Heat exchanger and air-conditioning apparatus

1 . A heat exchanger comprising: a plurality of heat transfer tubes, the heat transfer tubes being disposed with a predetermined spacing from each other in an up and down direction; and a distributor configured to distribute refrigerant to the plurality of the heat transfer tubes, wherein the distributor includes a body part including a first inlet for refrigerant, and a first passage in which refrigerant entering through the first inlet flows upward, and a plurality of flow-splitting parts each including a second passage, each flow-splitting part communicating at a second inlet with the first passage and communicating at an outlet with one of the heat transfer tubes, and wherein the second inlets of at least two of the flow-splitting parts each communicate with the first passage at a location above the first inlet, wherein among the heat transfer tubes each communicating with the outlet of the flow-splitting part of which the second inlet communicates with the first passage at a location above the first inlet, at least a first one of the heat transfer tubes from top is defined as a first heat transfer tube, wherein among the heat transfer tubes each communicating with the outlet of the flow-splitting part of which the second inlet communicates with the first passage at a location above the first inlet, the heat transfer tube positioned below the first heat transfer tube is defined as a second heat transfer tube, wherein the flow-splitting part of which the outlet communicates with the first heat transfer tube is defined as a first flow-splitting part, wherein the flow-splitting part of which the outlet communicates with the second heat transfer tube is defined as a second flow-splitting part, and wherein the second inlet of the first flow-splitting part communicates with the first passage at a location below the second inlet of the second flow-splitting part that communicates with the first passage at a highest location. 2 . The heat exchanger of claim 1 , wherein the body part is a first tubular component, the first tubular component including the first passage defined inside the first tubular component, and wherein each flow-splitting part is a second tubular component, the second tubular component including the second passage defined inside the second tubular component. 3 . The heat exchanger of claim 2 , wherein an end portion defining the second inlet of the second tubular component protrudes into the first tubular component from a side of the first tubular component, and wherein the end portion of the second tubular component serving as the first flow-splitting part protrudes into the first tubular component by a length shorter than a length by which the end portion of the second tubular component serving as the second flow-splitting part protrudes into the first tubular component. 4 . The heat exchanger of claim 2 , wherein an end portion defining the second inlet of the second tubular component serving as the second flow-splitting part protrudes into the first tubular component from a side of the first tubular component, and wherein the end portion of the second tubular component serving as the first flow-splitting part does not protrude into the first tubular component. 5 . The heat exchanger of claim 2 , wherein an end portion defining the second inlet of the second tubular component serving as the first flow-splitting part is inserted into the first tubular component from an upper end of the first tubular component, wherein among a plurality of virtual planes that pass through the second inlet of the second tubular component serving as the second flow-splitting part and are perpendicular to a direction of flow of refrigerant in the first passage, a virtual plane located above the second inlet of the first flow-splitting part is defined as a first plane, and wherein the second tubular component serving as the first flow-splitting part extends through the first plane. 6 . The heat exchanger of claim 1 , wherein the distributor includes a third tubular component having an interior divided into an upper space and a lower space, a communication part configured to provide communication between the upper space and the lower space, at least one fourth tubular component configured to provide communication between the lower space and one of the second heat transfer tubes, and at least one fifth tubular component configured to provide communication between the upper space and one of the first heat transfer tubes, wherein an area in the third tubular component where the lower space is provided serves as the body part, wherein the lower space serves as the first passage, wherein the fourth tubular component serves as the second flow-splitting part, wherein the communication part, an area in the third tubular component where the upper space is provided, and the fifth tubular component serve as the first flow-splitting part, and wherein a location where the communication part communicates with the lower space serves as the second inlet of the first flow-splitting part. 7 . The heat exchanger of claim 6 , wherein the third tubular component and the communication part are formed integrally with each other. 8 . The heat exchanger of claim 1 , wherein the first heat transfer tube comprises at least two first heat transfer tubes, and wherein the first flow-splitting part comprises at least one first flow-splitting part, the second inlet of the at least one first flow-splitting parts comprises one second inlet, the outlet of the at least one first flow-splitting part comprises at least two outlets, and the at least one first flow-splitting part communicates with the at least two first heat transfer tubes. 9 . The heat exchanger of claim 1 , wherein as viewed in section taken perpendicular to a direction of flow of refrigerant in the first passage, refrigerant entering the second inlet of the first flow-splitting part flows in a direction different from a direction of flow of refrigerant entering the second inlet of the second flow-splitting part. 10 . The heat exchanger of claim 1 , wherein the distributor includes a first plate-like component including the first inlet, the first passage, the second inlet of the second flow-splitting part, the second passage of the second flow-splitting part, the second inlet of the first flow-splitting part, and the second passage of the first flow-splitting part, a second plate-like component disposed on one side of the first plate-like component, the second plate-like component including the outlet of the second flow-splitting part that communicates with the second inlet of the second flow-splitting part, and the outlet of the first flow-splitting part that communicates with the second inlet of the first flow-splitting part, and a third plate-like component disposed on an other side of the first plate-like component, and wherein the third plate-like component, the first plate-like component, and the second plate-like component are stacked on each other to form the distributor. 11 . The heat exchanger of claim 1 , wherein the second flow-splitting part of the distributor comprises at least two second flow-splitting parts, wherein the second inlet of the second flow-splitting part of which the second inlet is positioned lowest is defined as a reference, wherein a height, from the reference, of the second inlet of the second flow-splitting part of which the second inlet is positioned highest is defined as a first height, wherein a height of the second inlet of the first flow-splitting part from the reference is defined as a second height, and wherein a height ratio obtained by dividing