Heat exchanger

What is claimed is: 1. A heat exchanger adapted to carry out heat exchange between a refrigerant that undergoes a phase change during heat exchange and another heating medium, the heat exchanger comprising: headers having the refrigerant flowing through interiors thereof; a plurality of multi-hole first flat tubes extending in a horizontal direction intersecting a lengthwise direction of the headers, the multi-hole first flat tubes having a plurality of refrigerant flow channels formed therein, with the refrigerant flowing through the refrigerant flow channels; and a plurality of second flat tubes stacked alternately with respect to the plurality of multi-hole first flat tubes, the other heating medium flowing through the second flat tubes, the headers being arranged to extend along a horizontal direction, the plurality of refrigerant flow channels formed in the multi-hole first flat tubes are arranged to line up with each other along a vertical direction, and a flow channel cross-section of a lowermost tier refrigerant flow channel positioned lowermost of the plurality of refrigerant flow channels being larger than a flow channel cross-section of upper tier refrigerant flow channels positioned above the lowermost tier refrigerant flow channel. 2. The heat exchanger according to claim 1 , wherein grooves promoting heat transfer promotion are formed on surfaces of the upper tier refrigerant flow channels, but are not formed on surfaces of the lowermost tier refrigerant flow channel. 3. A heat exchanger adapted to carry out heat exchange between a refrigerant that undergoes a phase change during heat exchange and another heating medium, the heat exchanger comprising: headers having the refrigerant flowing through interiors thereof; a plurality of multi-hole first flat tubes extending in a horizontal direction intersecting a lengthwise direction of the headers, the multi-hole first flat tubes having a plurality of refrigerant flow channels formed therein, with the refrigerant flowing through the refrigerant flow channels; and a plurality of second flat tubes stacked alternately with respect to the plurality of multi-hole first flat tubes, the other heating medium flowing through the second flat tubes, the headers being arranged to extend along a horizontal direction, the headers including a header inlet section to receive the refrigerant and a header outlet section to outlet the refrigerant, the plurality of multi-hole first flat tubes communicating via communicating portions that include a tube inlet section to receive the other heating medium and a tube outlet section to outlet the other heating medium, the communicating portions extending along the lengthwise direction of the headers, the headers being arranged such that a header outlet section side is positioned below a header inlet section side, the second flat tubes including a heat transfer portion contacting the multi-hole first flat tubes, and the communicating portions being arranged below the heat transfer portion. 4. The heat exchanger according to claim 1 , wherein when the multi-hole first flat tubes have been fitted into the headers, a gap is formed between a bottom surface of the header interior and a bottom end of the multi-hole first flat tubes. 5. The heat exchanger according to claim 2 , wherein when the multi-hole first flat tubes have been fitted into the headers, a pan is formed between a bottom surface of the header interior and a bottom end of the multi-hole first flat tubes. 6. The heat exchanger according to claim 4 , wherein the headers include a header inlet section to receive the refrigerant and a header outlet section to outlet the refrigerant, the plurality of multi-hole first flat tubes communicate via communicating portions that include a tube inlet section to receive the other heating medium and a tube outlet section to outlet the other heating medium, the communicating portions extend along the lengthwise direction of the headers, and the headers are arranged such that a header outlet section side is positioned below a header inlet section side. 7. The heat exchanger according to claim 2 , wherein the headers include a header inlet section to receive the refrigerant and a header outlet section to outlet the refrigerant, the plurality of multi-hole first flat tubes communicate via communicating portions that include a tube inlet section to receive the other heating medium and a tube outlet section to outlet the other heating medium, the communicating portions extend along the lengthwise direction of the headers, and the headers are arranged such that a header outlet section side is positioned below a header inlet section side. 8. The heat exchanger according to claim 1 , wherein the headers include a header inlet section to receive the refrigerant and a header outlet section to outlet the refrigerant, the plurality of multi-hole first flat tubes communicate via communicating portions that include a tube inlet section to receive the other heating medium and a tube outlet section to outlet the other heating medium, the communicating portions extend along the lengthwise direction of the headers, and the headers are arranged such that a header outlet section side is positioned below a header inlet section side. 9. The heat exchanger according to claim 5 , wherein the headers include a header inlet section to receive the refrigerant and a header outlet section to outlet the refrigerant, the plurality of multi-hole first flat tubes communicate via communicating portions that include a tube inlet section to receive the other heating medium and a tube outlet section to outlet the other heating medium, the communicating portions extend along the lengthwise direction of the headers, and the headers are arranged such that a header outlet section side is positioned below a header inlet section side.