JP2012154501A - Heat exchanger and air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchanger with flat tubes arranged vertically, reducing a time required for defrosting by facilitating draining of drain water.SOLUTION: The heat exchanger (30) includes a plurality of flat tubes (33) and a plurality of fins (35). The fin (35), which is a corrugate fin, is arranged between the flat tubes (33) arranged vertically. Between the flat tubes (33) adjacent vertically, a plurality of heat transfer parts (37) provided on the fin (35) are arranged along the extending direction of the flat tubes (33). The heat transfer part (37) is formed with a plurality of louvers (50, 60) extending vertically. In the heat transfer part (37), the louvers lying near the upwind form upwind side louvers (50) and the louvers lying on a downwind side of the upwind side louvers (50) form downwind side louvers (60). The lower ends of the upwind side louvers (50) are situated upper than the lower ends of the downwind side louvers (60).

Description

  The present invention relates to a heat exchanger that includes a flat tube and fins and exchanges heat between fluid flowing in the flat tube and air.

  Conventionally, a heat exchanger including a flat tube and fins is known. For example, in the heat exchanger described in Patent Document 1, a plurality of flat tubes extending in the left-right direction are arranged one above the other at a predetermined interval, and plate-like fins are arranged at a predetermined interval from each other. They are arranged in the direction of extension. Further, in the heat exchangers described in Patent Document 2 and Patent Document 3, a plurality of flat tubes extending in the left-right direction are arranged one above the other at a predetermined interval, and one corrugated fin is provided between adjacent flat tubes. It is provided one by one. In these heat exchangers, the air flowing while contacting the fins exchanges heat with the fluid flowing in the flat tube.

  Usually, a louver for promoting heat transfer is formed on the fin of this type of heat exchanger. In order to improve the heat transfer performance of the fin, it is advantageous to make the length of the louver as long as possible. Therefore, as described in FIG. 2 of Patent Document 2 and FIG. 4 of Patent Document 3, in the fins of the conventional heat exchanger, the louver formed almost over the entire width of the fin is in the air passage direction. Are lined up.

JP 2003-262485 A JP 2010-002138 A JP 11-294984 A

  By the way, the refrigerant circuit of the air conditioner is provided with an outdoor heat exchanger that exchanges heat between the refrigerant and outdoor air. During the heating operation of the air conditioner, the outdoor heat exchanger functions as an evaporator. When the evaporation temperature of the refrigerant in the outdoor heat exchanger falls below 0 ° C., moisture in the air becomes frost (that is, ice) and adheres to the outdoor heat exchanger. Therefore, during the heating operation in a state where the outside air temperature is low, a defrosting operation for melting frost attached to the outdoor heat exchanger is performed, for example, every time a predetermined time elapses. During the defrosting operation, the high-temperature refrigerant is supplied to the outdoor heat exchanger, and the frost attached to the outdoor heat exchanger is heated by the refrigerant and melts. As a result, the frost adhering to the outdoor heat exchanger becomes drain water and is discharged from the outdoor heat exchanger.

  On the other hand, a heat exchanger in which flat tubes are lined up and down can be used as an outdoor heat exchanger of an air conditioner. However, in this heat exchanger, since the flat side surface of the flat tube faces upward, drain water tends to accumulate on the flat tube. In particular, in a conventional heat exchanger in which the louver is formed over almost the entire width of the fin, the drain water generated during the defrosting operation is discharged from the periphery of the fin because the lower end of the louver is close to the flat tube. It is hard to be done. If drain water stays around the fins, heat transfer from the refrigerant to the frost is hindered by the drain water, and there is a possibility that the time required for the frost to melt is increased.

  The present invention has been made in view of such a point, and the object thereof is to reduce the amount of drain water staying and reduce the time required for defrosting in a heat exchanger in which flat tubes are arranged vertically. It is in.

  According to the first aspect of the present invention, air is provided between a plurality of flat tubes (33) that are arranged one above the other so that the side surfaces face each other and in which a fluid passage (34) is formed, and between the adjacent flat tubes (33). A plurality of fins (35, 36) partitioned into a plurality of ventilation paths (39) through which the air flows, and the fins (35, 36) are formed in a plate shape extending from one to the other of the adjacent flat tubes (33). A heat exchanger having a plurality of heat transfer portions (37) formed and constituting the side walls of the ventilation path (39) is an object. In the fins (35, 36), a plurality of vertically extending louvers (50, 60) formed by cutting and raising the heat transfer section (37) are arranged in the air passage direction, and In the hot section (37), the lower end of the windward louver (50), which is a louver located on the windward side, is lower than the lower edge of the leeward louver (60), which is a louver located on the leeward side of the windward louver (50). It is located above.

  In the first invention, the heat exchanger (30) is provided with a plurality of flat tubes (33) and a plurality of fins (35, 36). Between the flat tubes (33) lined up and down, the heat transfer section (37) of the fins (35, 36) is arranged. In the heat exchanger (30), air passes through the ventilation path (39) between the flat tubes (33) arranged vertically, and the air and the fluid flowing through the passage (34) in the flat tubes (33) Exchange. In the heat transfer section (37) of the fins (35, 36), a plurality of louvers (50, 60) extending vertically are arranged in the air passage direction. In the heat transfer section (37), the position of the lower end of the leeward louver (50) is higher than the position of the lower end of the leeward louver (60). That is, in each heat transfer section (37), the distance between the lower flat tube (33) of the heat transfer section (37) and the lower end of the windward louver (50) is below the heat transfer section (37). It is wider than the distance between the flat tube (33) on the side and the lower end of the leeward louver (60).

  By the way, when the temperature of the fluid flowing in the flat tube (33) is lower than 0 ° C., moisture in the air becomes frost and adheres to the surface of the heat transfer section (37). Further, in the heat transfer section (37), the amount of frost attached to the windward side (that is, the upstream side in the air passage direction) increases. That is, in the heat transfer section (37), the amount of frost adhering to the leeward louver (50) is larger than the amount of frost adhering to the leeward louver (60). For this reason, during the defrosting for melting the frost, the amount of drain water generated by the windward louver (50) becomes relatively large.

  As described above, in the heat transfer section (37) of the first invention, the distance between the flat tube (33) below the heat transfer section (37) and the lower end of the windward louver (50) is the transfer distance. It is wider than the distance between the flat tube (33) below the hot part (37) and the lower end of the windward louver (50). For this reason, the drain water generated in the vicinity of the windward louver (50) during the defrosting quickly flows down under the windward louver (50) due to gravity and does not stay in the vicinity of the windward louver (50).

  In a second aspect based on the first aspect, in the heat transfer section (37), the lower end of the windward louver (50) becomes lower from the windward toward the windward.

  In the heat transfer section (37) of the second invention, the distance between the flat tube (33) on the lower side of the heat transfer section (37) and the lower end of the windward louver (50) increases from the windward to the leeward. It is narrower. In this heat transfer section (37), the distance between the flat tube (33) below the heat transfer section (37) and the lower end of the leeward louver (60) is below the heat transfer section (37). It is narrower than the distance between the flat tube (33) on the side and the lower end of the windward louver (50). That is, in the heat transfer section (37), the distance between the lower end of the louver (50, 60) and the flat tube (33) becomes narrower from the windward to the leeward. For this reason, the drain water generated by the windward louver (50) and flowing down during defrosting is drawn to the leeward side of the heat transfer section (37) by capillary action.

  According to a third invention, in the first or second invention, the louver (50, 60) is inclined with respect to the vertical direction so that the lower end is located on the leeward side of the upper end.

  In the third invention, the longitudinal direction of the louver (50, 60) is inclined with respect to the vertical direction, and the lower end of the louver (50, 60) is located leeward than the upper end. As described above, during defrosting, the frost adhering to the heat transfer section (37) of the fins (35, 36) is melted to generate drain water. The generated drain water is guided by the louvers (50, 60) and flows down toward the leeward side.

  According to a fourth aspect of the present invention, in any one of the first to third aspects of the invention, in each heat transfer section (37) of the fin (35, 36), the cut-up height of the upwind louver (50) is The leeward louver (60) is lower than the cut and raised height.

  In the fourth invention, the cut-and-raised height of the windward louver (50) is relatively low, and the tip of the leeward louver (60) protrudes beyond the tip of the windward louver (50). For this reason, compared with the case where the cut-and-raised height of the leeward louver (60) and the leeward louver (50) are equal, the amount of frost adhering to the leeward louver (60) increases. Therefore, in the heat transfer section (37) of the present invention, the difference between the amount of frost adhering to the leeward portion and the amount of frost adhering to the leeward portion is reduced.

  Moreover, in 4th invention, in the adjacent heat-transfer part (37), the space | interval of leeward louvers (60) becomes narrow compared with the space | interval of leeward louvers (50). For this reason, drain water generated in the vicinity of the windward louver (50) during the defrosting is drawn to the leeward side of the heat transfer section (37) by capillary action.

  According to a fifth invention, in any one of the first to fourth inventions, the cut-and-raised end (53, 63) of the louver (50, 60) includes a main edge (54, 64) and the main edge (54, 64). An upper edge (55,65) inclined from the main edge (54,64) from the upper end of the edge (54,64) to the upper end of the louver (50,60); A lower edge (56,66) that extends from the lower end of the main edge (54,64) to the lower end of the louver (50,60) and is inclined with respect to the main edge (54,64); And at least a part of the plurality of louvers (50, 60) formed in each heat transfer section (37) is the main edge (54, 64) of the lower edge (56, 66). ) With respect to the main edge (54, 64) of the upper edge (55, 65).

  In the fifth invention, the cut and raised ends (53,63) of the louvers (50,60) are the main edge (54,64), the upper edge (55,65), and the lower edge (56,66). It is comprised by. In the louver (50,60), the inclination of the lower edge (56,66) with respect to the main edge (54,64) is relative to the main edge (54,64) of the upper edge (55,65). It is gentler than the slope. For this reason, between the cut-and-raised ends (53, 63) of the louvers (50, 60) adjacent in the air passage direction, the gap between the lower edge portions (56, 66) is the upper edge portion (55, 60). 65) Longer than the gap between them. On the other hand, the drain water generated during the defrosting also enters between the cut and raised ends (53, 63) of the louvers (50, 60) adjacent in the air passing direction. The drain water that has entered between the louvers (50, 60) is drawn into the gap between the elongated lower edges (56, 66) by capillary action.

  In a sixth aspect of the present invention based on any one of the first to fifth aspects, the fin (36) has a plate shape in which a plurality of notches (45) for inserting the flat tube (33) are provided. The flat tube (33) is disposed at a predetermined interval in the extending direction of the flat tube (33), the flat tube (33) is sandwiched by the periphery of the notch (45), and the fin (36) Then, the part between the notch part (45) adjacent up and down comprises the said heat-transfer part (37).

  In the sixth invention, the plurality of fins (36) formed in a plate shape are arranged at predetermined intervals in the extending direction of the flat tube (33). Each fin (36) is formed with a plurality of notches (45) for inserting the flat tube (33). As for each fin (36), the peripheral part of the notch (45) has pinched the flat tube (33). And in each fin (36), the part between the notch parts (45) adjacent up and down comprises a heat-transfer part (37).

  A seventh invention is the corrugated fin according to any one of the first to fifth inventions, wherein the fin (35) meanders up and down and is arranged between the adjacent flat tubes (33). A plurality of the heat transfer portions (37) arranged in the extending direction of the flat tube (33) and a portion continuous to the upper end or the lower end of the adjacent heat transfer portion (37), the flat tube (33) And a plurality of intermediate plate portions (41) joined to each other.

  In 7th invention, the fin (35) which is a corrugated fin is arrange | positioned between adjacent flat tubes (33). Each fin (35) is provided with a plurality of heat transfer sections (37) arranged in the extending direction of the flat tube (33). Moreover, in each fin (35), the adjacent heat-transfer part (37) is connected to the intermediate plate part (41), and this intermediate plate part (41) is joined to the flat side surface of the flat tube (33). .

  An eighth invention is directed to the air conditioner (10), and includes a refrigerant circuit (20) provided with the heat exchanger (30) according to any one of the first to seventh inventions, and the refrigerant circuit In (20), the refrigerant is circulated to perform the refrigeration cycle.

  In the eighth invention, the heat exchanger (30) of any one of the first to seventh inventions is connected to the refrigerant circuit (20). In the heat exchanger (30), the refrigerant circulating in the refrigerant circuit (20) flows through the passage (34) of the flat tube (33) and exchanges heat with the air flowing through the ventilation path (39).

  In the present invention, the heat transfer section (37) is provided in the fins (35, 36). In addition, a plurality of louvers (50, 60) are formed in the heat transfer section (37).

  As described above, when the temperature of the fluid flowing in the flat tube (33) is lower than 0 ° C., moisture in the air becomes frost and adheres to the surface of the heat transfer section (37). In this case, the amount of frost attached to the vicinity of the windward louver (50) is relatively large. For this reason, the amount of drain water produced | generated in the windward louver (50) vicinity becomes comparatively large during the defrost which melts the frost adhering to the heat-transfer part (37).

  On the other hand, in each heat transfer part (37) of the fins (35, 36) of the present invention, the distance between the flat tube (33) below the heat transfer part (37) and the lower end of the windward louver (50) is The distance between the flat tube (33) below the heat transfer section (37) and the lower end of the windward louver (50) is wider. For this reason, drain water generated in the vicinity of the windward louver (50) during the defrosting is quickly discharged to the lower side of the windward louver (50). That is, drain water that inhibits heat transfer from the fins (35, 36) to the frost is quickly discharged from the vicinity of the windward louver (50). Therefore, according to the present invention, it is possible to reduce the time required to melt the frost adhering to the vicinity of the windward louver (50). As a result, the time required to defrost the entire heat exchanger (30) is reduced. Can be shortened.

  In the heat transfer section (37) of the second aspect of the invention, the distance between the lower end of the louver (50, 60) and the flat tube (33) becomes narrower from the windward side toward the leeward side. For this reason, the drain water generated near the windward louver (50) during the defrosting and flowing down is drawn to the leeward side of the heat transfer section (37) by capillary action, and below the windward louver (50). It is discharged from the position. Therefore, according to this invention, the drain water that inhibits the heat transfer from the fins (35, 36) to the frost can be discharged more rapidly from the vicinity of the windward louver (50).

  In the third invention, the louver (50, 60) is inclined with respect to the vertical direction, and the lower end of the louver (50, 60) is located leeward than the upper end. For this reason, the drain water generated during the defrosting is guided to the leeward side by the inclined louvers (50, 60). Therefore, according to the present invention, the amount of drain water staying in the vicinity of the windward louver (50) can be further reduced.

  In the fourth aspect of the invention, since the cut-and-raised height of the leeward louver (50) is lower than the cut-and-raised height of the leeward louver (60), The amount of frost that adheres to the leeward part is averaged. Therefore, according to the present invention, it is possible to extend the time until the capacity reduction of the heat exchanger (30) due to frost adhesion reaches the limit, and the frequency of defrosting can be reduced.

  Moreover, in the said 4th invention, the space | interval of the adjacent heat-transfer part (37) becomes narrow in the part of the leeward side of a heat-transfer part (37). For this reason, the drain water generated by the windward louver (50) during the defrosting is drawn to the leeward side of the heat transfer section (37) by capillary action. Therefore, according to this invention, the drain water that inhibits the heat transfer from the fins (35, 36) to the frost can be discharged more rapidly from the vicinity of the windward louver (50).

  In the fifth invention, at the cut-and-raised end (53, 63) of the louver (50, 60), the inclination of the lower edge (56, 66) with respect to the main edge (54, 64) is the upper edge ( 55, 65) is gentler than the inclination with respect to the main edge (54, 64). For this reason, the drain water generated on the surfaces of the fins (35, 36) and entering between the cut-and-raised ends (53, 63) of the louvers (50, 60) adjacent to each other in the air passage direction is caused by capillary action. It is drawn into the gap between the elongated lower edges (56, 66). Therefore, according to the present invention, the drain water that has entered between the cut-and-raised ends (53, 63) of the louvers (50, 60) adjacent to each other in the air passage direction is moved downward not only by gravity but also by capillary action. The amount of drain water remaining on the surface of the heat transfer section (37) can be reduced.

It is a refrigerant circuit diagram which shows schematic structure of an air conditioner provided with the heat exchanger of Embodiment 1. It is a schematic perspective view of the heat exchanger of Embodiment 1. It is a partial cross section figure which shows the front of the heat exchanger of Embodiment 1. It is sectional drawing of the heat exchanger which shows a part of AA cross section of FIG. It is a schematic perspective view of the fin provided in the heat exchanger of Embodiment 1. It is a figure which shows the heat-transfer part provided in the fin of the heat exchanger of Embodiment 1, Comprising: (A) is a front view of a heat-transfer part, (B) shows the BB cross section of (A). It is sectional drawing. FIG. 7 is an enlarged view of a part of FIG. 6B, wherein FIG. 6A is a cross-sectional view of the leeward louver, and FIG. 6B is a cross-sectional view of the leeward louver. It is sectional drawing of the fin provided in the heat exchanger of Embodiment 1, Comprising: (A) shows CC cross section of FIG. 6, (B) shows DD cross section of FIG. It is a figure which shows the several heat-transfer part provided in the fin of the heat exchanger of Embodiment 1, Comprising: It is sectional drawing equivalent to FIG. 6 (B). It is a figure which shows the state of the frost and drain water in the defrost operation in the heat exchanger of Embodiment 1, and the conventional heat exchanger. It is sectional drawing of the fin which shows the EE cross section of FIG. It is a schematic perspective view of the heat exchanger of Embodiment 2. It is a partial cross section figure which shows the front of the heat exchanger of Embodiment 2. It is sectional drawing of the heat exchanger which shows a part of FF cross section of FIG. It is a figure which shows the principal part of the fin of the heat exchanger of Embodiment 2, Comprising: (A) is a front view of a fin, (B) is sectional drawing which shows the GG cross section of (A). It is a figure which expands and shows a part of FIG. 15 (B), (A) is sectional drawing of an upwind louver, (B) is sectional drawing of a leeward louver. It is sectional drawing of the fin provided in the heat exchanger of Embodiment 2, Comprising: (A) shows the HH cross section of FIG. 15, (B) shows the II cross section of FIG. It is a figure which shows the heat-transfer part of the some fin provided in the heat exchanger of Embodiment 2, Comprising: It is sectional drawing equivalent to FIG.15 (B). It is a front view of a fin which shows what applied the 1st modification of other embodiments to a fin of Embodiment 2, and is a figure equivalent to Drawing 15 (A). It is sectional drawing of the heat exchanger which shows what applied the 2nd modification of other embodiment to the fin of Embodiment 2, Comprising: It is a figure equivalent to FIG. It is sectional drawing of the heat exchanger which shows what applied the 3rd modification of other embodiment to the fin of Embodiment 1, and is a figure equivalent to FIG. It is sectional drawing of the heat exchanger which shows what applied the 4th modification of other embodiment to the fin of Embodiment 1, and is a figure equivalent to FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 of the Invention
A first embodiment of the present invention will be described. The heat exchanger (30) of Embodiment 1 comprises the outdoor heat exchanger (23) of the air conditioner (10) mentioned later.

-Air conditioner-
The air conditioner (10) provided with the heat exchanger (30) of the present embodiment will be described with reference to FIG.

<Configuration of air conditioner>
The air conditioner (10) includes an outdoor unit (11) and an indoor unit (12). The outdoor unit (11) and the indoor unit (12) are connected to each other via a liquid side connecting pipe (13) and a gas side connecting pipe (14). In the air conditioner (10), the refrigerant circuit (20) is formed by the outdoor unit (11), the indoor unit (12), the liquid side communication pipe (13), and the gas side communication pipe (14).

  The refrigerant circuit (20) is provided with a compressor (21), a four-way switching valve (22), an outdoor heat exchanger (23), an expansion valve (24), and an indoor heat exchanger (25). ing. The compressor (21), the four-way switching valve (22), the outdoor heat exchanger (23), and the expansion valve (24) are accommodated in the outdoor unit (11). The outdoor unit (11) is provided with an outdoor fan (15) for supplying outdoor air to the outdoor heat exchanger (23). On the other hand, the indoor heat exchanger (25) is accommodated in the indoor unit (12). The indoor unit (12) is provided with an indoor fan (16) for supplying room air to the indoor heat exchanger (25).

  The refrigerant circuit (20) is a closed circuit filled with a refrigerant. In the refrigerant circuit (20), the compressor (21) has its discharge side connected to the first port of the four-way switching valve (22) and its suction side connected to the second port of the four-way switching valve (22). Yes. In the refrigerant circuit (20), the outdoor heat exchanger (23), the expansion valve (24), and the indoor heat exchanger are sequentially arranged from the third port to the fourth port of the four-way switching valve (22). (25) and are arranged.

  The compressor (21) is a scroll type or rotary type hermetic compressor. The four-way switching valve (22) includes a first state (state indicated by a solid line in FIG. 1) in which the first port communicates with the third port and the second port communicates with the fourth port; The port is switched to a second state (state indicated by a broken line in FIG. 1) in which the port communicates with the fourth port and the second port communicates with the third port. The expansion valve (24) is a so-called electronic expansion valve.

  The outdoor heat exchanger (23) exchanges heat between the outdoor air and the refrigerant. The outdoor heat exchanger (23) is configured by the heat exchanger (30) of the present embodiment. On the other hand, the indoor heat exchanger (25) exchanges heat between the indoor air and the refrigerant. The indoor heat exchanger (25) is constituted by a so-called cross fin type fin-and-tube heat exchanger provided with a heat transfer tube which is a circular tube.

<Cooling operation>
The air conditioner (10) performs a cooling operation. During the cooling operation, the four-way switching valve (22) is set to the first state. During the cooling operation, the outdoor fan (15) and the indoor fan (16) are operated.

  In the refrigerant circuit (20), a refrigeration cycle is performed. Specifically, the refrigerant discharged from the compressor (21) flows into the outdoor heat exchanger (23) through the four-way switching valve (22), dissipates heat to the outdoor air, and is condensed. The refrigerant flowing out of the outdoor heat exchanger (23) expands when passing through the expansion valve (24), then flows into the indoor heat exchanger (25), absorbs heat from the indoor air, and evaporates. The refrigerant that has flowed out of the indoor heat exchanger (25) passes through the four-way switching valve (22) and then is sucked into the compressor (21) and compressed. The indoor unit (12) supplies the air cooled in the indoor heat exchanger (25) to the room.

<Heating operation>
The air conditioner (10) performs heating operation. During the heating operation, the four-way selector valve (22) is set to the second state. During the heating operation, the outdoor fan (15) and the indoor fan (16) are operated.

  In the refrigerant circuit (20), a refrigeration cycle is performed. Specifically, the refrigerant discharged from the compressor (21) flows into the indoor heat exchanger (25) through the four-way switching valve (22), dissipates heat to the indoor air, and condenses. The refrigerant flowing out of the indoor heat exchanger (25) expands when passing through the expansion valve (24), then flows into the outdoor heat exchanger (23), absorbs heat from the outdoor air, and evaporates. The refrigerant that has flowed out of the outdoor heat exchanger (23) passes through the four-way switching valve (22) and then is sucked into the compressor (21) and compressed. The indoor unit (12) supplies the air heated in the indoor heat exchanger (25) to the room.

<Defrosting operation>
As described above, the outdoor heat exchanger (23) functions as an evaporator during the heating operation. Under operating conditions where the outside air temperature is low, the evaporation temperature of the refrigerant in the outdoor heat exchanger (23) may be lower than 0 ° C. In this case, the moisture in the outdoor air becomes frost and the outdoor heat exchanger (23 ). Therefore, the air conditioner (10) performs the defrosting operation every time the duration time of the heating operation reaches a predetermined value (for example, several tens of minutes).

  When starting the defrosting operation, the four-way switching valve (22) is switched from the second state to the first state, and the outdoor fan (15) and the indoor fan (16) are stopped. In the refrigerant circuit (20) during the defrosting operation, the high-temperature refrigerant discharged from the compressor (21) is supplied to the outdoor heat exchanger (23). In the outdoor heat exchanger (23), the frost adhering to the surface is heated and melted by the refrigerant. The refrigerant that has radiated heat in the outdoor heat exchanger (23) sequentially passes through the expansion valve (24) and the indoor heat exchanger (25), and is then sucked into the compressor (21) and compressed. When the defrosting operation is completed, the heating operation is resumed. That is, the four-way switching valve (22) is switched from the first state to the second state, and the operation of the outdoor fan (15) and the indoor fan (16) is resumed.

-Heat exchanger of Embodiment 1-
The heat exchanger (30) of the present embodiment constituting the outdoor heat exchanger (23) of the air conditioner (10) will be described with reference to FIGS.

<Overall configuration of heat exchanger>
As shown in FIGS. 2 and 3, the heat exchanger (30) of the present embodiment includes one first header collecting pipe (31), one second header collecting pipe (32), and many flat tubes. (33) and a large number of fins (35). The first header collecting pipe (31), the second header collecting pipe (32), the flat pipe (33), and the fin (35) are all made of an aluminum alloy and are joined to each other by brazing. .

  Each of the first header collecting pipe (31) and the second header collecting pipe (32) is formed in an elongated hollow cylindrical shape whose both ends are closed. In FIG. 3, the first header collecting pipe (31) is erected at the left end of the heat exchanger (30), and the second header collecting pipe (32) is erected at the right end of the heat exchanger (30). That is, the first header collecting pipe (31) and the second header collecting pipe (32) are installed in such a posture that their respective axial directions are in the vertical direction.

  As shown in FIG. 4, the flat tube (33) is a heat transfer tube whose cross-sectional shape is a flat oval or a rounded rectangle. In the heat exchanger (30), the plurality of flat tubes (33) are arranged in a posture in which the extending direction is the left-right direction and the flat side surfaces face each other. In addition, the plurality of flat tubes (33) are arranged side by side at regular intervals. Each flat tube (33) has one end inserted into the first header collecting tube (31) and the other end inserted into the second header collecting tube (32).

  As shown in FIG. 4, each flat tube (33) is formed with a plurality of fluid passages (34). Each fluid passage (34) is a passage extending in the extending direction of the flat tube (33). In each flat tube (33), the plurality of fluid passages (34) are arranged in a line in the width direction orthogonal to the extending direction of the flat tube (33). One end of each of the plurality of fluid passages (34) formed in each flat pipe (33) communicates with the internal space of the first header collecting pipe (31), and the other end of each of the plurality of fluid passages (34) is the second header collecting pipe (32). ). The refrigerant supplied to the heat exchanger (30) exchanges heat with air while flowing through the fluid passage (34) of the flat tube (33).

  A fin (35) is a corrugated fin meandering up and down, and is arrange | positioned between the flat pipes (33) adjacent up and down. As will be described in detail later, the fin (35) has a plurality of heat transfer portions (37) and a plurality of intermediate plate portions (41). In each fin (35), the intermediate plate portion (41) is joined to the flat tube (33) by brazing.

  As shown in FIG. 3, in the heat exchanger (30), the space between the upper and lower flat tubes (33) is divided into a plurality of ventilation paths (39) by the heat transfer section (37) of the fin (35). Partitioned. The heat exchanger (30) exchanges heat between the refrigerant flowing through the fluid passage (34) of the flat tube (33) and the air flowing through the ventilation passage (39).

  As described above, the heat exchanger (30) includes a plurality of flat tubes (33) arranged vertically so that the flat side faces each other, and a plate-like shape extending from one to the other of the adjacent flat tubes (33). A plurality of fins (35) having a heat transfer section (37). Between the adjacent flat tubes (33), a plurality of heat transfer portions (37) are arranged in the extending direction of the flat tubes (33). And in this heat exchanger (30), the air which flows between adjacent heat-transfer parts (37) heat-exchanges with the fluid which flows through the inside of each flat tube (33).

<Fin configuration>
As shown in FIG. 5, the fin (35) is a corrugated fin formed by bending a metal plate having a certain width, and has a shape meandering up and down. In the fin (35), heat transfer portions (37) and intermediate plate portions (41) are alternately formed along the extending direction of the flat tube (33). That is, the fin (35) is provided with a plurality of heat transfer portions (37) arranged between adjacent flat tubes (33) and arranged in the extending direction of the flat tubes (33). The fin (35) is formed with a protruding plate portion (42). In addition, in FIG. 5, illustration of the louver (50, 60, 70) and the water guide rib (71) which will be described later is omitted.

  A heat-transfer part (37) is a plate-shaped part ranging from one to the other of the flat pipe (33) adjacent up and down. In the heat transfer section (37), the windward end is the leading edge (38). Although not shown in FIG. 5, a plurality of louvers (50, 60) are formed in the heat transfer section (37). The intermediate plate portion (41) is a plate-like portion along the flat side surface of the flat tube (33), and is continuous with the upper ends or lower ends of the heat transfer portions (37) adjacent to the left and right. The angle formed by the heat transfer section (37) and the intermediate plate section (41) is substantially a right angle.

  The protruding plate portion (42) is a plate-like portion formed continuously at the leeward end of each heat transfer portion (37). The projecting plate portion (42) is formed in an elongated plate shape extending vertically, and projects further to the leeward side than the flat tube (33). Moreover, the upper end of the protruding plate part (42) protrudes above the upper end of the heat transfer part (37), and the lower end protrudes below the lower end of the heat transfer part (37). As shown in FIG. 4, in the heat exchanger (30), the protruding plate portions (42) of the fins (35) that are vertically adjacent to each other across the flat tube (33) are in contact with each other.

  As shown in FIG. 6, a plurality of louvers (50, 60, 70) are formed on the heat transfer section (37) and the protruding plate section (42) of the fin (35). Each louver (50, 60, 70) is formed by cutting and raising the heat transfer section (37) and the protruding plate section (42). That is, each louver (50, 60, 70) makes a plurality of slit-like cuts in the heat transfer part (37) and the protruding plate part (42), and plastically deforms so as to twist the part between the adjacent cuts. It is formed by.

  The longitudinal direction of each louver (50, 60, 70) is substantially parallel to the front edge (38) of the heat transfer section (37) (that is, substantially vertical). That is, the longitudinal direction of each louver (50, 60, 70) is the vertical direction. In the heat transfer section (37), a plurality of louvers (50, 60, 70) extending in the vertical direction are formed side by side from the windward side toward the leeward side.

  The six louvers formed in the windward region in the heat transfer section (37) constitute the windward louver (50). That is, in the heat transfer section (37), the six louvers adjacent to each other including the louver formed on the most windward side constitute the windward louver (50). Further, the six louvers formed in the leeward region adjacent to the region where the leeward louver (50) is formed constitute the leeward louver (60). Further, the two louvers formed in the region extending from the leeward end of the heat transfer section (37) to the protruding plate section (42) constitute an auxiliary louver (70).

  In this way, the heat transfer section (37) has six leeward louvers (50), six leeward louvers (60), and two auxiliary louvers in order from the leeward side to the leeward side. (70) and are formed. The number of louvers (50, 60, 70) described above is merely an example. The detailed shape of each louver (50, 60, 70) will be described later.

  Of the heat transfer part (37) of the fin (35), the part other than the louvers (50, 60, 70) is a flat region without cuts and protrusions.

  Specifically, in the heat transfer section (37), a flat region between the upper end of the heat transfer section (37) and the windward louver (50) forms a first upper flat section (81), and the heat transfer section ( The flat area between the upper end of 37) and the leeward louver (60) constitutes the second upper flat part (82). The first upper flat portion (81) is an area continuous with the windward louver (50) and is adjacent to the fold (51) located at the upper end of the windward louver (50). The second upper flat portion (82) is an area continuous with the leeward louver (60) and is adjacent to the fold (61) located at the upper end of the leeward louver (60).

  In the heat transfer section (37), the flat region between the lower end of the heat transfer section (37) and the windward louver (50) constitutes the first lower flat section (83), and the heat transfer section (37 ) And the leeward louver (60) constitutes a second lower flat part (84). The first lower flat portion (83) is an area continuous with the windward louver (50) and is adjacent to the fold (52) located at the lower end of the windward louver (50). The second lower flat portion (84) is an area continuous with the leeward louver (60) and is adjacent to the fold (62) located at the lower end of the leeward louver (60).

  The projecting plate portion (42) of the fin (35) is formed with a water guiding rib (71). The water guiding rib (71) is an elongated concave groove extending vertically along the leeward end of the protruding plate portion (42).

<Louver shape>
The detailed shape of the louvers (50, 60, 70) formed on the fin (35) will be described. Note that “right” and “left” used in this description mean directions when the fin (35) is viewed from the windward side (that is, the front side of the heat exchanger (30)).

  As shown in FIG. 6 (A), the length in the vertical direction of the windward louver (50) gradually increases from the windward toward the leeward. That is, in the heat transfer section (37), the windward louver (50) closest to the windward is the shortest, and the windward louver (50) closest to the leeward is the longest. The distances L1 from the upper end of each windward louver (50) to the upper end of the heat transfer section (37) are equal to each other. Accordingly, the position of the lower end of the windward louver (50) gradually decreases from the windward to the leeward. In other words, the distance L2 from the lower end of the windward louver (50) closest to the windward side to the lower end of the heat transfer part (37) is the distance L2 from the lower end of the windward louver (50) closest to the leeward side to the heat transfer part (37). It is longer than the distance L3 to the lower end (L2> L3). The distance L1 from the upper end of the windward louver (50) to the upper end of the heat transfer section (37) is the distance L3 from the lower end of the windward louver (50) closest to the leeward to the lower end of the heat transfer section (37). Shorter (L3> L1).

  The lengths of the leeward louvers (60) in the vertical direction are equal to each other. Each leeward louver (60) is longer than the leeward louver (50) closest to the leeward side. The distances L4 from the upper end of each leeward louver (60) to the upper end of the heat transfer section (37) are equal to each other. The distance L4 is equal to the distance L1 from the upper end of the windward louver (50) to the upper end of the heat transfer section (37). Therefore, the distance L5 from the lower end of the leeward louver (60) to the lower end of the heat transfer section (37) is the distance L3 from the lower end of the leeward louver (50) closest to the leeward to the lower end of the heat transfer section (37). Shorter (L3> L5).

  The vertical length of the auxiliary louver (70) is shorter than the vertical length of the leeward louver (60). The position of the upper end of the auxiliary louver (70) is lower than the position of the upper end of the leeward louver (60). The position of the lower end of the auxiliary louver (70) is higher than the position of the lower end of the leeward louver (60).

  In the heat transfer section (37), the windward louver (50) and the leeward louver (60) having the above-described lengths are formed. Further, as described above, in the heat transfer section (37), the first lower flat portion (83) is formed below the windward louver (50), and the second lower side is located below the leeward louver (60). A flat portion (84) is formed. Therefore, in the heat transfer part (37), the vertical width of the first lower flat part (83) is wider than the vertical width of the first lower flat part (83).

  As shown in FIG. 6B, each louver (50, 60, 70) is inclined with respect to the flat portion (81 to 84). The leeward louver (50) and the leeward louver (60) are inclined in opposite directions, and the leeward louver (60) and the auxiliary louver (70) are inclined in the same direction. As shown in FIG. 8, the windward louver (50) has a windward cut-and-raised end (53) bulging to the left and a leeward cut-and-raised end (53) bulging to the right. The leeward louver (60) has a cut-and-raised end (63) on the leeward side that bulges to the right and a leeward-side cut and raised end (63) that bulges to the left.

  As shown in FIG. 7A, the two windward louvers (50a) located closer to the windward side have a width W1 in the lateral direction (that is, the air passage direction) and are flat (81, 83). ) Is the angle of inclination θ1, and the height of the cut and raised (that is, the distance from the cut and raised end (53a) to the flat portion (81, 83)) is H1. Further, the four upwind louvers (50b) located closer to the leeward have a width in the lateral direction (that is, the air passage direction) of W2, and an inclination angle with respect to the flat portion (81,83) is θ2. The cut and raised height (that is, the distance from the cut and raised end (53b) to the flat portion (81, 83)) is H2. As shown in FIG. 7B, the leeward louver (60) has a width in the lateral direction (that is, the air passage direction) of W3, and an inclination angle with respect to the flat portion (82, 84) is θ3. The cut and raised height (that is, the distance from the cut and raised end (63) to the flat portion (82, 84)) is H3. The auxiliary louver (70) has a lateral width, an inclination angle with respect to the flat portion (82, 84), and a cut-and-raised height that are equal to those of the leeward louver (60).

  As shown in FIG. 7, the width W1 of the windward louver (50a) is wider than the width W2 of the windward louver (50b), and the width W2 of the windward louver (50b) is larger than the width W3 of the leeward louver (60). Also wide (W1> W2> W3). Further, the inclination angle θ1 of the windward louver (50a) is smaller than the inclination angle θ2 of the windward louver (50b), and the inclination angle θ2 of the windward louver (50b) is smaller than the inclination angle θ3 of the leeward louver (60). Small (θ1 <θ2 <θ3). That is, the inclination of the windward louver (50a) is gentler than that of the windward louver (50b), and the inclination of the windward louver (50b) is gentler than the inclination of the leeward louver (60). The cut-and-raised height H1 of the windward louver (50a) is lower than the cut-and-raised height H2 of the windward louver (50b), and the cut-and-raised height H2 of the windward louver (50b) is the leeward louver (60). Is lower than the height H3 (H1 <H2 <H3).

  In the heat exchanger (30), the heat transfer portions (37) of the fins (35) are arranged at a constant pitch along the extending direction of the flat tube (33). That is, as shown in FIG. 9, in the heat exchanger (30), the plurality of heat transfer sections (37) are arranged in the extending direction of the flat tube (33) at a constant interval D0. On the other hand, the relationship between the cut-and-raised heights of the leeward louver (50a, 50b) and the leeward louver (60) is H1 <H2 <H3. For this reason, in the two heat transfer parts (37) adjacent to each other in the extending direction of the flat tube (33), the distance D1 between the windward louvers (50a) closer to the windward is between the windward louvers (50b) closer to the leeward. The distance D2 is wider than the distance D2, and the distance D2 between the leeward louvers (50b) closer to the leeward is wider than the distance D3 between the leeward louvers (60) (D0> D1> D2> D3).

  As shown in FIG. 8, the cut-and-raised ends (53, 63) of the leeward louver (50) and the leeward louver (60) are the main edge (54, 64), the upper edge (55, 65), And the lower edge (56, 66). The extension direction of the main edges (54, 64) is substantially parallel to the extension direction of the front edge (38) of the heat transfer part (37). The upper edge portion (55, 65) extends from the upper end of the main edge portion (54, 64) to the upper end of the louver (50, 60), and is inclined with respect to the main edge portion (54, 64). Yes. The lower edge portion (56,66) extends from the lower end of the main edge portion (54,64) to the lower end of the louver (50,60), and is inclined with respect to the main edge portion (54,64). ing.

  As shown in FIG. 8A, in the windward louver (50), the inclination angle of the upper edge (55) with respect to the main edge (54) is θ4, and the main edge of the lower edge (56) The inclination angle with respect to (54) is θ5. As shown in FIG. 6, in all the windward louvers (50), the inclination angle θ5 of the lower edge portion (56) is smaller than the inclination angle θ4 of the upper edge portion (55) (θ5 <θ4). Therefore, in all the windward louvers (50), the lower edge (56) is longer than the upper edge (55). All the windward louvers (50) are asymmetric louvers in which the shape of the cut-and-raised end (53) is asymmetric in the vertical direction.

  8A shows an upwind louver (50b) located closer to the leeward side. As shown in FIG. 7A, the cut-and-raised height of the windward louver (50b) is H2. Moreover, as shown also in FIG. 9, in the heat-transfer part (37) adjacent to the passage direction of air, the space | interval of windward louvers (50b) is D2.

  As shown in FIG. 8B, in the leeward louver (60), the inclination angle of the upper edge (65) with respect to the main edge (64) is θ6, and the main edge of the lower edge (66) The inclination angle with respect to (64) is θ7. As shown in FIG. 6, in the two leeward louvers (60a) located closer to the windward, the inclination angle θ6 of the lower edge (66) is smaller than the inclination angle θ7 of the upper edge (65) ( θ6 <θ7). Accordingly, in the leeward louver (60a), the lower edge (66) is longer than the upper edge (65). The leeward louver (60a) is an asymmetric louver in which the shape of the cut-and-raised end (63) is asymmetric in the vertical direction. On the other hand, in the three leeward louvers (60b) located closer to the leeward, the inclination angle θ6 of the lower edge (66) is equal to the inclination angle θ7 of the upper edge (65) (θ6 = θ7). Therefore, in this leeward louver (60b), the length of the lower edge (66) and the upper edge (65) is equal. The leeward louver (60b) is a symmetric louver in which the shape of the cut and raised end (63) is vertically symmetric.

  FIG. 8B shows a leeward louver (60b) located closer to the leeward side. As shown in FIG. 7B, the cut-and-raised height of the leeward louver (60b) is H3. Moreover, as shown also in FIG. 9, in the heat-transfer part (37) adjacent to the passage direction of air, the space | interval of leeward louvers (60b) is D3.

-State of frost and drain water during defrosting operation-
As described above, the heat exchanger (30) of the present embodiment constitutes the outdoor heat exchanger (23) of the air conditioner (10). The air conditioner (10) performs a heating operation. However, in an operation state where the evaporation temperature of the refrigerant in the outdoor heat exchanger (23) is lower than 0 ° C., moisture in the outdoor air becomes frost and the outdoor heat exchanger (23 ). For this reason, the air conditioner (10) performs a defrosting operation for melting frost attached to the outdoor heat exchanger (23). During the defrosting operation, drain water is generated by melting of the frost.

  The state of frost and drain water from immediately before the start of the defrosting operation to immediately after the end of the defrosting operation will be described with reference to FIG. Here, the state of frost and drain water in the heat exchanger (30) of the present embodiment will be described in comparison with the state of frost and drain water in a conventional heat exchanger. In this conventional heat exchanger, all the louvers are formed over substantially the entire width of the heat transfer section, and all the louvers are cut and raised at the same height.

  Immediately before the start of the defrosting operation, a large amount of frost adheres to the heat transfer section (37) of the fin, and the space between the adjacent heat transfer sections (37) is almost blocked by frost.

  As shown in FIG. 10 (a1), in the conventional heat exchanger, frost is concentrated on the windward area of the fins, and the flow of air passing through the heat exchanger and the heat exchange between the air and the refrigerant are performed. Disturbed by frost. For this reason, in the conventional heat exchanger, it is necessary to perform a defrosting operation in spite of the fact that frost hardly adheres to the leeward region of the fin.

  On the other hand, as shown in FIG. 10 (b1), in the heat exchanger (30) of the present embodiment, frost also adheres to the leeward region of the heat transfer section (37). In the upper area of the heat transfer section (37) where the windward louver (50) is formed, the air flow gap is blocked by frost, but it is lower than the windward louver (50). A gap through which air flows remains in the side region. For this reason, in the heat exchanger (30) of this embodiment, frost adheres also to the part in which the leeward louver (60) was formed among the heat-transfer parts (37).

  Furthermore, in the heat exchanger (30) of this embodiment, the cut-and-raised height H3 of the leeward louver (60) is higher than the cut-and-raised heights H1 and H2 of the leeward louver (50). For this reason, it is easy for wind to hit the leeward louver (60) located behind the leeward louver (50), and as a result, the amount of frost adhering to the leeward louver (60) increases.

  As described above, in the heat exchanger (30) of the present embodiment, frost adheres not only to the upwind area of the fin (35) but also to the downwind area thereof. For this reason, the amount of frost adhering to the heat exchanger (30) when it is necessary to perform the defrosting operation is the same as that of the heat exchanger (30) of the present embodiment. More than a vessel. Therefore, compared with the air conditioner which has the outdoor heat exchanger comprised by the conventional heat exchanger, the air conditioner which has the outdoor heat exchanger (23) comprised by the heat exchanger (30) of this embodiment In (10), the time interval from the end of the defrosting operation to the start of the next defrosting operation becomes longer, and as a result, the duration of the heating operation becomes longer.

  When the defrosting operation is started, the frost attached to the heat exchanger (30) is warmed by the refrigerant and gradually melts.

  As shown in FIGS. 10 (a2) and (a3), in the conventional heat exchanger, drain water stays around the remaining frost. In the conventional heat exchanger, all the louvers are formed over almost the entire width of the heat transfer section, and the gap between the adjacent heat transfer sections becomes narrow in almost the entire windward area of the heat transfer section. ing. For this reason, the drain water produced when the frost melts is held in the gap between the adjacent heat transfer parts, and hardly flows out from the periphery of the frost. If drain water stays around frost, it will be in the state which floated in drain water, and frost will leave | separate from the surface of a heat-transfer part.

  On the other hand, as shown in FIGS. 10 (b2) and (b3), in the heat exchanger (30) of the present embodiment, the generated drain water flows down, and the drain water does not stay around the remaining frost. In the heat exchanger (30) of the present embodiment, the lower end of the leeward louver (50) is higher than the lower end of the leeward louver (60). Therefore, the clearance gap between adjacent heat-transfer parts (37) is wide in the area | region below a windward louver (50). For this reason, the drain water produced | generated when the frost adhering to a windward louver (50) melt | dissolves flows along the 1st lower side flat part (83), and falls immediately below. When drain water is quickly discharged from around the frost, the frost is kept in contact with the surface of the heat transfer section (37).

  Thus, in the heat exchanger (30) of the present embodiment, the drain water generated during the defrosting operation is quickly discharged from the vicinity of the windward louver (50) where the amount of frost attached is relatively large. For this reason, the frost remaining around the windward louver (50) is kept in contact with the surface of the heat transfer section (37). Here, as in the conventional heat exchanger, when the remaining frost floats in the drain water and leaves the heat transfer section, the heat transfer from the heat transfer section to the frost is inhibited by the drain water. , It takes longer time to thaw the frost. In contrast, in the heat exchanger (30) of the present embodiment, the remaining frost is kept in contact with the surface of the heat transfer section (37), and the heat is transferred without being disturbed by the drain water. Move from frost to frost. Therefore, compared with the air conditioner which has the outdoor heat exchanger comprised by the conventional heat exchanger, the air conditioner which has the outdoor heat exchanger (23) comprised by the heat exchanger (30) of this embodiment In (10), the duration of the defrosting operation (that is, the time during which the heating operation is interrupted) is shortened.

  Usually, in the heat exchanger (30) immediately after the end of the defrosting operation, there is no frost but drain water is present.

  As shown in FIG. 10 (a4), in the conventional heat exchanger (30), a relatively large amount of drain water stays in the vicinity of the lower end of the heat transfer section (37) of the fin. In the conventional heat exchanger (30), all louvers are formed over almost the entire width of the heat transfer section (37), and the gap between adjacent heat transfer sections (37) is narrow. The upper side surface of the flat tube (33) is a substantially horizontal surface. For this reason, the drain water produced | generated during the defrost operation is hold | maintained in the clearance gap between adjacent heat-transfer parts (37), and will stay on the upper surface of a flat tube (33).

  On the other hand, as shown in FIG. 10 (b4), in the heat exchanger (30) of the present embodiment, most of the drain water generated during the defrosting operation moves to the leeward side, and the protruding plate (42) is moved. It will be discharged downward. In the heat exchanger (30) of the present embodiment, the lower end of the leeward louver (60) is lower than the lower end of the leeward louver (50). Therefore, the clearance gap between adjacent heat-transfer parts (37) is narrow in the area | region below the leeward louver (60). The drain water collected on the upper surface of the flat tube (33) is drawn to the leeward side by capillary action. That is, during the defrosting operation, the outdoor fan (15) is stopped, and the drain water moves to the leeward side even though the upper surface of the flat tube (33) is substantially horizontal.

  As described above, in the heat exchanger (30) of the present embodiment, the drain water generated during the defrosting operation hardly remains on the surface of the heat transfer section (37). If the drain water remains on the surface of the heat transfer section (37), the drain water remaining after the resumption of the heating operation freezes, and the time until it is necessary to perform the defrosting operation again is shortened. . Therefore, compared with the air conditioner which has the outdoor heat exchanger comprised by the conventional heat exchanger, the air conditioner which has the outdoor heat exchanger (23) comprised by the heat exchanger (30) of this embodiment In (10), the elapsed time from the end of the defrosting operation to the start of the next defrosting operation (that is, the duration of the heating operation) becomes longer.

  As described above, in the heat exchanger (30) of the present embodiment, the inclination angle θ5 of the lower edge (56) of the windward louver (50) is the inclination angle θ4 of the upper edge (55). (See FIG. 8A). For this reason, as shown in FIG. 11, between the windward louvers (50) adjacent to each other in the air passage direction, gaps formed between the lower edge portions (56) are separated from each other on the upper edge. It becomes elongated compared to the gap formed between the portions (55).

  In general, a relatively large capillary force acts on a liquid present in a relatively narrow gap. Further, the capillary force acting on the liquid increases as the gap becomes narrower. On the other hand, as shown in FIG. 11, in a state where drain water enters between the cut and raised ends (53) of the windward louvers (50) adjacent in the air passage direction, the lower side in contact with the lower end of the drain water. The interval between the edge portions (56) is narrower than the interval between the main edge portions (54) in contact with the upper end of the drain water. Accordingly, the downward capillary force acting on the drain water is stronger than the upward capillary force, and the drain water is drawn to the lower edge (56) side (ie, the lower side).

  The windward louver (50) is an asymmetric louver in which the shape of the cut-and-raised end (53) is asymmetric in the vertical direction, and its lower edge (56) is relatively long. For this reason, the area | region where the space | interval of cut-and-raised end (53) is narrow is expanded between the windward louvers (50) adjacent in the passage direction of air. As a result, the region where the downward capillary force acting on the drain water becomes stronger than the upward capillary force is expanded, and the possibility that the drain water moves downward due to capillary action is increased.

  In this way, the drain water that has entered between the cut-and-raised ends (53) of the windward louvers (50) adjacent to each other in the air passage direction passes into the narrow and narrow gap between the lower edges (56). It is drawn by capillary action. That is, this drain water flows downward not only by the action of gravity but also by capillary action. Therefore, the drain water generated in the vicinity of the windward louver (50) during the defrosting operation is quickly discharged downward, and the cut-and-raised ends (53) of the windward louvers (50) adjacent to each other in the air passing direction are It becomes difficult to be held in between.

  In the heat exchanger (30) of the present embodiment, the leeward louver (60a) located closer to the windward also has the inclination angle θ7 of the lower edge (56) that is the inclination angle θ6 of the upper edge (55). Smaller asymmetric louvers (see FIG. 6). Therefore, similarly to the case of the leeward louver (50), the drain water flows downward between the adjacent leeward louvers (60a) by the action of both gravity and capillary action.

-Effect of Embodiment 1-
As described above, according to the heat exchanger (30) of the present embodiment, during the heating operation of the air conditioner (10), only in the region closer to the windward side of the heat transfer section (37) of the fin (35). In addition, frost can be attached to the area closer to the lee. Therefore, if the outdoor heat exchanger (23) of the air conditioner (10) is configured by the heat exchanger (30) of this embodiment, the duration of the heating operation can be extended.

  Moreover, according to the heat exchanger (30) of this embodiment, the drain water produced | generated during the defrosting operation | movement of an air conditioner (10) is promptly transmitted from the surface of the heat-transfer part (37) of a fin (35). Can be discharged. For this reason, the amount of heat transferred from the heat transfer section (37) to the frost can be sufficiently secured. Therefore, if the outdoor heat exchanger (23) of the air conditioner (10) is configured by the heat exchanger (30) of the present embodiment, the time required for the defrosting operation can be shortened.

  Moreover, according to the heat exchanger (30) of this embodiment, the amount of drain water remaining on the surface of the heat transfer section (37) at the end of the defrosting operation can be reduced. The drain water remaining on the surface of the heat transfer section (37) freezes after restarting the heating operation. For this reason, if the drain water remaining on the surface of the heat transfer section (37) decreases, the time until the next defrosting operation becomes necessary becomes longer. Therefore, if the outdoor heat exchanger (23) of the air conditioner (10) is configured by the heat exchanger (30) of this embodiment, the duration of the heating operation can be extended.

  Thus, if the outdoor heat exchanger (23) of the air conditioner (10) is configured by the heat exchanger (30) of the present embodiment, the duration of the heating operation can be extended, and further, the defrosting operation is performed. Can be shortened. Therefore, if the outdoor heat exchanger (23) of the air conditioner (10) is configured by the heat exchanger (30) of the present embodiment, the temporal average value of the heating capacity of the air conditioner (10) (that is, The substantial heating capacity of the air conditioner (10) can be increased.

<< Embodiment 2 of the Invention >>
A second embodiment of the present invention will be described. Similarly to the heat exchanger (30) of the first embodiment, the heat exchanger (30) of the second embodiment constitutes an outdoor heat exchanger (23) of the air conditioner (10). Below, the heat exchanger (30) of this embodiment is demonstrated, referring FIGS. 12-18 suitably.

<Overall configuration of heat exchanger>
As shown in FIGS. 12 and 13, the heat exchanger (30) of the present embodiment includes one first header collecting pipe (31), one second header collecting pipe (32), and a number of flat tubes. (33) and a large number of fins (36). The first header collecting pipe (31), the second header collecting pipe (32), the flat pipe (33), and the fin (36) are all made of an aluminum alloy and are joined to each other by brazing. .

  The configuration and arrangement of the first header collecting pipe (31), the second header collecting pipe (32), and the flat pipe (33) are the same as those of the heat exchanger (30) of the first embodiment. That is, the first header collecting pipe (31) and the second header collecting pipe (32) are both formed in a vertically long cylindrical shape, one at the left end of the heat exchanger (30) and the other at the heat exchanger (30). 30) are arranged at the right end of each. On the other hand, the flat tube (33) is a heat transfer tube having a flat cross-sectional shape, and is arranged side by side in a posture in which the flat side surfaces face each other. Each flat tube (33) has a plurality of fluid passages (34). One end of each of the flat tubes (33) arranged in the vertical direction is inserted into the first header collecting pipe (31), and the other end is inserted into the second header collecting pipe (32).

  The fins (36) are plate-like fins and are arranged at regular intervals in the extending direction of the flat tube (33). That is, the fin (36) is disposed so as to be substantially orthogonal to the extending direction of the flat tube (33). Although mentioned later in detail, in each fin (36), the part located between the flat pipes (33) adjacent up and down comprises the heat-transfer part (37).

  As shown in FIG. 13, in the heat exchanger (30), the space between the upper and lower flat tubes (33) is divided into a plurality of ventilation paths (39) by the heat transfer section (37) of the fin (36). Partitioned. The heat exchanger (30) exchanges heat between the refrigerant flowing through the fluid passage (34) of the flat tube (33) and the air flowing through the ventilation passage (39).

  As described above, the heat exchanger (30) includes a plurality of flat tubes (33) arranged vertically so that the flat side faces each other, and a plate-like shape extending from one to the other of the adjacent flat tubes (33). A plurality of fins (36) having a heat transfer section (37). Between the adjacent flat tubes (33), a plurality of heat transfer portions (37) are arranged in the extending direction of the flat tubes (33). And in this heat exchanger (30), the air which flows between adjacent heat-transfer parts (37) heat-exchanges with the fluid which flows through the inside of each flat tube (33).

<Fin configuration>
As shown in FIG. 14, the fin (36) is a vertically long plate-like fin formed by pressing a metal plate.

  The fin (36) has a number of elongated notches (45) extending in the width direction of the fin (36) from the front edge (38) of the fin (36). In the fin (36), a large number of notches (45) are formed at regular intervals in the longitudinal direction (vertical direction) of the fin (36). The notch (45) is a notch for inserting the flat tube (33). The portion closer to the lee of the notch (45) constitutes the tube insertion portion (46). The tube insertion portion (46) has a vertical width substantially equal to the thickness of the flat tube (33) and a length substantially equal to the width of the flat tube (33).

  The flat tube (33) is inserted into the tube insertion portion (46) of the fin (36) and joined to the peripheral portion of the tube insertion portion (46) by brazing. That is, the flat tube (33) is sandwiched between the peripheral portions of the tube insertion portion (46) which is a part of the notch (45).

  In the fin (36), the portion between the notches (45) adjacent to each other in the top and bottom forms a heat transfer portion (37), and the leeward side portion of the tube insertion portion (46) is the leeward side plate portion (47). It is composed. In other words, the fin (36) has a plurality of heat transfer portions (37) adjacent to each other up and down across the flat tube (33), and one leeward continuous to the leeward end of each heat transfer portion (37). A side plate portion (47) is provided. In the heat exchanger (30) of the present embodiment, the heat transfer section (37) of the fin (36) is disposed between the flat tubes (33) arranged in the vertical direction, and the leeward side plate portion (47) is disposed in the flat tube (33 ) Protrudes further to the leeward side.

  As shown in FIG. 15, a plurality of louvers (50, 60) are formed in the heat transfer section (37) and the leeward side plate section (47) of the fin (36). Each louver (50, 60) is formed by raising the heat transfer section (37) and the leeward side plate section (47). That is, each louver (50, 60) is formed by making a plurality of slit-like cuts in the heat transfer part (37) and the leeward side plate part (47), and plastically deforming so as to twist the part between the adjacent cuts. Is formed.

  The longitudinal direction of each louver (50, 60) is substantially parallel to the front edge (38) of the heat transfer section (37). That is, the longitudinal direction of each louver (50, 60) is the vertical direction. In the heat transfer section (37), a plurality of louvers (50, 60) extending in the vertical direction are formed side by side from the leeward side to the leeward side.

  The six louvers formed in the windward region in the heat transfer section (37) constitute the windward louver (50). That is, in the heat transfer section (37), the six louvers adjacent to each other including the louver formed on the most windward side constitute the windward louver (50). The remaining nine louvers located on the leeward side of the leeward louver (50) constitute the leeward louver (60). The leeward louver (60) is formed in a region extending from the leeward side portion of the heat transfer portion (37) to the leeward side plate portion (47).

  In this way, the heat transfer section (37) and the leeward side plate section (47) have six windward louvers (50) and nine leeward louvers (60) in order from the windward side to the leeward side. And are formed. The number of louvers (50, 60) described above is merely an example. The detailed shape of each louver (50, 60) will be described later.

  Of the heat transfer section (37) of the fin (36), the upper and lower portions of the louvers (50, 60) are flat regions without cuts and protrusions.

  Specifically, in the heat transfer section (37), a flat region between the upper end of the heat transfer section (37) and the windward louver (50) forms a first upper flat section (81), and the heat transfer section ( The flat area between the upper end of 37) and the leeward louver (60) constitutes the second upper flat part (82). The first upper flat portion (81) is an area continuous with the windward louver (50) and is adjacent to the fold (51) located at the upper end of the windward louver (50). The second upper flat portion (82) is an area continuous with the leeward louver (60) and is adjacent to the fold (61) located at the upper end of the leeward louver (60).

  In the heat transfer section (37), the flat region between the lower end of the heat transfer section (37) and the windward louver (50) constitutes the first lower flat section (83), and the heat transfer section (37 ) And the leeward louver (60) constitutes a second lower flat part (84). The first lower flat portion (83) is an area continuous with the windward louver (50) and is adjacent to the fold (52) located at the lower end of the windward louver (50). The second lower flat portion (84) is an area continuous with the leeward louver (60) and is adjacent to the fold (62) located at the lower end of the leeward louver (60).

  A water guide rib (71) is formed on the leeward side plate portion (47) of the fin (36). The water guide rib (71) is a long and narrow groove extending vertically along the leeward end of the leeward plate (47), and is formed from the upper end to the lower end of the leeward plate (47). .

  The fin (36) is formed with a tab (48) for maintaining a distance from the adjacent fin (36). As shown in FIG. 15B, the tab (48) is a rectangular piece formed by cutting and raising the fin (36). As shown in FIG. 18, the tab (48) maintains the space between the fins (36) by the protrusions coming into contact with the adjacent fins (36). As shown in FIGS. 14 and 15, in the fin (36), one tab (48) is formed on each heat transfer section (37), and a plurality of tabs (48) are formed on the leeward side plate section (47). ing. In each heat transfer section (37), a tab (48) is arranged in a portion closer to the windward side than the windward louver (50). In the leeward side plate portion (47), one tab (48) is arranged on the leeward side portion of each tube insertion portion (46).

<Louver shape>
The detailed shape of the louvers (50, 60) formed on the fin (36) will be described. Note that “right” and “left” used in this description mean directions when the fin (36) is viewed from the windward side (that is, the front side of the heat exchanger (30)).

  As shown in FIG. 15, the distance from the upper ends of the four upwind louvers (50b) located closer to the leeward to the upper end of the heat transfer section (37) is L11. The positions of the upper ends of the two windward louvers (50a) located closer to the windward are slightly lower than the positions of the upper ends of the remaining four windward louvers (50b). The position of the lower end of the windward louver (50) gradually decreases from the windward to the leeward. Therefore, the distance L12 from the lower end of the windward louver (50) closest to the windward side to the lower end of the heat transfer part (37) is the distance L12 from the lower end of the windward louver (50) closest to the leeward side to the heat transfer part (37). It is longer than the distance L13 to the lower end (L12> L13). The distance L11 from the upper end of the windward louver (50) to the upper end of the heat transfer part (37) is the distance L13 from the lower end of the windward louver (50) closest to the leeward to the lower end of the heat transfer part (37). Shorter (L13> L11).

  The lengths of the leeward louvers (60) in the vertical direction are equal to each other. Each leeward louver (60) is longer than the leeward louver (50) closest to the leeward side. The distances L14 from the upper end of each leeward louver (60) to the upper end of the heat transfer section (37) are equal to each other. The distance L14 is equal to the distance L11 from the upper end of the windward louver (50) to the upper end of the heat transfer section (37). Accordingly, the distance L15 from the lower end of the leeward louver (60) to the lower end of the heat transfer section (37) is the distance L13 from the lower end of the leeward louver (50) closest to the leeward to the lower end of the heat transfer section (37). Shorter (L13> L15).

  In the heat transfer section (37), the windward louver (50) and the leeward louver (60) having the above-described lengths are formed. Further, as described above, in the heat transfer section (37), the first lower flat portion (83) is formed below the windward louver (50), and the second lower side is located below the leeward louver (60). A flat portion (84) is formed. Therefore, in the heat transfer part (37), the vertical width of the first lower flat part (83) is wider than the vertical width of the first lower flat part (83).

  As shown in FIG. 15B, each louver (50, 60) is inclined with respect to the flat portion (81 to 84). Further, the leeward louver (50) and the leeward louver (60) are inclined in directions opposite to each other. As shown in FIG. 17, the windward louver (50) has a windward cut-and-raised end (53) bulging to the left and a leeward cut-and-raised end (53) bulging to the right. The leeward louver (60) has a cut-and-raised end (63) on the leeward side that bulges to the right and a leeward-side cut and raised end (63) that bulges to the left.

  As shown in FIG. 16 (A), the two windward louvers (50a) located closer to the windward side have a width W11 in the lateral direction (that is, the air passage direction) and are flat (81, 83). ) Is an inclination angle θ11, and the cut-and-raised height (that is, the distance from the cut-and-raised end (53a) to the flat portion (81, 83)) is H11. Further, the four upwind louvers (50b) located closer to the leeward have a width in the lateral direction (that is, an air passage direction) of W12, and an inclination angle with respect to the flat portion (81,83) is θ12. The cut and raised height (that is, the distance from the cut and raised end (53b) to the flat portion (81, 83)) is H12. As shown in FIG. 16B, the leeward louver (60) has a width in the lateral direction (that is, the air passage direction) of W13, and an inclination angle with respect to the flat portion (82, 84) is θ13. The cut and raised height (that is, the distance from the cut and raised end (63) to the flat portion (82, 84)) is H13.

  As shown in FIG. 16, the width W11 of the windward louver (50a) is wider than the width W12 of the windward louver (50b), and the width W12 of the windward louver (50b) is larger than the width W13 of the leeward louver (60). Wide (W11> W12> W13). The inclination angle θ11 of the windward louver (50a) is smaller than the inclination angle θ12 of the windward louver (50b), and the inclination angle θ12 of the windward louver (50b) is smaller than the inclination angle θ13 of the leeward louver (60). Small (θ11 <θ12 <θ13). That is, the inclination of the windward louver (50a) is gentler than that of the windward louver (50b), and the inclination of the windward louver (50b) is gentler than the inclination of the leeward louver (60). Further, the cut-and-raised height H11 of the windward louver (50a) is lower than the cut-and-raised height H12 of the windward louver (50b), and the cut-and-raised height H12 of the windward louver (50b) is the leeward louver (60). It is lower than the cut and raised height H13 (H11 <H12 <H13).

  In the heat exchanger (30), the heat transfer portions (37) of the fins (36) are arranged at a constant pitch along the extending direction of the flat tube (33). That is, as shown in FIG. 18, in the heat exchanger (30), a plurality of heat transfer sections (37) are arranged in the extending direction of the flat tube (33) at a constant interval D10. This distance D10 is equal to the height of the tab (48). On the other hand, the relationship between the cut and raised heights of the leeward louver (50a, 50b) and the leeward louver (60) is H11 <H12 <H13. For this reason, in the two heat transfer parts (37) adjacent to each other in the extending direction of the flat tube (33), the distance D11 between the windward louvers (50a) closer to the windward is between the windward louvers (50b) closer to the leeward. The distance D12 is wider than the distance D12, and the distance D12 between the leeward louvers (50b) closer to the leeward is wider than the distance D13 between the leeward louvers (60) (D10> D11> D12> D13).

  As shown in FIG. 17, the cut-and-raised ends (53, 63) of the leeward louver (50) and the leeward louver (60) have a main edge (54, 64), an upper edge (55, 65), and And the lower edge (56, 66). The extension direction of the main edges (54, 64) is substantially parallel to the extension direction of the front edge (38) of the heat transfer part (37). The upper edge portion (55, 65) extends from the upper end of the main edge portion (54, 64) to the upper end of the louver (50, 60), and is inclined with respect to the main edge portion (54, 64). Yes. The lower edge portion (56,66) extends from the lower end of the main edge portion (54,64) to the lower end of the louver (50,60), and is inclined with respect to the main edge portion (54,64). ing.

  As shown in FIG. 17A, in the windward louver (50), the inclination angle of the upper edge (55) with respect to the main edge (54) is θ14, and the main edge of the lower edge (56) The inclination angle with respect to (54) is θ15. As shown in FIG. 15, in all the windward louvers (50), the inclination angle θ15 of the lower edge portion (56) is smaller than the inclination angle θ14 of the upper edge portion (55) (θ15 <θ14). Therefore, in all the windward louvers (50), the lower edge (56) is longer than the upper edge (55). All the windward louvers (50) are asymmetric louvers in which the shape of the cut-and-raised end (53) is asymmetric in the vertical direction.

  FIG. 17A shows an upwind louver (50b) located closer to the leeward side. As shown in FIG. 16A, the cut-and-raised height of the windward louver (50b) is H12.

  As shown in FIG. 17B, in the leeward louver (60), the inclination angle of the upper edge (65) with respect to the main edge (64) is θ16, and the main edge of the lower edge (66) The inclination angle with respect to (64) is θ17. As shown in FIG. 15, in the two leeward louvers (60a) located closer to the windward, the inclination angle θ16 of the lower edge (66) is smaller than the inclination angle θ17 of the upper edge (65) ( θ16 <θ17). Accordingly, in the leeward louver (60a), the lower edge (66) is longer than the upper edge (65). The leeward louver (60a) is an asymmetric louver in which the shape of the cut-and-raised end (63) is asymmetric in the vertical direction. On the other hand, in the six leeward louvers (60b) located closer to the leeward, the inclination angle θ16 of the lower edge (66) is equal to the inclination angle θ17 of the upper edge (65) (θ16 = θ17). Therefore, in this leeward louver (60b), the length of the lower edge (66) and the upper edge (65) is equal.

  FIG. 17B shows a leeward louver (60b) located closer to the leeward side. As shown in FIG. 16B, the cut-and-raised height of the leeward louver (60b) is H13. The leeward louver (60b) is a symmetric louver in which the shape of the cut and raised end (63) is vertically symmetric.

-Effect of Embodiment 2-
The effect obtained by the heat exchanger (30) of the present embodiment is the same as the effect obtained by the heat exchanger (30) of the first embodiment.

  That is, in the heat exchanger (30) of the present embodiment, the lower end of the windward louver (50) is higher than the lower end of the leeward louver (60), similarly to the heat exchanger (30) of the first embodiment. Furthermore, the cut-and-raised heights H11 and H12 of the leeward louver (50) are lower than the cut-and-raised height H13 of the leeward louver (60). For this reason, during heating operation of the air conditioner (10), frost adheres not only to the leeward louver (50) but also to the leeward louver (60), which may increase the duration of the heating operation. it can. In addition, during the defrosting operation of the air conditioner (10), the drain water generated near the windward louver (50) can flow quickly downward, and the frost is in contact with the surface of the heat transfer section (37). Since the amount of heat transferred from the heat transfer section (37) to the frost can be ensured while maintaining this state, the time required for the defrosting operation can be shortened. Furthermore, since the drain water that has flowed down below the windward louver (50) can be moved to the leeward side by capillary action, the amount of drain water remaining on the surface of the heat transfer section (37) at the end of the defrosting operation As a result, the time interval until the next defrosting operation can be extended.

  Further, in the heat exchanger (30) of the present embodiment, in the same way as the heat exchanger (30) of the first embodiment, all the windward louvers (50) and some of the leeward louvers (60a) are cut off. The inclination angles θ15 and θ17 of the lower edge (56,66) of the raised end (53,63) are larger than the inclination angles θ14 and θ16 of the upper edge (55,65) of the raised end (53,63). It is getting smaller. For this reason, drain water that has entered between the leeward louvers (50) and leeward louvers (60a) adjacent to each other in the air passage direction can be discharged downward by the action of both gravity and capillary action. .

<< Other Embodiments >>
The modification of the heat exchanger (30) of Embodiment 1 and 2 is demonstrated.

-First modification-
In the heat exchanger (30) of each of the above embodiments, the longitudinal direction of the louvers (50, 60, 70) formed in the heat transfer section (37) of the fins (35, 36) is inclined with respect to the vertical direction. May be.

  FIG. 19 shows an application of this modification to the fin (36) of the heat exchanger (30) of the second embodiment. In the heat transfer section (37) of the fin (36) shown in the figure, the longitudinal direction of all the louvers (50, 60) is the front edge (38) of the heat transfer section (37) (ie, substantially vertical Direction). In addition, each louver (50, 60) is inclined such that the lower end thereof is located on the leeward side of the upper end. If the inclination of the louver (50, 60) with respect to the vertical direction is within 20 °, the longitudinal direction of the louver (50, 60) is substantially the vertical direction.

  When the louver (50, 60) is inclined as shown in FIG. 19, the drain water generated during the defrosting operation of the air conditioner (10) flows down along the louver (50, 60). Guided to the leeward side. Therefore, according to this modification, the drain water generated during the defrosting operation can flow more reliably to the leeward side, and the drain water remaining on the surface of the heat transfer section (37) at the end of the defrosting operation. The amount can be reduced.

-Second modification-
In the heat exchanger (30) of each of the above embodiments, the positions of the lower ends of all the louvers (50, 60, 70) formed in the heat transfer section (37) of the fins (35, 36) It may be getting lower gradually toward.

  FIG. 20 shows an application of this modification to the fins (36) of the heat exchanger (30) of the second embodiment. In the heat transfer section (37) of the fin (36) shown in the figure, the positions of the lower ends of all the louvers (50, 60) are gradually lowered from the windward to the leeward. That is, in this heat transfer section (37), the position of the lower end of the windward louver (50) located closest to the windward is the highest, and the position of the lower end of the leeward louver (60) located closest to the leeward is the highest. Low.

-Third modification-
In the heat exchanger (30) of each embodiment described above, the positions of the upper ends of the windward louvers (50) formed in the heat transfer section (37) of the fins (35, 36) may be different from each other.

  FIG. 21 shows an application of this modification to the fin (35) of the heat exchanger (30) of the first embodiment. In the heat transfer section (37) of the fin (35) shown in the figure, the lengths of all the windward louvers (50) are equal to each other. In the heat transfer section (37), the position of the lower end of the windward louver (50) is gradually lowered from the windward to the leeward as in the first embodiment. Therefore, in the heat transfer section (37), the position of the upper end of the windward louver (50) is gradually lowered from the windward to the leeward.

-Fourth modification-
In the heat exchanger (30) of each of the above embodiments, the positions of the lower ends of all the windward louvers (50) formed in the heat transfer section (37) of the fins (35, 36) may coincide with each other. . However, in this modification, the position of the lower end of the leeward louver (50) must be higher than the position of the lower end of the leeward louver (60).

  FIG. 22 shows an application of this modification to the fin (35) of the heat exchanger (30) of the first embodiment. In the heat transfer section (37) of the fin (35) in the figure, all the windward louvers (50) are equal in length to each other, and the positions of their lower ends are the same height. However, the position of the lower end of each leeward louver (50) is above the position of the lower end of the leeward louver (60).

  In the fins (35, 36) to which this modification is applied, the vertical height of the first lower flat portion (83) formed below the windward louver (50) is the same as that of the leeward louver (60). It becomes higher than the height in the vertical direction of the second lower flat portion (84) formed below. Therefore, also in the heat exchanger (30) to which the present modification is applied, the windward louver (50) during the defrosting operation of the air conditioner (10) as in the heat exchanger (30) of each of the above embodiments. The drain water generated in the vicinity is quickly discharged downward without staying around the windward louver (50).

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a heat exchanger having flat tubes and fins arranged vertically.

10 Air conditioner
20 Refrigerant circuit
30 heat exchanger
33 Flat tube
34 Fluid passage (passage)
35 fins
36 fins
37 Heat transfer section
39 Ventilation path
41 Intermediate plate
45 Notch
50 Windward louver
53 Cut edge
54 Main edge
55 Upper edge
56 Lower edge
60 Downward louver
63 Cut end
64 Main edge
65 Upper edge
66 Lower edge

Claims (8)

A plurality of flat tubes (33) that are arranged vertically so that the side faces are opposed to each other and in which a fluid passage (34) is formed, and a plurality of ventilation channels through which air flows between the adjacent flat tubes (33) A plurality of fins (35, 36) partitioned into (39),
The fins (35, 36) have a plurality of heat transfer portions (37) that are formed in a plate shape extending from one side of the adjacent flat tube (33) to the other and constitute the side wall of the ventilation path (39). A heat exchanger,
In the fins (35, 36), a plurality of vertically extending louvers (50, 60) formed by cutting and raising the heat transfer section (37) are arranged in the air passage direction.
In the heat transfer section (37), the lower end of the windward louver (50) that is a louver located on the windward side is the lower end of the leeward louver (60) that is a louver located on the leeward side of the windward louver (50). A heat exchanger characterized in that the heat exchanger is located above. In claim 1,
In the heat transfer section (37), the lower end of the upwind louver (50) is lowered from the upwind toward the downwind. In claim 1 or 2,
The heat exchanger according to claim 1, wherein the louvers (50, 60) are inclined with respect to a vertical direction so that a lower end is located on a leeward side with respect to an upper end. In any one of Claims 1 thru | or 3,
In each heat transfer part (37) of the fin (35, 36),
The heat exchanger characterized in that the cut-and-raised height of the leeward louver (50) is lower than the cut-and-raised height of the leeward louver (60). In any one of Claims 1 thru | or 4,
The cut-and-raised end (53,63) of the louver (50,60) extends from the main edge (54,64) and the upper end of the main edge (54,64) to the upper end of the louver (50,60). An upper edge (55,65) that is an extended portion and is inclined with respect to the main edge (54,64), and a lower end of the louver (50,60) from a lower end of the main edge (54,64) A lower edge (56,66) inclined with respect to the main edge (54,64),
At least a part of the plurality of louvers (50, 60) formed in each heat transfer section (37) has an inclination of the lower edge (56, 66) with respect to the main edge (54, 64). The heat exchanger is characterized by being gentler than the inclination of the upper edge (55, 65) with respect to the main edge (54, 64). In any one of Claims 1 thru | or 5,
The fin (36) is formed in a plate shape provided with a plurality of notches (45) for inserting the flat tube (33), and has a predetermined interval in the extending direction of the flat tube (33). Are arranged, sandwiching the flat tube (33) at the periphery of the notch (45),
In the fin (36), a portion between the notch portions (45) vertically adjacent to each other constitutes the heat transfer section (37). In any one of Claims 1 thru | or 5,
The fin (35) is a corrugated fin meandering up and down disposed between the adjacent flat tubes (33), and a plurality of the heat transfer sections ( 37) and a plurality of intermediate plate portions (41) joined to the flat tube (33) that are continuous to the upper end or lower end of the adjacent heat transfer portions (37). Features heat exchanger. A refrigerant circuit (20) provided with the heat exchanger (30) according to any one of claims 1 to 7,
An air conditioner that performs a refrigeration cycle by circulating refrigerant in the refrigerant circuit (20).

Images