150                                         Defrosting for Air Source Heat Pump

         References


          [1] Wang F, Liang CH, Yang MT, Zhang XS. Preliminary study of a novel defrosting method
             for air source heat pumps based on superhydrophobic fin. Appl Therm Eng 2015;90:
             136–44.
          [2] Ye XM, Xia XH, Zhang JF. Optimal sampling plan for clean development mechanism
             energy efficiency lighting projects. Appl Energy 2013;112:1006–15.
          [3] Ni L, Dong JK, Yao Y, Shen C, Qv DH, Zhang XD. A review of heat pump systems for
             heating and cooling of buildings in China in the last decade. Renew Energy 2015;84:
             30–45.
          [4] Payne V, O’Neal DL. Defrost cycle performance for an air-source heat pump with a scroll
             and a reciprocating compressor. Int J Refrig 1995;18(2):107–12.
          [5] Song MJ, Deng SM, Xia L. A semi-empirical modeling study on the defrosting perfor-
             mance for an air source heat pump unit with local drainage of melted frost from its
             three-circuit outdoor coil. Appl Energy 2014;136:537–47.
          [6] Wang ZY, Wang XX, Dong ZM. Defrost improvement by heat pump refrigerant charge
             compensating. Appl Energy 2008;85:1050–9.
          [7] Song MJ, Pan DM, Li N, Deng SM. An experimental study on the negative effects of
             downwards flow of the melted frost over a multi-circuit outdoor coil in an air source heat
             pump during reverse cycle defrosting. Appl Energy 2015;138:598–604.
          [8] Song MJ, Deng SM, Pan DM, Mao N. An experimental study on the effects of downwards
             flowing of melted frost over a vertical multi-circuit outdoor coil in an air source heat pump
             on defrosting performance during reverse cycle defrosting. Appl Therm Eng 2014;67:
             258–65.
          [9] Qu ML, Xia L, Jiang YQ, Deng SM. A study of the reverse cycle defrosting performance
             on a multi-circuit outdoor coil in an air source heat pump-Part I: experiments. Appl Energy
             2012;91:122–9.
         [10] O’Neal DL, Peterson KT, Anand NK, Schliesing JS. Refrigeration system dynamics dur-
             ing the reversing cycle defrost. ASHRAE Trans 1989;95(2):689–98.
         [11] Ciriello V, Bottarelli M, Di Federico V. Uncertainty-based analysis of variations in sub-
             surface thermal field due to horizontal flat-panel heat exchangers. Proc Environ Sci
             2015;25:50–7.
         [12] Qi GP, Jiang F. Numerical investigation on prevention of fouling in the horizontal tube
             heat exchanger: particle distribution and pressure drop. Desalination 2015;367:112–25.
         [13] Dong JK, Deng SM, Jiang YQ, Xia L, Yao Y. An experimental study on defrosting heat
             supplies and energy consumptions during a reverse cycle defrost operation for an air
             source heat pump. Appl Therm Eng 2012;37:380–7.
         [14] Shen C, Jiang YQ, Yao Y, Deng SM. Experimental performance evaluation of a novel dry-
             expansion evaporator with defouling function in a wastewater source heat pump. Appl
             Energy 2012;95:202–9.
         [15] Adamson AW. Physical chemistry of surfaces. New York, NY: John Wiley; 1982.
         [16] Li LT, Wang W, Sun YY, Feng YC, Lu WP, Zhu JH, Ge YJ. Investigation of defrosting
             water retention on the surface of evaporator impacting the performance of air source heat
             pump during periodic frosting-defrosting cycles. Appl Energy 2014;135:98–107.
         [17] Kannadasan N, Ramanathan K, Suresh S. Comparison of heat transfer and pressure drop in
             horizontal and vertical helically coiled heat exchanger with CuO/water based nano fluids.
             Exp Thermal Fluid Sci 2012;42:64–70.
         [18] Yoon S, Lee SR, Go GH. Evaluation of thermal efficiency in different types of horizontal
             ground heat exchangers. Energy Buildings 2015;105:100–5.