vol. 128, pp. 1095-1101.DOI
13 
Kontomaris, K., 2014, HFO-1336mzz-Z: High Temperature Chemical Stability and Use as a Working Fluid in Organic Rankine Cycles, 15th International Refrigeration and Air Conditioning Conference, p. 2550.URL
14 
Juhasz, J. R., and Simoni, L. D., 2015, A Review of Potential Working Fluids for Low Temperature Organic Rankine Cycles in Waste Heat Recovery, 3rd International Seminar on ORC Power Systems, pp. 1-10.URL
15 
Mateu-Royo, C., Navarro-Esbrí, J., Mota-Babiloni, A., Molés, F., and Amat-Albuixech, M., 2019, Experimental Exergy and Energy Analysis of a Novel High-temperature Heat Pump with Scroll Compressor for Waste Heat Recovery, Applied Energy, Vol. 253, p. 113504.DOI