KR20140116431A - Air conditioner - Google Patents

Abstract

There is provided an air conditioner capable of preventing the drainage amount dropped from the upper heat exchanger portion where the defrost operation is performed from being re-frozen in the heat exchanger portion used for the heating operation and suppressing the decrease in the heating capacity . A heat source side heat exchanger 8 in which a plurality of heat exchanging parts 17 in which refrigerant is supplied in different paths in a vertical direction and a heat exchanging part 17 are used to heat And a partial defrosting means for performing a defrosting operation on the heat exchanging portion (17), wherein the drainage mechanism (37, 30f) for draining the drain water generated in each heat exchanging portion And is provided for each heat exchanging part (17).

Description

AIR CONDITIONER

The present invention relates to an air conditioner. In particular, the present invention relates to an air conditioner that includes a heat source side heat exchanger composed of a plurality of heat exchanging portions to which refrigerant is supplied in different paths, and can perform a defrosting operation for each heat exchanging portion.

BACKGROUND ART [0002] Conventionally, an air conditioner capable of performing cooling operation and heating operation by switching the flow of refrigerant through a four-way switching valve is known. If the heating operation is performed by the air conditioner under an environment in which the outdoor air temperature is low, the property may adhere to the heat exchanger of the outdoor unit. Since adhering to such properties results in deterioration of heat exchange efficiency, the air conditioner is provided with a defrost function for removing the usual property.

One of the de-frost functions is an inverse cycle de-frost operation. When the temperature of the fins or the like of the heat exchanger of the outdoor unit becomes a predetermined temperature, the indoor side is temporarily cooled by switching the four- And the gaseous refrigerant is supplied to the exchanger at a high temperature and a high pressure to melt and remove the gaseous phase. However, since the heating operation can not be performed while the inverse cyclic de-frost operation is being carried out, there is a fear that the comfort of the room is impaired.

As a result, various technologies have been proposed to enable the de-frost operation while continuing the heating operation. For example, Patent Document 1 discloses an outdoor heat exchanger in which a plurality of heat exchangers (heat exchangers), in which refrigerant is supplied in different passes, are arranged in a vertical direction, and a heat exchanger is used to perform heating operation And a defrosting operation can be performed on the other heat exchanger.

Japanese Patent Application Laid-Open No. 2009-281698

The air conditioning apparatus of Patent Document 1 is configured to perform the de-frost operation in order from the upper heat exchanger. According to Patent Document 1, by dropping the drain water generated by the defrosting operation on the upper heat exchanger into the lower heat exchanger, it becomes possible to melt the property adhered to the heat exchanger on the lower side of the drain water have. Further, according to Patent Document 1, even if the drainage number that has lost heat in the lower heat exchanger is frozen again, it is possible to dissolve the re-frozen drain water (ice) by the defrost operation for the lower heat exchanger thereafter .

However, since the ice produced by re-freezing the drain water is difficult to melt because it is different from the property, it is difficult to surely remove it, and if it is tried to remove it reliably, a long time of defrosting operation is required, Is high.

SUMMARY OF THE INVENTION The present invention has been made in view of such a situation, and it is an object of the present invention to provide a heat source side heat exchanger in which a plurality of heat exchanging parts in which refrigerant is supplied in different paths are juxtaposed in the vertical direction, In an air conditioner capable of performing a defrost operation with respect to another heat exchanger, drainage dripped from the upper heat exchanger is prevented from being re-frozen in the lower heat exchanger, thereby suppressing deterioration of the heating capacity And an object of the present invention is to provide an air conditioner that can be operated by a user.

(1) According to the present invention, there is provided a heat source side heat exchanger comprising a heat source side heat exchanger in which a plurality of heat exchanging parts are arranged in a vertical direction and refrigerant is supplied in different paths, and a heat exchanging part And a partial defrosting means for performing a defrosting operation,

And a drain mechanism for draining the drain water generated in each of the heat exchange units is provided for each of the heat exchange units.

According to the air conditioner having the above-described structure, since the drain mechanism is provided for each of the plurality of heat exchanging units, it is possible to appropriately prevent the drain water generated in the upper heat exchanging unit from falling into the lower heat exchanging unit and re- .

(2) It is preferable that the drainage mechanism is provided with a drain pan provided between the adjacent heat exchange units in the vertical direction, and receiving drain water dropped from the upper heat exchange unit.

According to this configuration, it is possible to reliably receive the drain water generated in the upper heat exchanging portion and to drop it in the lower heat exchanging portion.

(3) The drain pan may include a discharge unit for discharging the drain water to the outside.

According to this configuration, the drain water received by the drain pan can be discharged to the outside by the discharge portion, and it is possible to suitably prevent the drainage water from dropping to the heat exchange portion located below the drain pan.

(4) It is preferable that the drain pan is divided into a plurality of collection areas, and each of the collection areas has the discharge part.

According to this configuration, by dividing the drain pan into a plurality of water collecting areas, it becomes possible to make each water collecting area small, and to form a water gradient more promptly to guide the drain water to the discharge part. Therefore, discharge of the drain water from the discharge portion can be promoted.

(5) It is preferable that the air conditioner is provided with a diathesis structure for connecting the discharge portions of the plurality of drain fans and guiding the drain water discharged from each discharge portion downwardly.

With this configuration, the drain paths from the plurality of drain fans can be integrated and simplified.

(6) It is preferable that the drain pan forms a heat insulating layer between the upper and lower heat exchanging parts.

With this configuration, it is possible to suppress the heat transfer between the heat exchanger for performing the de-frost operation and the heat exchanger for performing the heating operation, thereby suppressing the deterioration of the defrost capability and the heating capability.

(7) The partial de-frosting means may include a heat exchanging portion that is connected to a heat exchanging portion that is used for heating operation and another heat exchanging portion that is subjected to a defrosting operation and that flows refrigerant from the other heat exchanging portion to the heat exchanging portion And a de-frost circuit for condensing the refrigerant in the other heat exchanging part to supercool the refrigerant, and then evaporating the refrigerant in a part of the heat exchanging part.

According to this configuration, since substantially all of the refrigerant can be supplied to the heat exchanger (heat exchanger) on the use side and the heat exchanger on some heat exchangers used for heating operation, a part of the refrigerant discharged from the compressor The deterioration of the heating ability can be suppressed, as compared with the case of using only for the heating.

According to the present invention, drain water dropped from the upper heat exchanger can be prevented from being re-frozen in the lower heat exchanger, and deterioration of the heating capacity can be suppressed.

1 is a perspective view showing an appearance of an outdoor unit of an air conditioner according to an embodiment of the present invention;
2 is a plan view showing the inside of an outdoor unit;
3 is a perspective view showing an outdoor heat exchanger;
4 is a plan view of the drain pan;
5 is a sectional view taken along the line V-V in Fig.
6 is a sectional view taken along a line VI-VI in Fig.
7 is a cross-sectional view taken along line VII-VII in Fig.
8 is a sectional view taken along line VIII-VIII in FIG.
9 is a sectional view taken along line IX-IX in Fig.
10 is a schematic diagram showing a refrigerant circuit of an air conditioner capable of de-frost operation.
11 is a ph diagram showing a refrigeration cycle of the defrost operation.

[Configuration of Refrigerant Circuit]

First, an example of a refrigerant circuit that can be applied to the air conditioner according to the embodiment of the present invention will be described with reference to Fig. 10 is a schematic diagram showing a refrigerant circuit of an air conditioner capable of de-frost operation.

The air conditioner 1 is a separate type having an outdoor unit 2 and an indoor unit 3 and has a refrigerant circuit (main refrigerant circuit) 4 for distributing the refrigerant between the outdoor unit 2 and the indoor unit 3 Respectively.

The outdoor unit 2 is provided with a compressor 6, a four-way switching valve 7, an outdoor heat exchanger (heat source side heat exchanger) 8, an outdoor expansion valve 9, Respectively. Further, the outdoor unit 2 is provided with a blowing fan 10. The indoor unit 3 is provided with an indoor expansion valve 14, an indoor heat exchanger (use side heat exchanger) 11, and the like. The four-way switching valve 7 and the indoor heat exchanger 11 are connected by the gas side refrigerant communication pipe 12 and the indoor expansion valve 14 and the outdoor expansion valve 9 are connected by the liquid side refrigerant communication pipe 13 Respectively.

In the air conditioning apparatus 1 having the above-described configuration, when the cooling operation is performed, the four-way switching valve 7 is maintained in a state shown by a dotted line in Fig. The high-temperature, high-pressure gaseous refrigerant discharged from the compressor 6 flows into the outdoor heat exchanger 8 through the four-way switching valve 7 as indicated by the dotted arrows, And is condensed and liquefied by heat exchange with outdoor air. The liquefied refrigerant passes through the outdoor expansion valve 9 in a fully opened state and flows into the indoor unit 3 through the liquid side refrigerant communication pipe 13. In the indoor unit 3, the refrigerant is decompressed to a predetermined low pressure by the indoor expansion valve 14, and is heat-exchanged with room air in the indoor heat exchanger 11 to be evaporated. The room air cooled by the evaporation of the refrigerant is blown into the room by an indoor fan (not shown), and the room is cooled. The refrigerant vaporized and vaporized in the indoor heat exchanger 11 is returned to the outdoor unit 2 through the gas-side refrigerant communication pipe 12 and sucked into the compressor 6 via the four-way switching valve 7.

On the other hand, when performing the heating operation, the four-way switching valve 7 is maintained in the state shown by the solid line in Fig. The high-temperature, high-pressure gaseous refrigerant discharged from the compressor 6 flows into the indoor heat exchanger 11 of the indoor unit 3 through the four-way switching valve 7 as indicated by the solid line arrow, Condensate and liquefy by heat exchange. The room air heated by the condensation of the refrigerant is blown into the room by the indoor fan, and the room is heated. The liquefied refrigerant in the indoor heat exchanger (11) is returned from the indoor expansion valve (14) in the fully opened state to the outdoor unit (2) through the liquid side refrigerant communication pipe (13). The refrigerant returned to the outdoor unit 2 is depressurized to a predetermined low pressure by the outdoor expansion valve 9 and is heat-exchanged with the outdoor air by the outdoor heat exchanger 8 to be evaporated. The refrigerant vaporized and evaporated in the outdoor heat exchanger 8 is sucked into the compressor 6 through the four-way switching valve 7.

The air conditioner 1 of the present embodiment is constituted by a plurality of heat exchanging portions 17a to 17c to which refrigerant is supplied by different paths of the outdoor heat exchanger 8. [ When the heating operation is carried out, the refrigerant is divided by the fractionating capillary (sorting mechanism) 18 and supplied to each of the heat exchanging portions 17a to 17c, and the refrigerant is circulated through the respective heat exchanging portions 17a to 17c Are sucked into the compressor (6) after merging in the header tube (19). In the example shown in Fig. 10, three heat exchanging portions (first to third heat exchanging portions) 17a to 17c are provided, and are classified into three passes by the flow dividing capillary 18.

The air conditioner 1 of the present embodiment is configured to be capable of performing a defrosting operation (defrosting operation) with respect to other heat exchanging portions while performing a heating operation using a part of the heat exchanging portion. Therefore, in addition to the main refrigerant circuit 4, the air conditioning apparatus 1 is provided with a de-frost circuit (partial defrosting means) for changing the flow path of the refrigerant during the heating operation and de- ) 50 as shown in Fig. Hereinafter, the de-frost circuit 50 will be described in detail. In the following description, when referring to the flow of the refrigerant, the flow direction of the refrigerant at the time of the heating operation is used as a reference.

[Configuration of De-Frost Circuit]

The de-frost circuit 50 is constituted by a bypass pipe 23, first to seventh electromagnetic valves 20a to 20c, 22, 25a to 25c and the like. Specifically, first to third electromagnetic valves (first to third opening / closing valves) 20a to 20c are installed between the first to third heat exchanging portions 17a to 17c and the header pipe 19, respectively And it is possible to switch between a mode of allowing the flow of the refrigerant between the heat exchanging portions 17a to 17c and the header pipe 19 and a mode of blocking the flow of the refrigerant.

A fourth electromagnetic valve (fourth opening / closing valve) 22 is provided on the upstream side of the flow dividing capillary 18 in the refrigerant pipe 21 flowing between the outdoor expansion valve 9 and the outdoor heat exchanger 8 . On the upstream side of the fourth electromagnetic valve 22, there is provided a bypass pipe 23 which branches off from the refrigerant pipe 21. The downstream side of the bypass pipe 23 serves as first to third bypass flow dividing tubes 24a to 24c divided into three by the sorter 26. Each bypass flow dividing pipe 24a to 24c is connected to the Is connected between the heat exchanging portions 17a to 17c and the header pipe 19 and upstream of the first to third electromagnetic valves 20a to 20c. In addition, fifth to seventh electromagnetic valves (fifth to seventh open / close valves) 25a to 25c are provided in the three bypass flow dividing tubes 24a to 24c, respectively.

As one example, the first heat exchanging portion 17a at the right end portion in Fig. 10 among the three heat exchanging portions 17a to 17c is subjected to the de-frost operation, and the second and third The case of performing the heating operation by using the heat exchanging parts 17b and 17c will be described. 10, the flow of the refrigerant around the outdoor heat exchanger 8 in the case of performing the de-frost operation is indicated by a white arrow. In Fig. 11, the refrigeration cycle in the case of performing the de-frost operation is shown on the P-h line.

In order to perform the de-frost operation on the first heat exchanging portion 17a, the first to seventh electromagnetic valves are operated as follows.

The first electromagnetic valve 20a is closed and the second electromagnetic valve 20b is opened. The third electromagnetic valve 20c is opened. The fourth electromagnetic valve 22 is closed. The fifth electromagnetic valve 25a is opened. Sixth electromagnetic valve 25b: closed, seventh electromagnetic valve 25c: closed.

Further, the outdoor expansion valve 9 has an opening degree larger than that in the normal heating operation.

By closing the fourth electromagnetic valve 22 as described above, the refrigerant flowing from the indoor heat exchanger 11 to the flow dividing capillary 18 through the outdoor expansion valve 9 is cut off, and the refrigerant is passed through the bypass pipe 23 . The fifth electromagnetic valve 25a of the first bypass flow branching pipe 24a is opened and the sixth and seventh electromagnetic valves 25b and 25c of the second and third bypass flow branching pipes 24b and 24c are opened. And 25c are closed and the first electromagnetic valve 20a is closed so that substantially all the refrigerant is introduced into the first heat exchanging portion 17a from the header pipe 19 side.

The refrigerant introduced into the first heat exchanging portion 17a is reduced to some extent in the course of flowing through the outdoor expansion valve 9, the bypass pipe 23, etc. (point a to point b in FIG. 11) But is in a state of 0 DEG C or higher and higher than the outside air temperature. For example, when the outside air temperature is -10 ° C, the refrigerant temperature is 5 to 10 ° C. Thereby, it is possible to use the heat of the coolant to melt the adhesive attached to the first heat exchanging portion 17a. The molten metal is drained from the first heat exchanging portion 17a to be taken in by the drain pan 37 and the bottom wall 30f (see FIG. 3) of the outdoor unit 2 to be described later, do.

The refrigerant having passed through the first heat exchanging portion 17a is condensed by heat exchange with the refrigerant and is supercooled (point b to point c in Fig. 11). The refrigerant then flows into the fractionating capillary tube 18, is sorted by the fractionating capillary tube 18, and flows into the second and third heat exchanging sections 17b and 17c. The refrigerant is further depressurized in the course of passing through the fractionation capillary 18 (point c to point d in Fig. 11). That is, the fractionating capillary 18 functions as a pressure reducing mechanism. The second and third electromagnetic valves 20b and 20c and the header pipe 19 are then connected to the first and second electromagnetic valves 20b and 20c by means of heat exchange between the refrigerant and the outside air in the second and third heat exchanging parts 17b and 17c, And is sucked into the compressor (6).

As described above, in the de-frost operation, the first heat exchanger 17a and the second and third heat exchangers 17b and 17c are connected in series and the first heat exchanger 17a The refrigerant is condensed by performing heat exchange between the refrigerant and the casting to be supercooled and the refrigerant is evaporated by performing heat exchange between the refrigerant and the outside air in the second and third heat exchanging parts 17b and 17c. In this de-frost operation, only the second and third heat exchangers 17b and 17c can be used for heating operation. However, the second and third heat exchangers 17b and 17c and the indoor heat exchanger 11 It is possible to flow substantially all of the refrigerant, so that the lowering of the heating capacity can be suppressed.

The de-frost operation for the second heat exchanger 17b or the third heat exchanger 17c can be performed in substantially the same procedure as described above. Specifically, when the second heat exchanger 17b is to be subjected to the de-frost operation, the first to seventh electromagnetic valves are operated as follows.

The first electromagnetic valve 20a is opened, the second electromagnetic valve 20b is closed, the third electromagnetic valve 20c is opened, the fourth electromagnetic valve 22 is closed, the fifth electromagnetic valve 25a is closed, Sixth electromagnetic valve 25b: open, seventh electromagnetic valve 25c: closed.

Thereby, the second heat exchanging portion 17b and the first and third heat exchanging portions 17a and 17c are connected in series and the heat exchanging portion 17b is provided with the heat The refrigerant can be evaporated by performing the heat exchange between the refrigerant and the outside air in the first and third heat exchanging parts 17a and 17c.

In the case of performing the de-frost operation for the third heat exchanging portion 17c, the first to seventh electromagnetic valves are operated as follows.

The first electromagnetic valve 20a is opened, the second electromagnetic valve 20b is opened, the third electromagnetic valve 20c is closed, the fourth electromagnetic valve 22 is closed, the fifth electromagnetic valve 25a is closed, Sixth electromagnetic valve 25b: closed, seventh electromagnetic valve 25c: opened.

Thereby, the third heat exchanging part 17c and the first and second heat exchanging parts 17a and 17b are connected in series and the heat exchanging part 17c is provided with the heat The refrigerant can be evaporated by performing the heat exchange between the refrigerant and the outside air in the first and second heat exchanging sections 17a and 17b.

[Configuration of the outdoor unit 2]

Next, a more detailed structure of the outdoor unit 2 will be described.

Fig. 1 is a perspective view showing an outdoor unit 2 of an air conditioner 1 according to an embodiment of the present invention. Fig. 2 is a plan view showing an internal structure of an outdoor unit 2. Fig. 2 shows the outdoor heat exchanger 8, the blowing fan 10 and the compressor 6 in the configuration of the outdoor unit 2 shown in Fig.

1, the outdoor unit 2 is constructed as a so-called trunk type outdoor unit 2 and includes front and rear walls 30a and 30b, left and right side walls 30c and 30d, a ceiling wall 30e and a bottom wall Frame) 30f. The casing 31 has a rectangular parallelepiped shape. Two jet holes 32 are formed in the upper portion of the front wall 30a on the left side. Each jet hole 32 is provided with a jet grill 33. [ A suction port (not shown) capable of sucking outside air into the casing 31 is formed in the rear wall 30b and the left side wall 30c of the casing 31. [

2, the inside of the casing 31 is partitioned into a mechanical room S1 and a heat exchange room S2 by a partition plate 35. As shown in Fig. Specifically, in the illustrated example, the right side of the partition plate 35 is the machine room S1, and the left side of the partition plate 35 is the heat exchange chamber S2. The partition plate 35 is provided between the front wall 30a and the rear wall 30b and is formed in a curved shape in which the machine room S1 side is recessed from above. The partition plate 35 is arranged such that its rear side is inclined toward the machine room S1 side (right side). The rear end of the partition plate 35 is connected to a tube plate 8a provided at the end of the outdoor heat exchanger 8. [

In the machine room S1, a compressor 6, an accumulator 28, and the like are disposed. On the other hand, the outdoor heat exchanger 8 and the blowing fan 10 are disposed in the heat exchange room S2. The outdoor heat exchanger 8 is formed in a substantially L shape when viewed in plan view along the inside of the rear wall 30b and the left side wall 30c of the casing 31 in which the suction port is formed. The air blowing fan 10 is disposed at a position corresponding to the upper and lower air outlets 32 (see Fig. 1) formed in the front wall 30a of the casing 31 and is provided at a position corresponding to the air inlets 30 of the rear wall 30b and the left wall 30c And the outside air sucked into the heat exchange room S2 is ejected from the air outlet 32. [

3 is a perspective view showing the outdoor heat exchanger 8.

The outdoor heat exchanger 8 of the present embodiment is constituted by a plurality of heat exchanging parts 17 to which refrigerant is supplied in the other path as described above. The plurality of heat exchanging portions 17 are formed in an L-shape when viewed from the top, and stacked in the vertical direction. In the example shown in Fig. 3, four heat exchanging parts 17 are stacked in the vertical direction, and a drain pan (drainage mechanism) 37 is provided between the respective heat exchanging parts 17. [ A bottom wall 30f is provided below the lowermost heat exchanging portion 17 and the bottom wall 30f functions as a drain pan.

The outdoor heat exchanger 8 is constructed so as to be capable of performing a defrosting operation (defrosting operation) with respect to the other heat exchanging portions 17 while the heating operation is performed by the part of the heat exchanging portion 17 as described above have. By performing the defrosting operation sequentially for the plurality of heat exchanging sections 17 one by one, it is possible to dissolve and remove the property adhering to all the heat exchanging sections 17 while maintaining the indoor heating . The drain pan 37 is disposed below the three upper heat exchanging portions 17, and is configured to take out the drain water generated by these de-frost operation and to drain it to the outside. The drain water generated by the defrosting operation of the lowermost heat exchanging portion 17 is received by the bottom wall 30f and discharged from a discharge port (not shown) formed in the bottom wall 30f And is discharged to the outside.

By providing the drain pan 37 as described above, the drainage water generated in the heat exchanging part 17 performing the defrosting operation is dropped to the lower heat exchanging part 17 performing the heating operation Can be prevented. As a result, the dropped drain water is not cooled again in the lower heat exchanger 17 and is not frozen, so that the lowering of the heating capacity can be suppressed.

Fig. 4 is a plan view of the drain pan 37, Fig. 5 is a sectional view taken along the line V-V in Fig. 4, and Fig. 6 is a sectional view taken along line VI-VI in Fig. 7 is a sectional view taken along line VII-VII in FIG. 4, FIG. 8 is a sectional view taken along line VIII-VIII in FIG. 4, and FIG. 9 is a sectional view taken along line IX-IX in FIG.

As shown in FIG. 4, the drain pan 37 disposed between the upper and lower heat exchanging portions 17 is formed in a substantially L shape corresponding to the heat exchanging portion 17 as viewed in a plan view. 3, the lower surface of the drain pan 37 is mounted on the upper side of the lower heat exchanging portion 17, and the upper side heat exchanging portion 17 is mounted on the upper surface thereof.

In addition, the drain pan 37 is partitioned into a plurality of collection areas 42, 43. Specifically, a partition wall 41 is provided at the substantially center of the drain pan 37 in the width direction, and is partitioned into two water collection areas 42 and 43 by the partition wall 41. In this embodiment, a first collecting area 42 formed of a rectilinear section is formed on the left side of the partition wall 41 in Fig. 4, and a bent part bent approximately 90 degrees to the right of the partition wall 41 A second collecting area 43 is formed. The first and second collecting areas 42 and 43 are provided with first and second discharging parts 44 and 45 for discharging the drain water to the outside, respectively.

5 to 7, the drain pan 37 includes a water receiving plate 47 for receiving drain water, and a water receiving plate 47 for receiving the drain water in both the first and second water collecting areas 42, And a space surrounded by the upper surface of the water receiving plate 47 and the opposing surfaces of the pair of support plates 48 serves as the water receiving space 49. [ 5 and 6, in the first and second collecting areas 42 and 43, the water receiving plate 47 is formed so as to become lower as it approaches the first and second discharging parts 44 and 45 So that the drain water received by the water receiving plate 47 is guided to the first and second discharge portions 44 and 45. [

2, 4, and 8, the first discharge portion 44 has an approximately rectangular shape as viewed from a plane projected from the first collection area 42 of the drain pan 37 to the interior side of the outdoor unit 2, A first vertical flow passage 52 passing through the first discharge block 51 in the vertical direction and a second vertical flow passage 52 passing through the first vertical flow passage 52 and the first collecting region 42 And a first transverse flow passage 53 passing through the first discharge block 51 and the one support plate 48 so as to connect the first discharge passage 51 and the second discharge passage 51. [ The drain water received by the water receiving plate 47 in the first collecting area 42 is guided to the first discharging part 44 by the inclination of the water receiving plate 47, And is discharged from the first collecting area 42 through the second vertical passage 53 and the first vertical passage 52.

3, the first discharge portions 44 of the upper and lower adjacent drain fans 37 are connected to each other by a diaphragm pipe 55, and the first discharge portions 44 of the drain pan 37, (44) is connected to a water pipe (55) extending downward. Therefore, the drain water discharged from the first discharge portion 44 of each drain pan 37 is discharged to the one system through the water pipe 55 and discharged to the outside through the bottom wall 30f.

The first discharge portion 44 and the water pipe 55 are located on the inner side of the outdoor unit 2 rather than the outdoor heat exchanger 8 and the air flow generated by the blowing fan 10 As shown in Fig. Thereby, the water pipe 55 hardly obstructs the air flow passing through the outdoor heat exchanger 8, and heat exchange between the outdoor air and the refrigerant flowing through the outdoor heat exchanger 8 can be appropriately performed. Since a relatively large space for air is formed on the inner side of the outdoor unit 2 than the outdoor heat exchanger 8, the space for installing the first discharge unit 44 and the water pipe 55 can be easily secured can do.

2, 4 and 9, the second discharge portion 45 is formed in a substantially triangular shape when seen from a plane projecting from the bent portion of the drain pan 37 to the outside of the outdoor unit 2, A second vertical flow passage 58 penetrating the second discharge block 57 in the vertical direction and a second vertical flow passage 58 connecting the second vertical flow passage 58 and the second collection area 43 A second discharge block 57, and a second transverse flow passage 59 penetrating through the one support plate 48. The drain water received by the water receiving plate 47 in the second collecting area 43 is guided to the second discharging part 45 by the inclination of the water receiving plate 47, (59) and the second vertical flow passage (58).

3, the second discharge portions 45 of the upper and lower adjacent drain panes 37 are connected to each other by a diaphragm pipe 55, and the second discharge portions 45 of the lower- (45) is connected to a water pipe (55) extending downward. Therefore, the drain water discharged from the second discharge portion 45 of each drain pan 37 is discharged through one diaphragm pipe 55 to one system and discharged to the outside through the bottom wall 30f.

The second discharge portion 45 and the water pipe 55 are arranged on the outer side of the outdoor unit 2 rather than the outdoor heat exchanger 8 but are the corner portions of the outdoor unit 2, Is disposed in a dead space formed between the second water collection area 43 of the drain pan 37 and the casing 31, which is a component of the outdoor unit 2. Thereby, it is not necessary to form a new dedicated space in the casing 31 in order to install the second discharge portion 45 and the diaphragm pipe 55.

Since the drain pan 37 has a plurality of water collecting areas 42 and 43, the water collecting areas 42 and 43 can be formed short. As a result, the inclination angle of the water receiving plate 47 for leading the drain water to the drain portions 44 and 45 can be increased as much as possible. If the inclination angle of the water receiving plate 47 is increased, for example, even if the outdoor unit 2 is installed in a slightly upward and downward inclined state, the drain water can be reliably guided to the drain portions 44 and 45.

As shown in Fig. 7, a heat insulating layer 60 is formed between the upper and lower heat exchanging portions 17 by a drain pan 37. As shown in Fig. That is, the space excluding the water receiving plate 47 is a space between the pair of support plates 48 of the drain pan 37, and this space serves as the heat insulating layer 60, and the upper and lower heat exchanging parts 17 ) Of the heat transfer medium. Therefore, the heat loss in each of the heat exchanging units 17 performing the heating operation and the de-frost operation can be reduced, and each operation can be efficiently performed.

The drain pan 37 may be formed of a synthetic resin or a metal, but it is preferable that the drain pan 37 is formed of a material having a low thermal conductivity in order to suppress heat transfer between the upper and lower heat exchanging portions 17. [ Therefore, it is preferable to use a synthetic resin material rather than a metal. As the synthetic resin material, for example, polycarbonate, ABS, PP and the like can be used. Further, the drain pan 37 can be formed of a transparent or semitransparent material. As a result, it is possible to confirm the state of the drain water (drainage state, freeze state) inside the drain pan 37 from the outside.

The drain pan 37 may include a heater 64 to prevent freezing of the drain water. 7, a heater 64 is provided in the recess 63 formed in the outer surface of the pair of support plates 48 to heat the drain water in the water receiving space 49 , It is possible to prevent freezing.

The present invention is not limited to the above-described embodiments, but can be appropriately modified within the scope of the invention described in the claims.

For example, in the above embodiment, the present invention is applied to the transverse ejection type outdoor unit 2, but the present invention can also be applied to the upper ejection type outdoor unit 2. In addition, the outdoor heat exchanger 8 is not limited to the L-shape in plan view, but may be a C-shape in plan view and a rectangular shape in plan view. The present invention is also applicable to a heating-only air conditioner that does not perform cooling operation. In this case, the four-way switching valve can be omitted.

Although the outdoor unit 2 of the above embodiment includes two blowing fans 10 in the upper and lower directions, one or more blowing fans 10 may be provided. The number (the number of passes) of the heat exchange portion 17 is not particularly limited as long as it is two or more. The de-frost operation may be performed by one heat exchanger 17 or by a plurality of heat exchangers 17 (for example, two).

The de-frost circuit 50 is not limited to the one shown in Fig. 10, but can be appropriately changed. Also, the mode of the de-frost operation is not limited to that described in the above embodiment, and various conventionally known types can be adopted. For example, a part of a high-temperature refrigerant discharged from a compressor is supplied to a heat exchanging part for performing a de-frost operation, and a known type (for example, Japanese Unexamined Patent Publication No. 2001-59664, and Japanese Unexamined Patent Publication No. 2009-281698). It is also possible to adopt a known type (see, for example, Japanese Patent Application Laid-Open No. 2009-162393) in which heat is given to the heat exchanger 17 performing the defrost operation to dissipate heat.

1: Air conditioner
2: outdoor unit
4: Refrigerant circuit
6: Compressor
8: outdoor heat exchanger
17: Heat exchanger
30f: bottom wall (drain pan)
37: Drain pan (drainage mechanism)
42: First collecting area
43: 2nd collecting area
44:
45:
50: De-Frost circuit (partial defrosting means)
55: Water pipe (frequency structure)
60: insulating layer

Claims (7)

A heat source side heat exchanger 8 in which a plurality of heat exchanging portions 17 in which refrigerant is supplied in different paths in a vertical direction and a heat exchanging portion 17 are used to heat And a partial defrosting means for performing a defrosting operation on the heat exchanging portion (17)
Wherein a drain mechanism (37, 30f) for draining the drain water generated in each of the heat exchanging portions (17) is provided for each of the heat exchanging portions (17). The method according to claim 1,
The drainage mechanism includes an air conditioner provided between a vertically adjacent heat exchanging part (17) and a drain pan (37) for receiving the drain water dropped from the upper heat exchanging part (17) . 3. The method of claim 2,
And the drain pan (37) has discharge portions (44, 45) for discharging the drain water received to the outside. The method of claim 3,
Wherein the drain pan (37) is divided into a plurality of water collecting areas (42, 33) and each of the water collecting areas (42, 33) has the water discharging part (44, 45). The method according to claim 3 or 4,
There is provided a diversion structure 55 for connecting the discharge portions 44 and 45 of the plurality of drain fans 37 and collectively guiding the drain water discharged from the discharge portions 44 and 45 downward Air conditioner. 6. The method according to any one of claims 2 to 5,
Wherein the drain pan (37) forms a heat insulating layer (60) between the upper and lower heat exchanging parts (17). 7. The method according to any one of claims 1 to 6,
The partial de-frosting means is a system in which a part of the heat exchanging portion 17 used for heating operation and the other heat exchanging portion 17 in which the defrosting operation is performed are connected in series, A de-frost circuit (50) for circulating a refrigerant through the heat exchanging part (17), supercooling the refrigerant in the other heat exchanging part (17) and supercooling the refrigerant, and evaporating the refrigerant in a part of the heat exchanging part (17) .

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