Efficiency of the heat pump cooperating with various heat sources in monovalent and bivalent systems

• Autorzy: Kurpaska S. , Latala H. , Lapczynska-Kordon B. , Mudryk K.

Warianty tytułu

PL

Efektywnosc pompy ciepla wspolpracujacej z dolnymi zrodlami ciepla w systemie mono i biwalentnym

• Języki publikacji: EN

Abstrakty

EN

PL

Słowa kluczowe

EN

heat pump; heat source; heat distribution; monovalent system; bivalent system; compressor heat pump; vertical exchanger; horizontal exchanger; coefficient performance; heating system

• Wydawca: -
• Czasopismo: Teka Komisji Motoryzacji i Energetyki Rolnictwa
• Rocznik: 2012
• Tom: 12
• Numer: 1
• Opis fizyczny: p.109-113,fig.,ref.

Twórcy

autor

Kurpaska S.

• Faculty of Power Engineering and Energetic, University of Agriculture in Krakow, Balicka 116B, 30-149 Krakow, Poland

autor

Latala H.

autor

Lapczynska-Kordon B.

autor

Mudryk K.

Bibliografia

• 1. Benli H. 2011. Energetic performance analysis of a ground-source heat pump system with latent heat storage for a greenhouse heating Energy Conversion and Management 52, p. 581-589.
• 2. Benli H, Durmus A. 2009. Evaluation of ground-source heat pump combined latent heat storage system performance in greenhouse heating. Energy Buildings 41, p. 220-228.
• 3. Boulard T, Razafinjohany E, Baille A, Jaffrin A, Fabre B. 2003. Performance of greenhouse heating system with a phase change material. Agric Forest Meteorology, 52, p. 303-318.
• 4. Esen H., Intali, Esen M. 2006. Numerical and experimental analysis of a horizontal ground-coupled heat pump system. Building and Environment, 42(3), p. 1126-1134.
• 5. Hawlader M.N.A., Chou S.K., Ullah M.Z. 2001. The performance of a solar assisted heat pump water heating system. Applied Thermal Engineering, 21(10), p. 10491065.
• 6. Hepbasli A., Akdemir O., Hancioglu E. 2003. Experimental study of a closed loop vertical ground heat pump system. Energy Conversion and Management, 42(4), p. 527-548.
• 7. Katsunori N, Takao K, Sayaka T. 2006. Development of a design and performance prediction tool for the ground-source heat pump system. Applied Thermal Engineering 26, p. 1578-1592.
• 8. Kaygusuz K., Ayhan T. 1999. Experimental and theoretical investigation of combined solar heat pump system for residential heating. Energy Conversion and Management, 40(13), p. 1377-1396.
• 9. Kaygusuz K. 1995. Performance of solar-assisted heat pump systems. Applied Energy, 51(2), p. 93-109.
• 10. Knaga J. 2007. Changeability of heat output of heat pump with scroll type compressor, TEKA Commission of Motorization and Power Industry in Agriculture VIIA, p. 41-46.
• 11. Knaga J. 2008. Energy efficiency of small compressor assisted airwater type heat pumps, TEKA Commission of Motorization and Power Industry in Agriculture VIII 2008, p. 99-106.
• 12. Kurpaska S. 2007. Energy analysis for lower heat sources of heating pump while heating a plastic tunnel (in Polish). Inżynieria Rolnicza, 9(97), p. 103-111.
• 13. Nagano K., Katsura T., Takeda S. 2006. Development of a design and performance prediction tool for the ground source heat pump system. Applied Thermal Engineering, 26(14-15), p. 1578-1592.
• 14. Ozgener O, Hepbasli A. 2004. Experimental performance analysis of a solar assisted ground-source heat pump greenhouse heating system. Renewable Energy, 37, p. 101-110.
• 15. Trillat-Berdal V., Souyri B., Fraisse G. 2006. Experimental study of a ground-coupled heat pump combined with thermal solar collectors. Energy and Buildings, 28(12), p. 1477-1484.
• 16. Xu G., Zhang A., Deng S. 2006. simulation study on the operating performance of a solar-air source heat pump water heater. Applied Thermal Engineering, 26 (11-12), p. 1257-1265.
• 17. Yumruta R., Unsal M. 2000. A computational model of a heat pump system with a hemispherical surface tank as a ground heat source. Energy, 25(4), p. 371-388.