Study on hybrid ground-coupled heat pump systems

Energy and Buildings

Volumn 40, Issue 11, 2008, Pages 2028-2036

  Yi, Man ^a   Hongxing, Yang ^a   Zhaohong, Fang ^b  

^a HONG KONG POLYTECHNIC UNIVERSITY   (Hong Kong)

^b SHANDONG JIANZHU UNIVERSITY   (China)

Author keywords

Ground heat exchanger; Heat pump; Hybrid ground coupled heat pump systems; Initial and operating cost; Simulation model; Supplemental heat rejecter

Indexed keywords

AIR; AIR CONDITIONING; BUILDINGS; COOLING; COOLING SYSTEMS; COSTS; FINANCE; HEAT PUMP SYSTEMS; INDUSTRIAL ECONOMICS; OPERATING COSTS; PUMPS; SULFATE MINERALS;

AIR-CONDITIONING SYSTEMS; BUILDING LOAD; COMPUTER PROGRAMS; COUPLED HEAT; DESIGN METHODS; GROUND HEAT EXCHANGER; GROUND-COUPLED HEAT PUMP SYSTEMS; HEAT PUMP; HEAT-TRANSFER; HOURLY SIMULATION; HYBRID GROUND-COUPLED HEAT PUMP SYSTEMS; INITIAL AND OPERATING COST; INITIAL COSTS; OPERATING DATA; RUNNING CONTROL; SIMULATION MODEL; SIMULATION RESULTS; SUPPLEMENTAL HEAT; SUPPLEMENTAL HEAT REJECTER; SYSTEM PERFORMANCES;

COMPUTER OPERATING SYSTEMS;

EID: 50349093264     PISSN: 03787788     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enbuild.2008.05.010     Document Type: Article

References (18)

1. ASHRAE. Commercial/Institutional Ground-Source Heat Pump Engineering Manual (1995), American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc., Atlanta
2. C.S. Gilbreath, Hybrid ground-source heat pump systems for commercial applications, Master's Thesis, University of Alabama, Tuscaloosa, Alabama, 1996.
3. Kavanaugh S.P., and Rafferty K. Ground-source Heat Pumps: Design of Geothermal Systems for Commercial and Institutional Buildings (1997), American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc., Atlanta
4. Kavanaugh S.P. A design method for hybrid ground-source heat pumps. ASHRAE Transactions 104 2 (1998) 691-698
5. Phetteplace G., and Sullivan W. Performance of a hybrid ground-coupled heat pump system [J]. ASHRAE Transactions 104 1b (1998) 763-770
6. Singh J.B., and Foster G. Advantages of using the hybrid geothermal option. The Second Stockton International Geothermal Conference, The Richard Stockton College of New Jersey (1998)
7. Yavuzturk C., and Spitler J.D. Comparative study of operating and control strategies for hybrid ground-source heat pump systems using a short time step simulation model. ASHRAE Transactions 106 2 (2000) 192-209
8. Lewis W.K. The evaporation of liquid into gas. Transactions of the ASME 44 (1922) 325-340
9. Robinson C.S. The design of cooling towers. Mechanical Engineering 15 (1923) 99-102
10. M.F. Verdunstungskiihung, VDI Forschungsar beiten, No. 275, Berlin, Germany, 1925.
11. Baker D.R., and Mart L.T. Analyzing cooling tower performance by the unit-volume coefficient. Chemical Engineering (1952)
12. Baker D.R., and Shryock H.A. A comprehensive approach to the analysis of cooling tower performance. Journal of Heat Transfer 83 (1961) 339-349
13. Blanchard C.H. Coefficient of performance for finite-speed heat pump. Journal of Applied Physics 51 5 (1980) 2471-2472
14. Goth Y., and Feidt M. Optimum COP for endoreversible heat-pump or refrigerating machine. Comptes rendus de l'Academie des sciences, Paris 303 1 (1986) 19-24
15. Philippi I., and Feidt M. Finite-time thermodynamics applied to inverse cycle machines. Proceedings of the XVIII International Congress on Refrigeration. Montreal, Canada (1991)
16. Wu C., Chen L., and Sun F. Optimization of steady flow heat-pumps. Energy Conversion and Management 39 5/6 (1998) 445-453
17. Zeng H.Y., Diao N.R., and Fang Z.H. A finite line-source model for boreholes in geothermal heat exchangers [J]. Heat Transfer Asian Research 31 7 (2002) 558-567
18. Zeng H.Y., Diao N.R., and Fang Z.H. Heat transfer analysis of boreholes in vertical ground heat exchangers [J]. International Journal of Heat and Mass Transfer 46 23 (2003) 4467-4481