Heat exchanger and air conditioner

1 . A heat exchanger configured to exchange heat between a refrigerant flowing through a plurality of flat tubes and air, the heat exchanger comprising: a windward tube bank and a leeward tube bank arranged in a flow direction of the air, each of which being constituted of the plurality of flat tubes arranged one above the other; and fins jointed to the flat tubes, wherein the windward tube bank is divided into a principal windward bank portion and an auxiliary windward bank portion, each of which being constituted of the plurality of the flat tubes arranged one above the other, the auxiliary windward bank portion is located below the principal windward bank portion, and is constituted of the flat tubes smaller in number than the flat tubes of the principal windward bank portion, the leeward tube bank is divided into a principal leeward bank portion and an auxiliary leeward bank portion, each of which being constituted of the plurality of flat tubes arranged one above the other, the auxiliary leeward bank portion is located below the principal leeward bank portion, and is constituted of the flat tubes smaller in number than the flat tubes of the principal leeward bank portion, the heat exchanger further comprises a header collecting pipe connected to one end of each of the flat tubes constituting the principal leeward bank portion to form principal communicating spaces communicating with the plurality of flat tubes, the auxiliary windward bank portion, the auxiliary leeward bank portion, the header collecting pipe, the principal leeward bank portion, and the principal windward bank portion are arranged in series in a refrigerant flow path, the refrigerant flows from the auxiliary windward bank portion to the principal windward bank portion in this order when the heat exchanger functions as an evaporator, and the refrigerant flows from the principal windward bank portion to the auxiliary windward bank portion in this order when the heat exchanger functions as a condenser. 2 . The heat exchanger of claim 1 , wherein the number of the flat tubes constituting the principal windward bank portion is equal to the number of the flat tubes constituting the principal leeward bank portion, and the number of the flat tubes constituting the auxiliary windward bank portion is equal to the number of the flat tubes constituting the auxiliary leeward bank portion. 3 . The heat exchanger of claim 1 , wherein the principal windward bank portion is further divided into a plurality of principal windward bank blocks, each of which being constituted of the plurality of the flat tubes arranged one above the other, the principal leeward bank portion is further divided into a plurality of principal leeward bank blocks, each of which being constituted of the plurality of flat tubes arranged one above the other, the number of the principal windward bank blocks is equal to the number of the principal leeward bank blocks, and the principal windward bank blocks and the principal leeward bank blocks form mutually different pairs, in each of which the principal windward bank block and the principal leeward bank block are arranged in series in the refrigerant flow path. 4 . The heat exchanger of claim 3 , wherein in each of the mutually different pairs, the number of the flat tubes constituting the principal windward bank block is equal to the number of the flat tubes constituting the principal leeward bank block. 5 . The heat exchanger of claim 4 , wherein in each of the mutually different pairs, the flat tubes constituting the principal windward bank block and the flat tubes constituting the principal leeward bank block are individually connected one by one. 6 . The heat exchanger of claim 3 , wherein the header collecting pipe is formed with as many the principal communicating spaces as the principal leeward bank blocks, and the principal communicating spaces and the principal leeward bank blocks form mutually different pairs, in each of which the principal communicating space communicates with the flat tubes constituting the principal leeward bank block. 7 . The heat exchanger of claim 1 , wherein the auxiliary windward bank portion is further divided into a plurality of auxiliary windward bank blocks, each of which being constituted of the plurality of the flat tubes arranged one above the other, the auxiliary leeward bank portion is further divided into a plurality of auxiliary leeward bank blocks, each of which being constituted of the plurality of flat tubes arranged one above the other, the number of the auxiliary windward bank blocks is equal to the number of the auxiliary leeward bank blocks, the auxiliary windward bank blocks and the auxiliary leeward bank blocks form mutually different pairs, and the auxiliary windward bank block and the auxiliary leeward bank block in each of the mutually different pairs are arranged in series in the refrigerant flow path. 8 . The heat exchanger of claim 7 , wherein in each of the mutually different pairs, the number of the flat tubes constituting the auxiliary windward bank block is equal to the number of the flat tubes constituting the auxiliary leeward bank block. 9 . The heat exchanger of claim 8 , wherein in each of the mutually different pairs, the flat tubes constituting the auxiliary windward bank block and the flat tubes constituting the auxiliary leeward bank block are individually connected one by one. 10 . The heat exchanger of claim 7 , wherein the header collecting pipe is further formed with a plurality of auxiliary communicating spaces each communicating with the flat tubes constituting the auxiliary leeward bank portion, the number of the auxiliary communicating spaces is equal to the number of the auxiliary leeward bank blocks, each of the auxiliary leeward bank blocks is paired with an associated one of the auxiliary communicating spaces, and in each of the pairs of the auxiliary communicating spaces and the auxiliary leeward bank blocks, the auxiliary communicating space communicates with the flat tubes constituting the auxiliary leeward bank block. 11 . The heat exchanger of claim 1 , wherein the principal leeward bank portion is further divided into a plurality of principal leeward bank blocks, each of which being constituted of the plurality of flat tubes arranged one above the other, the auxiliary leeward bank portion is further divided into a plurality of auxiliary leeward bank blocks, each of which being constituted of the plurality of flat tubes arranged one above the other, the header collecting pipe is formed with as many the principal communicating spaces as the principal leeward bank blocks, and the principal communicating spaces and the principal leeward bank blocks form mutually different pairs, in each of which the principal communicating space communicates with the flat tubes constituting the principal leeward bank block. 12 . The heat exchanger of claim 11 , wherein the principal leeward bank portion is formed with principal leeward bank block groups, each of which being constituted of the plurality of principal leeward bank blocks, the number of the principal leeward bank block groups is equal to the number of the auxiliary leeward bank blocks, the principal leeward bank block groups and the auxiliary leeward bank blocks form mutually different pairs, and in each of the mutually different pairs, the auxiliary leeward bank block is connected to the principal communicating space associated with the principal leeward bank block of the principal leeward bank block group. 13 . The heat exchanger of claim 12 , wherein the plurality of principal lee