Devices and methods of optimizing refrigerant flow in a heat exchanger

What is claimed is: 1 . A heat exchanger unit comprising: a plurality of heat exchanger coils, wherein (i) a first heat exchanger coil of the plurality of heat exchanger coils is disposed at a first location such that the first heat exchanger coil experiences a first airflow of air passing over the first heat exchanger coil and (ii) a second heat exchanger coil of the plurality of heat exchanger coils is disposed at a second location such that the second heat exchanger coil experiences a second airflow of air passing over the second heat exchanger coil, the first airflow being less than the second airflow; and a plurality of distributor tubes, each of the plurality of distributor tubes (i) being in fluid communication with a corresponding heat exchanger coil of the plurality of heat exchanger coils and (ii) being configured to direct a flow of refrigerant from an expansion valve to the corresponding heat exchanger coil of the plurality of heat exchanger coils, wherein a first distributor tube of the plurality of distributor tubes is configured to reduce a flow rate of refrigerant from the expansion valve to the first heat exchanger coil such that (i) a greater amount of refrigerant is directed to the second heat exchanger coil of the plurality of heat exchanger coils and (ii) refrigerant exits each heat exchanger coil of the plurality of heat exchanger coils as a superheated vapor refrigerant. 2 . The heat exchanger unit of claim 1 , wherein the first distributor tube of the plurality of distributor tubes is longer than a second distributor tube of the plurality of distributor tubes. 3 . The heat exchanger unit of claim 1 , wherein the first distributor tube of the plurality of distributor tubes comprises a greater number of bends than a number of bends in a second distributor tube of the plurality of distributor tubes. 4 . The heat exchanger unit of claim 1 , wherein the first distributor tube of the plurality of distributor tubes comprises a smaller inner diameter than a second distributor tube of the plurality of distributor tubes. 5 . The heat exchanger unit of claim 1 , wherein the first distributor tube of the plurality of distributor tubes comprises a constriction. 6 . The heat exchanger unit of claim 5 , wherein the constriction comprises a reduced cross-sectional area of the first distributor tube of the plurality of distributor tubes. 7 . The heat exchanger unit of claim 5 , wherein the constriction comprises a flow orifice. 8 . The heat exchanger unit of claim 7 , wherein the flow orifice comprises a single-stage flow orifice. 9 . The heat exchanger unit of claim 7 , wherein the flow orifice comprises a multi-stage flow orifice. 10 . The heat exchanger unit of claim 1 , wherein the first distributor tube of the plurality of distributor tubes comprises a valve configured to change a cross-sectional area of a flow path from the expansion valve to the heat exchanger coil. 11 . An air conditioning system comprising: a compressor; a condenser unit; an expansion valve; and an evaporator unit in fluid communication with the compressor, the condenser unit, and the expansion valve, the evaporator unit comprising: a plurality of heat exchanger coils, wherein (i) a first heat exchanger coil of the plurality of heat exchanger coils comprises a first length and (ii) a second heat exchanger coil of the plurality of heat exchanger coils comprises a second length, the first length being less than the second length; and a plurality of distributor tubes, each of the plurality of distributor tubes (i) being in fluid communication with a corresponding heat exchanger coil of the plurality of heat exchanger coils and (ii) being configured to direct a flow of refrigerant from an expansion valve to the corresponding heat exchanger coil of the plurality of heat exchanger coils, wherein a first distributor tube of the plurality of distributor tubes is configured to alter a flow rate of refrigerant from the expansion valve to the first heat exchanger coil such that (i) a greater amount of refrigerant is directed to the second heat exchanger coil of the plurality of heat exchanger coils and (ii) refrigerant exits each heat exchanger coil of the plurality of heat exchanger coils as a superheated vapor refrigerant. 12 . The air conditioning system of claim 11 , wherein the first distributor tube of the plurality of distributor tubes is longer than a second distributor tube of the plurality of distributor tubes. 13 . The air conditioning system of claim 11 , wherein the first distributor tube of the plurality of distributor tubes comprises a greater number of bends in the distributor tube than a number of bends in a second distributor tube of the plurality of distributor tubes. 14 . The air conditioning system of claim 11 , wherein the first distributor tube of the plurality of distributor tubes comprises a constriction. 15 . The air conditioning system of claim 14 , wherein the constriction comprises a reduced cross-sectional area of the first distributor tube of the plurality of distributor tubes. 16 . The air conditioning system of claim 14 , wherein the constriction comprises a flow orifice. 17 . The air conditioning system of claim 16 , wherein the flow orifice comprises a single-stage flow orifice. 18 . The air conditioning system of claim 16 , wherein the flow orifice comprises a multi-stage flow orifice. 19 . The air conditioning system of claim 11 , wherein the first distributor tube comprises a valve configured to change a cross-sectional area of a flow path from the expansion valve to the heat exchanger coil. 20 . The air conditioning system of claim 11 , wherein: a second distributor tube of the plurality of distributor tubes is shorter than the first distributor tube and a third distributor tube of the plurality of distributor tubes, the third distributor tube being in fluid communication with a third heat exchanger coil of the plurality of heat exchanger coils.