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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. 2024-04 (Vol.36 No.04)
  4. 10.6110/KJACR.2024.36.4.185
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References

1 
Rybach, L. and Sanner, B., 2000, Ground Source Heat Pump Systems, the European Experience, GHC Bull, Vol. 21, No. 1, pp. 16-26.DOI
2 
Pambou, C. H. K., Raymond, J., Miranda, M. M., and Giordano, N., 2022, Estimation of in Situ Heat Capacity and Thermal Diffusivity from Undisturbed Ground Temperature Profile Measured in Ground Heat Exchangers, Geosciences, Vol. 12, No. 5, p. 180.DOI
3 
Luo, J., Rohn, J., Bayer, M., Priess, A., Wilkmann, L., and Xiang, W., 2015, Heating and Cooling Performance Analysis of a Ground Source Heat Pump System in Southern Germany, Geothermics, Vol. 53, pp. 57-66.DOI
4 
Yavuzturk, C. and Spitler, J. D., 2000, Comparative Study of Operating and Control Strategies for Hybrid Ground-source Heat Pump Systems Using a Short Time Step Simulation Model, Ashrae Transactions, Vol. 106, p. 192.URL
5 
Xu, L., Pu, L., Zhang, S., and Li, Y., 2021, Hybrid Ground Source Heat Pump System for Overcoming Soil Thermal Imbalance: A Review, Sustainable Energy Technologies and Assessments, Vol. 44, p. 101098.DOI
6 
Park, H., Lee, J. S., Kim, W., and Kim, Y., 2012, Performance Optimization of a Hybrid Ground Source Heat Pump with the Parallel Configuration of a Ground Heat Exchanger and a Supplemental Heat Rejecter in the Cooling Mode, International Journal of Refrigeration, Vol. 35, No. 6, pp. 1537-1546.DOI
7 
Baek, S. H., Yeo, M. S., and Kim, K. W., 2017, Effects of the Geothermal Load on the Ground Temperature Recovery in a Ground Heat Exchanger, Energy and Buildings, Vol. 136, pp. 63-72.DOI
8 
Bae, S. and Nam, Y., 2022, Economic and Environmental Analysis of Ground Source Heat Pump System According to Operation Methods, Geothermics, Vol. 101, p. 102373.DOI
9 
Park, 2023, Design and Operating Strategy of A Novel Hybrid Ground Source Heat Pump System (Ph.D. dissertation), Inha University, Incheon, Korea.URL
10 
Bayer, P., de Paly, M., and Beck, M., 2014, Strategic Optimization of Borehole Heat Exchanger Field for Seasonal Geothermal Heating and Cooling, Applied Energy, Vol. 136, pp. 445-453.DOI
11 
Zeng, H. Y., Diao, N. R., and Fang, Z. H., 2002, A Finite Line-source Model for Boreholes in Geothermal Heat Exchangers, Heat Transfer—Asian Research: Co-sponsored by the Society of Chemical Engineers of Japan and the Heat Transfer Division of ASME, Vol. 31, No. 7, pp. 558-567.DOI
12 
Lamarche, L. and Beauchamp, B., 2007, A New Contribution to the Finite Line-source Model for Geothermal Boreholes, Energy and Buildings, Vol. 39, No. 2, pp. 188-198.DOI
13 
Hellström, G., 1989, Duct Ground Heat Storage Model, Manual for Computer Code, Department of Mathematical Physics, University of Lund, Sweden.URL
14 
Bernier, M. A., 2001, Ground-coupled Heat Pump System Simulation/Discussion, ASHRAE Transactions, Vol. 107, p. 605.URL
15 
Remund, C. P., 1999, Borehole Thermal Resistance: Laboratory and Field Studies, ASHRAE Transactions, Vol. 105, p. 439.DOI
16 
Kim, E. J., 2018, TRNSYS g-function Generator Using a Simple Boundary Condition, Energy and Buildings, Vol. 172, pp. 192-200.DOI
17 
Park, S. H., Jang, Y. S., and Kim, E. J., 2018, Using Duct Storage (DST) Model for Irregular Arrangements of Borehole Heat Exchangers, Energy, Vol. 142, pp. 851-861.DOI
18 
Yavuzturk, C. and Spitler, J. D., 1999, A Short Time Step Response Factor Model for Vertical Ground Loop Heat Exchangers, ASHRAE Transactions, Vol. 105, No. 2, pp. 475-485.URL