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           [19] Simms RB, Haslam SR, Craig JR. Impact of soil heterogeneity on the functioning of
               horizontal ground heat exchangers. Geothermics 2014;50:35–43.
           [20] Qu ML, Xia L, Deng SM, Jiang YQ. Improved indoor thermal comfort during defrost
               with a novel reverse-cycle defrosting method for air source heat pumps. Build Environ
               2010;45(11):2354–61.
           [21] Song MJ, Deng SM, Mao N, Ye XM. An experimental study on defrosting performance for
               an air source heat pump unit with a horizontally installed multi-circuit outdoor coil. Appl
               Energy 2016;165:371–82.
           [22] Hambraeus K. Heat transfer of oil-contaminated HFC134a in a horizontal evaporator. Int
               J Refrig 1995;18(2):87–99.
           [23] Liang CH, Wang F, Lv Y, Wu CX, Zhang XS, Zhang YF. Experimental study of the effects
               of fin surface characteristics on defrosting behavior. Appl Therm Eng 2015;75:86–92.
           [24] Yao Y, Jiang YQ, Deng SM, Ma ZL. A study on the performance of the airside heat
               exchanger under frosting in an air source heat pump water heater/chiller unit. Int
               J Heat Mass Transf 2004;47:17–8.
           [25] Song MJ, Wang ZH, Mao N, Li Z, Chen Y. An experimental study on the uneven refrig-
               erant distribution over a vertically installed multi-circuit outdoor coil in an air source heat
               pump unit during reverse cycle defrosting. Appl Therm Eng 2015;91:975–85.
           [26] Kim JH, Braun JE, Groll EA. A hybrid method for refrigerant flow balancing in multi-
               circuit evaporators: upstream versus downstream flow control. Int J Refrig 2009;32(6):
               1271–82.