Previous related work: A review                                    39

           [11] Amer M, Wang CC. Review of defrosting methods. Renew Sustain Energy Rev
               2017;73:53–74.
           [12] Song MJ, Dong JK, Wu CL, Jiang YQ, Qu ML. Studies on improving frosting and
               defrosting operation performances for air source heat pump: review and outlooks. HKIE
               Trans 2017;24(2):88–98.
           [13] Wang SW, Liu ZY. A new method for preventing heat pump from frosting. Renew Energy
               2005;30:753–61.
           [14] Wang FH, Wang ZH, Zheng YX, Lin Z, Hao PF, Huan C, Wang T. Performance inves-
               tigation of a novel frost-free air-source heat pump water heater combined with energy stor-
               age and dehumidification. Appl Energy 2015;139:212–9.
           [15] Wang ZH, Wang FH, Ma ZJ, Song MJ. Numerical study on the operating performances of
               a novel frost-free air-source heat pump unit using three different types of refrigerant. Appl
               Therm Eng 2017;112:248–58.
           [16] Wang ZH, Wang FH, Wang XK, Ma ZJ, Wu XZ, Song MJ. Dynamic character investi-
               gation and optimization of a novel air-source heat pump system. Appl Therm Eng
               2017;111:122–33.
           [17] Su W, Zhang XS. Performance analysis of a novel frost-free air-source heat pump with
               integrated membrane-based liquid desiccant dehumidification and humidification. Energy
               Build 2017;145:293–303.
           [18] Zhang L, Saikawa M, Fujinawa T. Experimental study on heat and mass transfer charac-
               teristics for a desiccant-coated fin-tube heat exchanger. Int J Heat Mass Transf
               2015;89:641–51.
           [19] Wang ZH, Zheng YX, Wang FH, Wang XK, Lin Z, Li JC, Huan C. Experimental analysis
               on a novel frost-free air-source heat pump water heater system. Appl Therm Eng 2014;70
               (1):808–16.
           [20] Jiang YQ, Fu HY, Yao Y, Yan L, Gao Q. Experimental study on concentration change of
               spray solution used for a novel non-frosting air source heat pump system. Energy Build
               2014;68:707–12.
           [21] Zhang L, Fujinawa T, Saikawa M. A new method for preventing air-source heat pump
               water heaters from frosting. In J Refrig 2012;35(5):1327–34.
           [22] Zhang L, Dang CB, Hihara E. Performance analysis of a no-frost hybrid air conditioning
               system with integrated liquid desiccant dehumidification. Int J Refrig 2010;33(1):116–24.
           [23] Liu D, Zhao FY, Tang GF. Frosting of heat pump with heat recovery facility. Renew
               Energy 2007;32(6):1228–42.
           [24] Kwak K, Bai C. A study on the performance enhancement of heat pump using electric
               heater under the frosting condition: heat pump under frosting condition. Appl Therm
               Eng 2010;30:539–43.
           [25] Tang JC, Gong GC, Su H, Wu FH, Herman C. Performance evaluation of a novel method
               of frost prevention and retardation for air source heat pumps using the orthogonal exper-
               iment design method. Appl Energy 2016;169:696–708.
           [26] Kragh J, Jørgen R, Svend S. Mechanical ventilation with heat recovery in cold climates.
               In: Proceedings of the seventh Nordic symposium on building physics in Nordic countries
               Technical University of Denmark; 2005. p. 1–8.
           [27] Song MJ. An experimental and numerical study on improving defrosting performances for
               an air source heat pump unit having a multi-circuit outdoor coil. The Hong Kong Poly-
               technic University; 2014 [PhD thesis].
           [28] Da Silva DL, Hermes CJ, Melo C. Experimental study of frost accumulation on fan-
               supplied tube-fin evaporators. Appl Therm Eng 2011;31:1013–20.