KR101401186B1 - Outdoor unit for air conditioner - Google Patents

Abstract

In the outdoor unit having the humidification function, the downsizing of the outdoor unit is planned while preventing deterioration of the humidification performance. And a guide structure 56b for changing the direction of a part of air blown by the outdoor fan 39 is provided. The humidification unit 60 has a moisture absorption portion 61 for absorbing moisture from the outside air and an air intake port 68a and an air exhaust port 69 for the outside air to be supplied to the moisture absorption portion 62. The exhaust port 69 is disposed facing the negative pressure space 70 around the outdoor fan 39. The humidifying unit 60 is structured such that the air whose direction is changed to the guide structure 56b is drawn into the air discharge port 69 via the air intake port 68a via the moisture absorption portion 61. [

Description

OUTDOOR UNIT FOR AIR CONDITIONER [0002]

The present invention relates to an outdoor unit of an air conditioner having a humidifying unit.

Among the conventional air conditioners having a humidifying function, there is a type in which an outdoor unit of an air conditioner and a humidifying unit (or a humidifying unit) are integrated. Such an air conditioner is disclosed in, for example, Patent Document 1 (Japanese Unexamined Patent Application Publication No. 2004-353898) or Patent Document 2 (Japanese Unexamined Patent Application Publication No. 2008-241212) The outdoor unit is partitioned vertically. In the outdoor units described in Patent Document 1 and Patent Document 2, a humidifying unit is provided above the partition plate, and a fan blowing to the heat exchanger or the heat exchanger is disposed below the partition plate.

In order to downsize the outdoor unit having such a humidifying function, in the air conditioner disclosed in Patent Document 1 or Patent Document 2, a humidifying rotor (adsorption rotating body or desiccant rotor) of the humidifying unit is horizontally installed.

Japanese Patent Application Laid-Open No. 2004-353898 Japanese Patent Application Laid-Open No. 2008-241212

However, even with such a configuration, the downsizing of the outdoor unit is not sufficient, and when attempting to reduce the size of the humidification unit to make the outdoor unit compact, the humidification performance of the humidification unit tends to deteriorate.

An object of the present invention is to provide downsizing of an outdoor unit while preventing deterioration of humidifying performance in an outdoor unit having a humidifying function.

An outdoor unit of an air conditioner according to a first aspect of the present invention includes a casing having a blower chamber through which outside air passes, an outdoor heat exchanger provided in the blower chamber for performing heat exchange between the outside air and an outdoor heat exchanger provided in the blower chamber, An outdoor fan for blowing outside air to the outdoor heat exchanger, a guide structure for changing the direction of a part of the air blown by the outdoor fan, a moisture absorption portion for moisture absorption from the outside air, a moistureproof portion for moistening the air by moistureproofing, And a humidifier unit having an intake port and an exhaust port of the outside air, an exhaust port facing the negative pressure space around the outdoor fan, and air that has been changed to a guide structure is passed through the air intake port to the exhaust port via the moisture intake port.

According to the outdoor unit according to the first aspect, the humidification unit is configured such that the exhaust port is disposed facing the negative pressure space around the outdoor fan, and the air that has been changed to the guide structure is passed through the air intake port to the air exhaust port via the moisture absorption portion. Thus, since the negative pressure space around the outdoor fan and the airflow generated by the outdoor fan are efficiently guided to the moisture absorption unit of the humidification unit by the guide structure, the outdoor fan can efficiently guide the ambient air to the moisture absorption unit, Improvement. Therefore, since the outside air is guided by the moisture absorbing portion, the conventional dedicated fan and the driving motor can be downsized or omitted. As a result, downsizing of the humidifying unit can be achieved.

In an outdoor unit of an air conditioner according to a second aspect of the present invention, in the outdoor unit according to the first aspect, the humidifier unit sucks only the air guided along the guide structure via the outdoor fan at the air inlet.

According to the outdoor unit of the second aspect, since only the air guided along the guide structure is drawn into the intake port via the outdoor fan, it is possible to efficiently utilize the airflow generated by the outdoor fan to efficiently introduce the outside air.

In an outdoor unit of an air conditioner according to a third aspect of the present invention, in the outdoor unit of the first aspect, the humidification unit is configured such that, at the air intake port, air introduced into the first path along the guide structure, Lt; / RTI > together.

According to the outdoor unit of the third aspect, air flowing along the guide structure can be used to load air introduced into the second path. By using the second path, air having a humidity higher than that of the first path can be supplied to the moisture- It becomes easy to introduce.

In an outdoor unit of an air conditioner according to a fourth aspect of the present invention, in the outdoor unit of any one of the first aspect to the third aspect, the casing comprises: a front plate having a blowout port for blowing outside air blown by the outdoor fan; And the guide structure is mounted on a front plate covering a part of the outlet.

According to the outdoor unit of the fourth aspect, since the guide structure is mounted on the front plate, mounting of the guide structure is simplified.

In an outdoor unit of an air conditioner according to a fifth aspect of the present invention, in the outdoor unit of the fourth aspect, the casing further includes a grill mounted on the front plate and covering the outlet of the front plate, and the guide structure is formed on the grill .

According to the outdoor unit of the fifth aspect, since the guide structure is formed in the grille, the guide structure can be formed at the time of forming the grille.

An outdoor unit of an air conditioner according to a sixth aspect of the present invention is the outdoor unit according to the fourth aspect or the fifth aspect of the present invention which divides a space sandwiched between a guide structure and a front plate and between a guide structure and a front plate, And a partitioning member for forming a channel surrounding the air flow toward the intake port.

According to the outdoor unit of the sixth aspect, since the flow of the air is surrounded by the channel formed by providing the partitioning member, the flow of the air which does not reach the inlet port is cut off from this passage, have.

According to a seventh aspect of the present invention, in the outdoor unit of the air conditioner, in the outdoor unit of the sixth aspect, the partition member extends in the rotating direction of the outdoor fan.

According to the outdoor unit of the seventh aspect, since the partition member extends in the rotating direction of the outdoor fan, the pressure generated by the partition member in the flow of air taken out from the outdoor fan and rotating in the rotating direction of the outdoor fan is made small .

In an outdoor unit of an air conditioner according to an eighth aspect of the present invention, in the outdoor unit according to any one of the fourth to seventh aspects, the guide structure has a structure in which the direction of the air outlet from the air inlet to the vicinity of the end near the rotation center of the outdoor fan is And a baffle member that interferes with the flow of air toward the outside.

According to the outdoor unit of the eighth aspect, since the flow of the air from the inlet port toward the outlet port can be suppressed by the baffle member, the amount of the air leading to the inlet port can be increased as compared with the case without the baffle member.

The outdoor unit of an air conditioner according to a ninth aspect of the present invention is the outdoor unit of any one of the fourth aspect to the eighth aspect, further comprising: a rectifying member disposed between the guide structure and the front plate and extending smoothly from the air- Respectively.

According to the outdoor unit of the ninth aspect, the flow of air flows along the rectifying member toward the intake port, so that the noise caused by the flow of air toward the intake port can be suppressed to a low level.

In an outdoor unit of an air conditioner according to a tenth aspect of the present invention, in the outdoor unit according to any of the first to ninth aspects, the humidification unit includes: an outdoor unit And a duct for adsorption is curved downward when viewed from the side.

According to the outdoor unit of the tenth aspect, the outside air can be easily guided to the moisture-absorbing portion via the moisture-absorbing duct by the blowing of the outdoor fan directed upward from below the outdoor unit.

In the outdoor unit of the air conditioner according to the first aspect of the present invention, since the negative pressure space around the outdoor fan and the airflow generated by the outdoor fan are efficiently guided to the moisture absorption unit of the humidification unit by the guide structure, Downsizing of the outdoor unit can be achieved.

In the outdoor unit of the air conditioner according to the second aspect of the present invention, the outside structure can be efficiently guided to the air inlet by the guide structure, and the other structure for guiding the outside air to the moisture absorption portion can be made smaller.

In the outdoor unit of the air conditioner according to the third aspect of the present invention, humidifying performance can be improved by introducing air having a humidity higher than that of the air in the first path into the moisture absorber using the second path.

In the outdoor unit of the air conditioner according to the fourth aspect of the present invention, the installation of the guide structure is simple, and the downsized outdoor unit can be provided at low cost.

In an outdoor unit of an air conditioner according to a fifth aspect of the present invention, an outdoor unit having a guide structure can be provided at low cost.

In the outdoor unit of the air conditioner according to the sixth aspect of the present invention, sufficient air can be easily supplied to the moisture absorption portion by the partitioning member, and the humidifying performance can be improved.

According to a seventh aspect of the present invention, in the outdoor unit of the air conditioner, the humidification performance can be improved by reducing the pressure generated by the partitioning member in the flow of air leading to the intake port.

In the outdoor unit of the air conditioner according to the eighth aspect of the present invention, sufficient air can be easily supplied to the moisture absorption portion by the baffle member, and the humidifying performance can be improved.

In the outdoor unit of the air conditioner according to the ninth aspect of the present invention, noise can be suppressed by the rectifying member.

In the outdoor unit of the air conditioner according to the tenth aspect of the present invention, the amount of outside air supplied to the moisture absorber increases, thereby improving the humidifying performance.

1 is a conceptual diagram showing an outline of a configuration of an air conditioner according to a first embodiment;
2 is a circuit diagram showing an outline of an outdoor unit of an air conditioner.
3 is a perspective view showing an appearance of an outdoor unit in a state where a grill or an outdoor heat exchanger is removed;
4 is a plan view of an outdoor unit with a top plate removed;
5 is a perspective view showing the appearance of an outdoor unit in a state where the front plate, the top plate, the left plate, and the like are removed.
6 is a sectional view taken along the line I-I in Fig.
7 is a perspective view of a humidifying unit viewed from a diagonal line on the right front side.
8 is a perspective view of a humidifying unit viewed from a rear right oblique line.
9 is a partially enlarged cross-sectional view of an outdoor unit for explaining the flow of ambient air around the humidifying unit;
10 is an exploded perspective view showing a humidification rotor and a heater.
11 is a bottom view of the member around the heater of the humidifying unit;
12 is a partially enlarged sectional view of the vicinity of the humidifying unit of the outdoor unit;
13 is a partially enlarged sectional view of an outdoor unit of an air conditioner according to a second embodiment.
14 is a circuit diagram showing an outline of an outdoor unit of an air conditioner according to a modified example of the embodiment;
Fig. 15 is a top view of an outdoor unit according to a modification of Fig. 14 in a state in which the top plate is detached; Fig.
16 is an enlarged front view of the outdoor unit shown in Fig.
Fig. 17 is a circuit diagram showing an outline of an outdoor unit of an air conditioner according to a third embodiment. Fig.
18 is an enlarged front view of the outdoor unit according to the third embodiment;
19 is a perspective view showing an appearance of the outdoor unit of FIG. 18 in a state where the grill or the outdoor heat exchanger is removed.
Fig. 20 is a perspective view showing the appearance of the outdoor unit of Fig. 19 in a state in which the front plate and the top plate are detached. Fig.
Fig. 21 is a rear view showing the appearance of the outdoor unit of Fig. 18 in a state in which the outdoor heat exchanger, the outdoor fan, the protective wire net, and the like are removed. Fig.
22 is a rear view showing an example of a grill according to the third embodiment;
Fig. 23 is a perspective view of the grill of Fig. 22 viewed from an oblique line on the back side; Fig.
Fig. 24 is a perspective view of another grill according to the third embodiment, viewed from a rear oblique line; Fig.
25 is a rear view showing another example of a grill according to the third embodiment;
Fig. 26 is a perspective view of the grill of Fig. 25 viewed from a diagonal line on the back side; Fig.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. Further, the embodiment of the outdoor unit of the air conditioner according to the present invention is not limited to the embodiment described below, and can be changed without departing from the gist of the invention.

≪ First Embodiment >

(1) Outline of configuration of air conditioner

The air conditioner 10 according to the first embodiment of the present invention is constituted such that an indoor unit 20 and an outdoor unit 30 are connected to each other by a communication pipe 12 as shown in Fig. The air conditioner 10 has a plurality of operation modes such as cooling operation, heating operation, dehumidification operation, humidification operation, air supply operation and exhaust operation, and these operation modes can be appropriately combined.

Heat exchange is performed in the indoor unit 20 and the outdoor unit 30 in order to cool or warm the air in the room and the indoor unit 20 and the outdoor unit 30 are connected to each other through the communication pipe 12. [ There is a movement of the heat between. In order to perform such heat exchange and heat transfer, for example, the refrigerant circuit shown in Fig. 2 is formed in the air conditioner 10. An indoor heat exchanger 21 is installed in the indoor unit 20 of Fig. 2 and a compressor 31, a switching valve 32, an outdoor heat exchanger 33, A valve 34, a filter 35, an accumulator 36, a liquid shutoff valve 37 and a gas shutoff valve 38 are provided. The liquid refrigerant piping 14 and the gas refrigerant piping 16 connecting the indoor unit 20 and the outdoor unit 30 communicate with each other through the communication piping 12.

In the humidifying operation, the air supply operation and the exhaust operation, the indoor unit 20 is connected to the outdoor unit 30 through the air supply duct 18 of the communication pipe 12 in order to supply outside air to the room, There is a movement of air in. Particularly, in the humidifying operation, moisture is taken from the outside air in the outdoor unit 30 in order to supply air having a high humidity and a high humidity from the outdoor unit 30 to the indoor unit 20. Therefore, the outdoor unit (30) is provided with a humidifying unit (60) having a function of taking moisture from the outside air.

(1-1) Operation of Refrigerant Circuit

The operation of the refrigerant circuit is not different from the conventional one, but the operation of the refrigerant circuit shown in Fig. 2 will be briefly described.

The refrigerant is discharged to the outdoor heat exchanger 33 via the check valve 32. The outdoor heat exchanger 33 is connected to the outdoor heat exchanger 33 through the outdoor heat exchanger 33, Heat exchange with the outside air is performed in the outdoor heat exchanger (33), and the refrigerant that has lost heat is sent to the electric valve (34). The high-pressure liquid refrigerant changes from the electric valve 34 to the low-pressure state. The refrigerant expanded in the electric valve 34 enters the indoor heat exchanger 21 via the liquid shutoff valve 37 and the liquid refrigerant piping 14 via the filter 35. The indoor heat exchanger 21 performs heat exchange with the indoor air, takes heat, and the refrigerant whose temperature rises is sent to the gas switching valve 32 through the gas refrigerant pipe 16. The gas shut-off valve 38 and the accumulator 36 are connected to each other. The refrigerant sent from the indoor heat exchanger 21 through the gas refrigerant piping 16 is sent to the compressor 31 via the accumulator 36. [

In heating, the switch valve 32 is connected by a dotted line, and the refrigerant compressed and discharged by the compressor 31 is sent to the indoor heat exchanger 21. Then, following the path opposite to that during cooling, the refrigerant exiting the outdoor heat exchanger 33 returns to the compressor 31. [ That is, the compressor 31, the switching valve 32, the gas refrigerant pipe 16, the indoor heat exchanger 21, the liquid refrigerant pipe 14, the electric valve 34, the outdoor heat exchanger 33, The refrigerant circulates in the order of the valve 32, the accumulator 36 and the compressor 31 in this order.

(2) Configuration of indoor unit

In addition to the indoor heat exchanger 21, an indoor fan 22 driven by a motor is provided in the indoor unit 20 on the downstream side of the indoor heat exchanger 21, as shown in Fig. The indoor fan 22 is a cross flow fan. When the indoor fan 22 is driven, the indoor air sucked from the suction port 23 in the upper portion of the indoor unit 20 shown in FIG. 1 passes through the indoor heat exchanger 21, .

The air supply duct 25 of the air supply duct 18 is provided in the indoor space of the indoor unit 20 in the space on the upstream side of the indoor heat exchanger 21. The air supply duct 18 is connected to the humidification unit 60 and air having a high humidity sent from the humidification unit 60 is supplied from the air supply mechanism 25 to the space on the upstream side of the indoor heat exchanger 21. It is possible to increase the humidity of the conditioned air taken out from the air outlet 24 of the indoor unit 20 by driving the indoor fan 22 in a state where the air with high humidity is supplied from the air supply mechanism 25. [ For example, at this time, the indoor heat exchanger 21 can be used as an evaporator at the same time, so that the indoor unit 20 can simultaneously perform the humidification operation and the cooling operation.

(3) Configuration of outdoor unit

(3-1) Outline of configuration of outdoor unit

The outdoor unit 30 includes a casing 40 and a partition plate 43. The interior space of the casing 40 is partitioned by the partition plate 43 into the fan chamber 41 And a machine room 42. In other words, in the outdoor unit 30, the blower chamber 41 and the machine room 42 are shielded by the partition plate 43 so that no wind is blown from the blower chamber 41 to the machine room 42.

2, an outdoor fan 39 driven by a fan motor 39a is connected to the outdoor heat exchanger 30. The outdoor fan 39 is connected to the outdoor heat exchanger 30, (33). The outdoor fan 39 is a propeller fan and has a propeller 39b driven by a fan motor 39a. When the outdoor fan 39 is driven, the outside air sucked from the rear side of the outdoor heat exchanger 33 through the outdoor heat exchanger 33 is taken out from the air outlet 44 of the outdoor unit 30. 1, the front surface of the air outlet 44 is covered with a grill 56 so that the propeller 39b of the outdoor fan 39 is not in contact with the outside of the outdoor unit 30. The grill 56 is mounted on the front plate 46 of the casing 40.

A humidifying unit 60 is provided in the blower chamber 41 of the outdoor unit 30 and a humidifying unit 60 is disposed in front of the outdoor heat exchanger 33. The humidifying unit 60 is disposed in front of the outdoor heat exchanger 33 because a portion of the humidifying unit 60 is caught in the air flow path passing through the outdoor heat exchanger 33. In order to suppress an increase in the blowing resistance of the air passage passing through the outdoor heat exchanger 33, a shape and an arrangement position to be described later are given to the humidification unit 60 at such a place.

(3-2) Casing

3 is a perspective view of the outdoor unit 30 and shows a state in which the grill 56 and the like are removed from the outdoor unit 30 shown in Fig. 4 is a plan view of the outdoor unit 30 and shows a state in which the top plate 48 of the outdoor unit 30 is removed. 5 is a perspective view of the outdoor unit 30 and shows a state in which the front plate 46, the top plate 48, the left plate 50, and the like are removed. 6 is a sectional view taken along the line I-I in Fig.

The casing 40 of the outdoor unit 30 has a front plate 46, a right plate 47, a top plate 48 and a bottom plate 49 shown in Fig. As shown in Fig. 4, the outdoor heat exchanger 33 has an L-shape when viewed from the top, and a left side surface 332 of the L-shaped outdoor heat exchanger 33 is formed on the left side surface of the casing 40 The left side plate 50 is attached to the front side. Although it can not be seen in Fig. 4, the left side plate 50 is formed in a lattice shape in order to guide the outside air to the outdoor heat exchanger 33. The rear portion 331 of the outdoor heat exchanger 33 is provided at the rear side of the blower chamber 41 although the rear side of the blower chamber 41 is opened for the rear portion 331 of the outdoor heat exchanger 33, Is equipped with a protective wire mesh.

The partition plate 43 partitioning the casing 40 by the blower chamber 41 and the machine room 42 is disposed substantially parallel to the right side plate 47 as shown in Fig. The partition plate 43 extends forward from the right end of the outdoor heat exchanger 33 and extends vertically from the bottom plate 49 to the top plate 48. The front portion of the partition plate 43 is mounted in contact with the front plate 46. The right side plate 47 covers the entire rear and right side surfaces from the right end to the right side of the rear portion 51 of the outdoor heat exchanger 33.

An opening 43b is formed in the partition plate 43 (see Fig. 5). The electrical component box 55 shown in Fig. 4 is disposed in the opening 43b and a pin for cooling the power device is disposed so as to protrude from the opening 43b toward the inside of the fan chamber 41. Fig.

3 is formed in the front plate 46 and a ring-shaped bell mouth 52 is mounted around the blow-out port 44. The ring- And a part of the propeller 39b is disposed so as to be contained in the space surrounded by the bell mouth 52.

A fan motor 39a is mounted on the rear side of the propeller 39b in order to couple the rotation shaft of the propeller 39b to the drive shaft of the fan motor 39a. The fan motor stand 53 for supporting the fan motor 39a is a member made of long metal on the rear surface side of the propeller 39b. The fan motor base 53 is provided with two support portions extending vertically so as not to obstruct the flow of outside air by the propeller 39b, And a plurality of transverse tongues connected to each other in the vicinity of the bottom plate (33b) or the bottom plate (49). The fan motor 53 is mounted on the bottom plate 49 and the upper end 33b of the outdoor heat exchanger 33. [

(3-3) The outdoor heat exchanger

As described above, the outdoor heat exchanger 33 has a rear portion 331 disposed on the rear side of the casing 40 and a left side portion 332 disposed on the left side, and the L- . The outdoor heat exchanger (33) has a plurality of fins extending long in the height direction, and a heat transfer pipe horizontally mounted through the fins and thermally connected to the plurality of fins. The outdoor heat exchanger (33) has a height from the bottom plate (49) to the top plate (48). The heat transfer tubes are arranged in a plurality of rows in the height direction by folding back and forth a plurality of times at both ends of the outdoor heat exchanger (33). For example, at the time of cooling, high temperature refrigerant enters from the heat transfer pipe in the lowest row of the outdoor heat exchanger (33), and the refrigerant temperature is lowered as the heat in the upper side is lowered. And the refrigerant temperature is increased as the lower side heat is entered. With this arrangement, the outside air cooled in the vicinity of the upper portion of the outdoor heat exchanger (33) is led to the moisture absorption duct (68) of the humidification unit (60).

(3-3-1) Arrangement of outdoor heat exchanger and humidifying unit

7 and 8 show a humidification unit 60 disposed in front of the outdoor heat exchanger 33. The humidification unit 60 shown in Fig. Fig. 7 is a perspective view of the humidifying unit 60 taken from the obliquely right front side of the humidifying unit 60, and Fig. 8 is a perspective view of the humidifying unit 60 seen from the rear right diagonal line. 7 and Fig. 8 show a state in which the upper cover 67 shown in Figs. 4 and 5 is removed.

It is a feature of the outdoor heat exchanger 33 that the humidifying unit 60 is exposed before the outdoor heat exchanger 33. The height of the position of the upper surface 60a of the humidification unit 60 coincides with the height of the upper end 33b (apex portion) of the outdoor heat exchanger 33. The humidification unit (60) is given a shape in which the volume is reduced as much as possible with a relatively complex appearance.

(3-4) Grill

The grill 56 shown in Fig. 1 is mounted on the front plate 46 of the casing 40 and covers the outlet 44. In the grill 56, a plurality of openings 56a shown in Fig. 9 are formed in order to blow outside air. On the upper left portion of the grill 56, a guide structure 56b is formed of a resin plate. That is, in order to form such a plate-like guide structure 56b, the area Ar1 has a structure in which the space between the fins 56d and 56d of the grill 56 is closed. For example, when the grill 56 is formed, the guide structure 56b is formed by machining to prevent the opening 56a from being formed in the portion to be the guide structure 56b. When molding the grill 56 by injection molding, a mold is formed so that the area corresponding to the guide structure 56b is clogged, for example. When the grill 56 is manufactured as described above, the step of separately forming the guide structure 56b can be omitted. Here, a guide structure 56b is formed outside the casing 40 in order to make the casing 40 compact.

16, the guide structure 56b is formed so as to be caught by a part of the air outlet 44 when viewed from the front, and blocks a part of the outside air taken out from the air outlet 44 toward the front . The blocked outside air is guided upward along the guide structure 56b, such as the route r1 shown by the two-dot chain line in Fig. The outside air directed upward along the guide structure 56b enters the air inlet 68a which is the only one open since the upper portion of the grill 56 is blocked. 1, when the outdoor unit 30 is viewed from the front, the upper and left ends of the guide structure 56b and the overlapping portion 56b1 of the front plate 46 are passages, and the guide structure 56b And the overlapping portion 56b2 of the blow-out port 44 toward the overlapping portion 56b1 on the upper side into the intake port 68a.

When the area of the overlapping portion 56b2 in which the guide structure 56b is caught by the air blow-out port 44 is increased, the amount of air in the outside air led to the air intake port 68a increases. On the other hand, Thereby reducing the air volume of the outside air. Therefore, the area occupied by the guide structure 56b on the air outlet 44 is set so as to distribute an appropriate amount of air to both.

(3-5) Humidification unit

2 and 5, the humidification unit 60 has a moisture absorption portion 61 for moisture absorption from outside air and a moistureproof portion 62 for moisture-proofing and humidifying air.

(3-5-1) Moisture Absorption Part and Moisture Absorption Part

In this humidifying unit 60, the moisture-absorbing portion 61 and the moisture-proof portion 62 are constituted by a single disk-shaped humidifying rotor 63 shown in Fig. That is, the humidification rotor 63 is a moisture absorptive and desorptive material which doubles as the moisture absorption portion 61 and the moisture-proof portion 62. The disk-shaped humidification rotor 63 is a zeolite rotor having a honeycomb structure formed by calcination of zeolite or the like. The humidification rotor 63 is rotatably supported by a motor of a rotor drive motor (not shown) that is mounted to rotate around the center of the disk as a rotation shaft and is transmitted to a gear 64 provided around the humidification rotor 63, .

The adsorbent such as zeolite forming the humidifying rotor 63 has a property of being moisture-absorbed from air at normal temperature and being heated to a temperature higher than normal temperature by air heated at a high temperature by the heater 71 . That is, the side of the humidification rotor 63 that is exposed to normal-temperature air becomes the moisture-absorbing portion 61, and the side exposed to the high-temperature air becomes the moisture-proof portion 62. From another viewpoint, the humidification rotor 63 absorbs moisture from the lower temperature side of the humidification rotor 63 and desorbs moisture from the higher humidification rotor 63 side. The moisture adsorbed on the humidifying rotor 63 by the moisture absorption in the moisture absorption portion 61 is carried to the moistureproof portion 62 in accordance with the rotation of the humidification rotor 63, The moisture adsorbed by the moisture in the portion 62 is desorbed and the air around the moisture-proof portion 62 is humidified. A heater 71 is provided above the moisture-proof portion 62 in order to heat the air passing through the moisture-proof portion 62 of the humidification rotor 63.

(3-5-2) Surrounding wall

As shown in Figs. 7 and 8, the entire circumferential range of the outer periphery of the disk-shaped humidification rotor 63 is surrounded by the surrounding walls 65 and 66. In the humidifying unit 60, the outer periphery of the moisture-absorbing portion 61 is covered by the surrounding wall 65, and the outer periphery of the moisture-proof portion 62 is covered by the surrounding wall 66.

(3-5-3) Hygroscopic duct

At the upper portion of the moisture absorption portion 61, a moisture absorption duct 68 for guiding the ambient air by the moisture absorption portion 61 is provided. As shown in Fig. 4, the hygroscopic duct 68 covers an upper portion of a linear hygroscopic unit 61 whose central angle alpha is greater than 180 degrees.

The hygroscopic duct 68 is open toward the front side and has an air inlet 68a for sucking outside air from the front side. As shown in Fig. 6, the hygroscopic duct 68 is formed at an upper portion of the hygroscopic duct 68, and an inclined portion 68b leading to the air inlet 68a is formed at the upper portion of the hygroscopic duct 68, The duct 68 is curved downward. Since the hygroscopic duct 68 has a structure curved toward the downward direction, the outside air blown from the lower side to the upper side can easily enter from the suction port 68a of the hygroscopic duct 68. The moisture absorbing duct 68 spreads vertically as it progresses from the intake port 68a to the rear side so that the outside air traveling from the intake port 68a to the rear side spreads vertically as it goes to the rear side, It becomes easy to spread over the whole of the portion 61. As shown in Fig. 4, the moisture-absorbing duct 68 covers the entire surface of the moisture-absorbing portion 61, so that the outside air passes through the humidifying rotor 63, which is disposed below.

(3-5-4) Exhaust port

The exhaust port 69 is located below the humidification rotor 63. The exhaust port 69 occupies almost the same area as the projected portion from the upper surface of the moisture absorption duct 68. A propeller 39b is disposed below the exhaust port 69 as shown in Fig. 6 or Fig. That is, the exhaust port 69 is opposed to the space 70 which becomes a negative pressure when the propeller 39b rotates. With this configuration, the outside air blown out from the bell mouth 52 by the propeller 39b and entering the air inlet port 68a is guided to the negative pressure space 70 through the path indicated by the two-dot chain line in Fig. 9, (69) to the blower chamber (41). Therefore, the outside air is sent to the moisture-absorbing portion 61 only by the outdoor fan 39, and a dedicated fan for sending the outside air to the moisture-absorbing portion 61 which is conventionally required can be omitted.

(3-5-5) Heater

10, a heater 71 is provided above the moisture-proof portion 62 of the humidification rotor 63 in order to perform damp-proofing from the moisture-proof portion 62. As shown in Fig. 11 is a bottom view of the heater 71 and the heater supporting member 74 viewed from below. The heater 71 has a structure in which a heating wire (not shown) is installed in a cylindrical housing, and heats the outside air sucked from the suction port 72 and sent to the humidifying rotor 63 with a heating wire. When the heated air escapes through the opening of the honeycomb structure of the humidifying rotor 63, the air in the humidifying duct 73 is humidified by the moisture vapor from the humidifying rotor 63.

The heater 71 is mounted on the lower side of the heater support member 74 as shown in Fig. The heater support member 74 has an upper surface portion 74a and a surrounding outer wall portion 74b and a fixing plate 74c and the upper surface and the side surface are surrounded by the upper surface portion 74a and the outer wall portion 74b, It is a tradition. The housing of the heater 71 and the heater supporting member 74 are formed of a metal plate because heat resistance is required. The suction port 72 is located on the front surface side of the heater support member 74 and below the humidifying rotor 63. The outside air sucked from the suction port 72 and over the humidifying rotor 63 is blown into the housing of the heater 71 To the rear side. At this time, the outside air is heated by the heater 71. The air that has passed through the housing of the heater 71 travels to the rear side through the humidifying rotor 63. Since the lower side of the rear side of the humidifying rotor 63 is connected to the humidifying duct 73 (see Fig. 5), the air that has flowed above the humidifying duct 73 passes under the humidifying rotor 63 And sucked into the duct 73 for humidification. The humidification rotor 63 is exposed to the air whose temperature has been raised by the heater 71 to thereby perform moisture-proof. In this way, the air humidified by the humidifying rotor 63 is led to the indoor unit 20 through the humidifying duct 73. 10, the lower portion of the heater supporting member 74 becomes the moisture-proof portion 62, and the other portion becomes the moisture-absorbing portion 61. As shown in Fig. The humidification rotor 63 is rotated in the clockwise direction when viewed from the upper surface and when the portion of the humidification rotor 63 functioning as the moisture absorption portion 61 rotates and comes under the heater support member 74, ). That is, the humidification rotor 63 is a moisture absorptive and desorptive material which doubles as the moisture absorption portion 61 and the moisture-proof portion 62.

(3-5-6) Turbo fan and humidification duct

As described above, since the humidifying duct 73 is located on the lower rear side of the humidifying rotor 63 and is located in front of the outdoor heat exchanger 33, the air passing through the outdoor heat exchanger 33 So that the airflow resistance is maintained. Further, since the turbo fan 75 is also disposed in front of the outdoor heat exchanger 33, it causes airflow resistance. Therefore, the turbo fan 75 having a comparatively large occupying volume is disposed in the vicinity of the outside heat exchanger 33 as shown in Figs. 2 and 4 And is installed in the machine room 42 as well.

The propeller 39b is disposed below the humidifying unit 60 and the humidifying unit 60 is disposed at the highest position among the rotating areas of the propeller 39b as compared with the upper end 33b of the outdoor heat exchanger 33 As shown in FIG. As a result, the outside air that has passed through the vicinity of the upper end of the outdoor heat exchanger 33 flows downward toward the propeller 39b. The duct near the turbo fan 75 is positioned at the same position as the height of the upper end 33b of the outdoor heat exchanger 33 so as not to obstruct the air flow path of the outside air as much as possible, And is arranged diagonally toward the turbo fan 75 so as to come to the turbo fan 75. [ 2, a damper 78 is mounted on the humidification duct 73, and the humidification duct 73 is provided with a damper 78 for humidifying the humidifying duct 73. The humidification duct 73 is provided with a damper 78, The flow of air flowing through the rotor 63 is prevented.

As shown in Fig. 7, the turbo fan 75 is arranged so as not to take up space in the front-rear direction. That is, the rotational axis of the impeller wheel of the turbo fan 75 is vertically arranged to extend in the front-rear direction. The suction port 76 of the turbo fan 75 is disposed toward the humidifying unit 60. In addition, the discharge port 77 of the turbo fan 75 is arranged obliquely downward. The damper 78 is installed on the side of the humidifying duct 73 and the discharge port 77 is disposed diagonally downward so that the vicinity of the discharge port 77 of the turbo fan 75 and the discharge port 77 is also connected to the outdoor unit 30 As shown in Fig. The air supply duct 18 is mounted on the discharge port 77 of the turbo fan 75 exposed from the opening 47a of the right side plate 47.

(3-5-7) Fixing the humidification unit

12 is a partial cross-sectional view of the outdoor unit 30 for showing the cross-sectional shape of the humidifying unit 60. As shown in Fig. The humidification unit (60) is fixed to the fan motor base (53) with a screw (53a). In addition, the front of the humidifying unit 60 extends to the front plate 46. In the fixed state, the humidification unit 60 does not move back and forth, right and left. A predetermined clearance Is is formed between the front surface 33a of the outdoor heat exchanger 33 and the rear surface 60b of the humidification unit 60. [ This gap Is is securely held by the rib 60c formed on the rear surface 60b. An inclined portion 68c is formed on the back side of the moisture absorption duct 68 and an inclined portion 65c inclined so as to protrude forward as the surrounding wall 65 shown in Fig. Is installed. If the inclined portion 65c is provided and the lower portion is inclined as shown in Fig. 12, the flow of the outside air is improved.

The outdoor air flows like the path r2 shown in Fig. 12, and the outdoor heat exchanger 33 on the rear surface side of the humidifying unit 60 is cooled by the outside air It is possible to prevent the heat exchange efficiency from being lowered.

The inclined portion 68c of the upper portion of the humidifying unit 60 allows the outside air passing through the front portion of the outdoor heat exchanger 33 to face the inclined portion 68c to face the humidifying unit 60 Moves forward to the left. As shown in Fig. 4, the outside air flowing toward the left side surface flows downward from the space 41a of the outdoor heat exchanger 33 and the humidifying unit 60, and a path r3 toward the propeller 39b . Therefore, compared with the case where the path r3 is not formed, the air flow resistance is lowered.

≪ Second Embodiment >

In the first embodiment, only the air which has been guided to the air intake port 68a by the guide structure 56Ab in the airflow generated by the outdoor fan 39 is drawn in the air intake port 68a of the moisture absorption duct 68. Since the configuration of the first embodiment can sufficiently utilize the air flow of the outdoor fan 39, it is easy to secure the amount of outside air to be taken in.

On the other hand, the outdoor unit 30A of the second embodiment shown in Fig. 13 has the opening 56Aba in the guide structure 56Ab of the grill 56A. The opening 56Aba is provided so as to face the intake port 68a. Thereby a path r1 extending along the guide structure 56Ab to the intake port 68a and a path r4 entering the intake port 68a directly from the opening 56Aba. At this time, the outside air is guided to the intake port 68a through the path r4 along the outside air sent to the path r1.

(4) Features

(4-1)

9 and the like, the negative pressure space 70 from the outdoor heat exchanger 33 to the part partitioned by the outdoor fan 39 and the bell mouth 52 is arranged so that the outdoor fan 39 is rotating when the outdoor fan 39 is rotating It is space that becomes negative pressure. The exhaust port 69 faces the negative pressure space 70 so that an air flow is generated from the side where the humidification rotor 63 is present to the negative pressure space 70 by sandwiching the exhaust port 69 therebetween. On the other hand, an air current is blown out from the blow-out port 44 in front of the bell mouth 52. The air that has been changed to the guide structures 56b and 56ab shown in Figs. 9 and 13 is introduced into the outdoor unit 30 from the air outlet 44 through the air inlet 68a and the air outlet 69 (R1) is formed. Therefore, outdoor air can be efficiently guided to the moisture absorption portion 61 by the outdoor fan 39, and the moisture absorption function is improved. As a result, since the outside air can be delivered to the moisture absorption portion 61, the conventional dedicated fan or the drive motor for the dedicated fan can be omitted. In the above embodiment, the case where the dedicated fan or the like is omitted has been described. However, if the dedicated fan or the drive motor can be downsized without omitting it, the downsizing of the humidification unit 60 can be achieved. If the humidification unit 60 can be downsized, the downsizing of the outdoor unit 30 can be achieved.

(4-2)

The configuration of the first embodiment shown in Fig. 9 is such that only the air delivered along the guide structures 56b, 56Ab via the outdoor fan 39 is drawn in through the intake port 68a. With such a configuration, it is possible to efficiently utilize the airflow generated by the outdoor fan 39 to efficiently introduce the outside air into the air inlet 68a.

(4-3)

As shown in Fig. 13, the air guided along the guide structure 56Ab to the path r1 (first path) can be used to bring in the air guided to the path r4 (second path) By using the route r4, it becomes easy to introduce air having higher humidity than the air of the route r1 (first route) into the moisture absorption portion.

Since most of the outside air sent to the path r1 passes through the outdoor heat exchanger 33 once, the humidity in the outdoor heat exchanger 33 may be lowered due to condensation. On the other hand, since the outside air directly entering the intake port 68a from the opening 56Aba does not pass through the outdoor heat exchanger 33, the humidity is often higher than the outside air carried by the path r1. By using the route r4 to hold the outside air at the air intake port 68a, there is a case where air with high humidity can be received. In such a case, air having a humidity higher than that of the air in the path r1 may be introduced into the moisture absorption portion 61 using the path r4, thereby improving the humidifying performance.

(4-4)

As shown in Figures 1, 9 and 13, the guide structures 56b, 56Ab are formed in the grilles 56, 56A and guide structures 56b, 56Ab together with the grills 56, 56A And is mounted on the front plate 46. That is, the guide structures 56b and 56Ab can be mounted by mounting the grills 56 and 56A, and the guide structures 56b and 56Ab can be mounted very simply.

Although the grilles 56 and 56A and the guide structures 56b and 56Ab are integrally formed in the above embodiment, the grilles 56 and 56A and the guide structures 56b and 56Ab may be separated from each other. Not only the case in which the guide structures 56b and 56Ab are indirectly mounted to the front plate 46 via the grill 56 and 56A but also the structure in which the guide structures 56b and 56Ab are directly attached to the front plate 46, As shown in Fig.

(4-5)

As described above, the guide structures 56b and 56Ab are formed on the grilles 56 and 56A, and the openings 56a of the grilles 56 and 56A are not punched. Therefore, the guide structures 56b and 56Ab can be formed simultaneously with the molding of the grills 56 and 56A. Thereby, it is not necessary to add a dedicated process for forming the guide structures 56b, 56Ab, and the outdoor units 30, 30A having the guide structures 56b, 56Ab can be provided at low cost.

(4-6)

9, in the humidifying unit 60, a moisture-absorbing duct 68 is disposed above the outdoor fan 39. As shown in Fig. The moisture absorbing duct 68 for guiding the outside air from the intake port 68a to the moisture absorption portion 61 is curved downward when a line passing through the middle between the upper end and the lower end is formed. The outside air coming from below through the path r1 is easily sucked by the moisture absorbing duct 68 and the outside air supplied to the moisture absorbing unit 61 is increased and the humidifying performance is improved.

(5) Modifications

(5-1)

In the above embodiment, a pair of air conditioners 10 is described in which one outdoor unit 30 is connected to one indoor unit 20. However, the type of the air conditioner to which the present invention can be applied, It is not limited to the type. For example, the present invention can be applied to a multi-type air conditioner in which a plurality of indoor units are connected to one outdoor unit.

(5-2)

The case in which the inside of the casing 40 of the outdoor unit 30 is divided into the blower chamber 41 and the machine room 42 has been described in the above embodiment, (40), the outdoor unit of the present invention can be constructed. For example, a partitioned space may be formed other than the fan chamber 41 and the machine room 42. For example, the machine room 42 may be provided as another room including other functions.

(5-3)

In the above embodiment, the outdoor heat exchanger 33 has an L-shaped shape when viewed from the upper surface. However, the outdoor heat exchanger constituting the outdoor unit of the present invention is not limited to the above-described shape. For example, the outdoor heat exchanger may have an I-shape when viewed from the top.

(5-4)

As shown in Fig. 5, an exhaust duct 80 may be provided. Even when such an exhaust duct is provided, it is preferable that a clearance Is2 (see Fig. 6) above a predetermined gap Is is provided between the rear face of the exhaust duct from the front face 33a of the outdoor heat exchanger 33 Do. Further, it is preferable that an inclined portion is provided below the exhaust duct 80, and the ventilation resistance is lowered by the inclined portion 80a.

(5-5)

In the above embodiment, the outdoor fan 39 has the propeller 39b, but is not limited to the one having the propeller 39b. The outdoor unit of the present invention can also be constituted by an outdoor fan having a blade of a type other than the propeller type.

(5-6)

In the above embodiment, description will be given of the case where the moisture absorption portion 61 is larger than the moisture absorption portion 62 and the central angle? Of the moisture absorption portion 61 is larger than 180 degrees as shown in Fig. The sizes of the moisture absorption portion 61 and the moistureproof portion 62 can be appropriately set. E.g. 13, the central angle may be set to 180 degrees so that the size of the moisture-absorbing portion 61 and the moisture-proof portion 62 are substantially equal to each other.

(5-7)

In the above embodiment, a dedicated fan for guiding the outside air to the moisture absorption portion 61 or a motor for driving the fan is omitted, but a dedicated fan or a motor for a dedicated fan may be mounted. Even in such a case, since the air is blown to the moisture absorption portion 61 by the outdoor fan 39, a dedicated fan for only directing the ambient air to the moisture absorption portion 61 or a motor for the exclusive fan can be made smaller The outdoor unit can be made more compact than the conventional one.

(5-8)

In the above embodiment, the case where the partition plate 43 divides the moisture-proof portion 62 and the turbo fan 75 is described, but the partition plate 43 shown in Figs. 14 and 15 It is also possible to form a partition between the moisture-absorbing portion 61 and the moisture-proof portion 62. 14 and 15, by disposing the partition plate 43 at the boundary between the moisture absorption portion 61 and the moistureproof portion 62, the humidity protection portion 62, the humidification duct 73, (75) may be installed in the machine room (42). Thereby, it is possible to prevent the moisture-proof portion 62 from being cooled by the outside air that has passed through the outdoor heat exchanger 33. Not only the parts of the turbo fan 75 and the humidifying duct 73 but also the entire moisture-proof part 62 and the humidifying duct 73 are separated from the passage of the outside air passing through the outdoor heat exchanger 33, It is possible to reduce an increase in ventilation resistance caused by these. In this modified example as well, the above-described guide structure can be applied by moving the position of the guide structure to the partition plate 43 by matching the position of the intake port 68a.

14 and 15 show an example in which the moisture-proof portion 62 is entirely disposed in the machine room 42, a part of the moisture-proof portion 62 may be arranged in the machine room 42. FIG. In the case where a part of the moisture-proof part 62 is disposed in the machine room 42, the effect of reducing the increase in the ventilation resistance and the effect of preventing the moisture-proof part 62 from being cold The effect is smaller, but this effect is improved compared to the first embodiment.

Although the turbo fan 75 is disposed in the forward and backward directions in which the rotary shaft extends, the installation direction of the turbo fan 75 is not limited to this example. For example, as shown in Fig. 15, the direction in which the rotation axis extends may be made to coincide with the left and right direction, which is the longitudinal direction of the casing 40. [ By thus aligning the direction in which the rotary shaft extends in the longitudinal direction of the casing 40, the length of the casing in the longitudinal direction can be shortened.

≪ Third Embodiment >

(1) Outline of configuration of air conditioner and outdoor unit

Next, an outdoor unit of the air conditioner according to the third embodiment will be described with reference to Figs. 17 to 23. Fig. An outline of the configuration of the air conditioner in which the outdoor unit 30B according to the third embodiment shown in Figs. 17 to 23 is mounted is shown in Fig. 17, in which, in the first embodiment, Is substantially the same as the outline of the configuration of the air conditioner 10 described above, but is partially changed. The outdoor unit 30B of the third embodiment also includes a casing 40B and a partition plate 43B similar to the outdoor unit 30 of the first embodiment. As shown in Figs. 17 and 20, The inner space of the casing 40B is partitioned by the partition plate 43B into the blower chamber 41B and the machine room 42B. The outdoor unit 30B is provided with a compressor 31, a switching valve 32, an outdoor heat exchanger 33, an electric valve 34, a filter 35, an accumulator A liquid shutoff valve 37, and a gas shutoff valve 38 are provided. 20, an outdoor fan 39B, to which the propeller 39Bb is driven by the fan motor 39Ba, is provided on the downstream side of the outdoor heat exchanger 33. As shown in Fig. The propeller 39Bb rotates counterclockwise when viewed from the front. The humidifying unit 60B is disposed in the space of the blower chamber 41B and is disposed above the outdoor fan 39B.

(2) Humidification unit

17, the structure of the humidifying unit 60B is the same as that of the humidifying unit 60 of the first embodiment in that the humidifying unit 60B has the moisture-absorbing portion 61 and the moisture-proof portion 62. [ 10, that the humidifying unit 60B has one disk-like humidification rotor 63 and the heater 71 shown in Fig. 10, the moisture-absorbing duct 68 shown in Fig. 9, (See Fig. 20) corresponding to the air outlet 69 shown in Fig. 7 and the air inlet 72 shown in Fig. 7, and the point that the humidification duct 73 and the turbo fan 72 And the turbo fan 75B corresponding to the humidifier unit 75 of the first embodiment is the same as the humidifier unit 60 of the first embodiment.

The structure in which the suction port 72B of the humidification unit 60B is different in shape and size from the suction port 72 of the humidification unit 60 and the outside air sucked from the suction port 72B is sent to the humidifying rotor 63 The humidification unit 60B is also the same as the humidification unit 60. Fig. The arrangement of the turbo fan 75 of the humidification unit 60 is vertical, while the turbo fan 75B of the humidification unit 60B is horizontally arranged. That is, while the rotational axis of the impeller wheel of the turbo fan 75 extends in the fore and aft direction, the rotational axis of the impeller wheel of the turbo fan 75B extends in the up and down direction. The turbo fan 75B is disposed in the blower chamber 41B above the propeller 39Bb as shown in Fig. 20, but the turbo fan 75B is arranged inside the blower chamber 41B Respectively.

A filter 68f is mounted on the suction port 68a of the humidification unit 60B. This makes it difficult to draw in the outside air as much as the pressure loss in the filter 68f as compared with the humidification unit 60 with respect to the flow of the outside air to be sucked. However, the structure that can suck a sufficient amount of outside air by the guide structure Respectively.

(3) Relation between the arrangement of the outdoor heat exchanger and the humidifying unit

Fig. 20 shows a humidifying unit 60B disposed in front of the outdoor heat exchanger 33. Fig. It is one of the characteristics of the outdoor unit 30B that the humidifying unit 60B is exposed and arranged in front of the outdoor heat exchanger 33. [ The height of the position of the upper surface 60Ba of the humidification unit 60B coincides with the height of the upper end 33b (top portion) of the outdoor heat exchanger 33. [ For this reason, the humidification unit 60B is given a shape in which the volume is reduced as much as possible without changing the appearance of a relatively complex appearance. Here, the height of the position of the upper surface 60Ba of the humidification unit 60B is made to coincide with the height of the upper end 33b of the outdoor heat exchanger 33. The height of the upper surface 60Ba of the outdoor heat exchanger 33 And the humidifier unit 60B is exposed and arranged in front, thereby making the outdoor unit 30B compact.

(4) Casing

Fig. 18 is a front view of the outdoor unit 30B, Fig. 19 is a perspective view of the outdoor unit 30B, and Fig. 19 shows a state in which the grill 56 and the like are removed from the outdoor unit 30B of Fig. The casing 40B of the outdoor unit 30B is provided with a front plate 46B, a right plate 47, a top plate 48 and a bottom plate 49. [ Similarly to the casing 40, the left side surface of the casing 40B is fitted with a left side plate formed in a lattice shape with respect to the front surface on the left side surface portion of the L-shaped outdoor heat exchanger 33. [ Like the casing 40, a protective wire mesh covering the rear portion of the outdoor heat exchanger 33 is mounted on the rear side of the blower chamber 41B of the casing 40B, and the rear side of the blower chamber 41B is opened.

A circular outlet port 44 shown in Fig. 19 is formed in the front plate 46B, and a ring-shaped bell mouth 52 is mounted around the outlet port 44. Fig. And a part of the propeller 39Bb is arranged to be accommodated in the space surrounded by the bell mouth 52. [

The difference between the casing 40B of the outdoor unit 30B of the second embodiment and the casing 40 of the first embodiment is that the opening 46Ba for the intake port 68a and the opening 46Ba for the intake port 72B (46Bb) is formed separately from the front plate 46B. On the other hand, only one opening 46a (see FIG. 3) for the intake port 68a and the intake port 72 is formed in the front plate 46 of the casing 40 of the first embodiment. The two openings 46Ba and 46Bb of the front plate 46B are separated by a rib 56q (see Fig. 23) of a grill 56B described later.

(5) Grills

Fig. 21 shows a state in which the grill 56B mounted on the casing 40B is viewed from the rear, with the outdoor heat exchanger 33, the outdoor fan 39B, and the like removed from the casing 40B. Fig. 22 is a rear view of the grill 56B, and Fig. 23 is a perspective view of the grill 56B as viewed from the diagonal line on the back. The grill 56B shown in Fig. 18 is mounted on the front plate 46B of the casing 40B and covers the outlet 44. Fig. In the grill 56B, a plurality of openings 56a are formed between the fingers 56d and 56d. On the upper portion of the grill 56B, a guide structure 56Bb is formed of a resin plate.

As shown in Figs. 18 and 21, the guide structure 56Bb is formed so as to be caught by a part of the air outlet 44 when seen from the front (or rear side), and is taken out from the air outlet 44 Thereby blocking a part of the air flow. In order to form the guide structure 56Bb, injection molding in which the opening 56a is not formed by closing the space between the flesh 56d and the flesh 56d at the portion which becomes the guide structure 56Bb, similarly to the formation of the grill 56, The guide structure 56Bb can be formed on the resin grill 56B.

21, in the outdoor unit 30B, it is found that the guide structure 56Bb has the overlapping portion 56Bb1 with the front plate 46B and the overlapping portion 56Bb2 with the blowout opening 44 . The space between the overlapping portion 56Bb1 of the front plate 46B and the front plate 46B becomes a passage and the outside air that has changed its direction to the overlapping portion 56Bb2 with the blow- 56Bb1, and the front plate 46B, and is guided to the intake port 68a. When the area of the overlapping portion 56Bb2 with the air outlet 44 increases, the air flow amount of the outside air introduced into the air inlet port 68a increases while the air flow resistance increases at the overlapping portion 56Bb2 with the air outlet 44, Resulting in a decrease in the air volume of the outside air which is led to the outdoor unit 33. Therefore, the area of the overlapping portion 56Bb2 with the blow-out port 44 is set such that an appropriate air volume is distributed to both.

In the grill 56B, a suction opening 56p is formed at a position facing the suction port 72B. The periphery of the suction opening 56p is surrounded by the ribs 56q and the outside air sucked from the inlet port 72B is not blown by the outdoor fan 39B but is received from the front of the outdoor unit 30B . Outside air directed from the air outlet 44 to the air inlet 68a is blocked by the guide structure 56Bb so as not to be sucked into the air inlet 72B by the rib 56q surrounding the suction opening 56p.

On the inner surface of the grill 56B, a rib 56r is formed below the suction opening 56p. The ribs 56r are formed in a smooth plate shape and extend in the rotating direction of the outdoor fan 39B. In other words, the rib 56r extends in a direction substantially orthogonal to a straight line extending radially from the rotation center 39Bb1 of the propeller 39Bb of the outdoor fan 39B. The intake port 68a is opposed to the area Ar2 surrounded by the advantageous lane in Fig. In this rib 56r, the front plate 46B and the guide structure 56Bb, a channel surrounded by three sides of the path r5 shown in Fig. 23 is formed. This channel smoothly guides the outside air swirled out from the air outlet 44 in the rotating direction of the propeller 39Bb of the outdoor fan 39B along the path r5.

(6) Features

(6-1)

The space from the outdoor heat exchanger 33 to the portion partitioned by the outdoor fan 39B and the bell mouth 52 is the same as that of the outdoor fan 39B when the outdoor fan 39B is rotating It is a space that becomes negative pressure. The exhaust port 69 faces the negative pressure space, and air flows toward the negative pressure space from the side where the humidification rotor 63 is present, with the exhaust port 69 sandwiched therebetween. On the other hand, an air current is blown out from the blow-out port 44 in front of the bell mouth 52.

The air that has been changed to the guide structure 56Bb shown in Figs. 22 and 23 is introduced into the outdoor unit 30B from the air outlet 44 through the air inlet 68a and the air outlet 69 via the moisture absorber 61 A path r5 is formed. As a result, the outdoor air can be efficiently guided to the moisture absorption portion 61 by the outdoor fan 39B, thereby improving the moisture absorption function. As a result, since the outside air can be delivered to the moisture absorption portion 61, the conventional dedicated fan or the drive motor for the dedicated fan can be omitted. In the above-described embodiment, the case where the dedicated fan or the like is omitted has been described. However, if the dedicated fan or the drive motor can be downsized, the downsizing of the humidification unit 60B can be achieved. If the humidification unit 60B can be downsized, the downsizing of the outdoor unit 30B can be achieved.

(6-2)

The configuration of the third embodiment shown in Fig. 23 is such that only the air guided to the path r5 along the guide structure 56Bb via the outdoor fan 39B is drawn into the intake port 68a. With such a configuration, it is possible to efficiently utilize the airflow generated by the outdoor fan 39 to efficiently introduce the outside air into the air inlet 68a.

In the third embodiment, the air introduced into the path r1 (first path) along the guide structure 56Ab shown in Fig. 13 is introduced to the air introduced into the path r4 (second path) An opening is provided in the guide structure 56Bb opposite to the intake port 68a of the third embodiment as in the case of the opening 56Aa of the second embodiment to form a path corresponding to the path r4 And air having a humidity higher than that of air in the path r1 may be introduced into the moisture absorption portion 61. [

(6-3)

As shown in Figs. 21 to 23, the guide structure 56Bb is formed in the grill 56B, and the guide structure 56Bb is attached to the front plate 46B together with the grill 56B. That is, the guide structure 56Bb can be mounted by mounting the grill 56B, and the guide structure 56Bb is mounted very simply.

Although the grill 56B and the guide structure 56Bb are integrally formed in the third embodiment, the grill 56B and the guide structure 56Bb may be separated from each other. The guide structure 56Bb may be directly mounted on the front plate 46B as well as the case where the guide structure 56Bb is indirectly mounted on the front plate 46B via the grill 56B as in the above embodiment .

As described above, the guide structure 56Bb is formed on the grill 56B and is formed of a portion where the opening 56a of the grill 56B is not formed. As a result, the guide structure 56Bb is formed at the same time as the grill 56B is formed. As a result, it is not necessary to add a dedicated process for forming the guide structure 56Bb, and the outdoor unit 30B having the guide structure 56Bb can be provided at low cost.

(6-4)

As shown in Fig. 20, the humidification unit 60B is also provided with a hygroscopic duct 68 above the outdoor fan 39B, like the humidification unit 60. As shown in Fig. Similarly to the moisture absorption duct 68 of the humidification unit 60, the moisture absorption duct 68 of the humidification unit 60B is also curved downward when a line passing through the middle between the upper and lower ends thereof is formed. As a result, the outside air coming from below through the path r1 is easily sucked by the hygroscopic duct 68, and the outside air supplied to the hygroscopic unit 61 increases, thereby improving the humidifying performance.

(6-5)

The ribs 56r shown in Figs. 22 and 23 are partition members disposed between the guide structure 56Bb and the front plate 46B to divide the space sandwiched between the guide structure 56Bb and the front plate 46B . The flow of the air that is guided from the air blow-out port 44 to the air inlets 68a through the ribs 56r passes through the channels surrounding the three sides of the front plate 46B, the guide structure 56Bb and the ribs 56r. Since the flow of air is surrounded by the channels formed by providing the ribs 56r (partition members), the flow of the air that does not reach the air inlet 68a is suppressed, . It is preferable that the partitioning member should be in contact with the front plate 46B so as to divide the space without gaps in order to suppress the flow of air in unnecessary directions, There is no.

The rib 56r is extended in the rotating direction of the outdoor fan 39B so that the flow of the air taken out from the outdoor fan 39B and turning in the rotating direction of the outdoor fan 39B is guided to the inlet 68a You can smoothly lead. As a result, it is possible to reduce the pressure generated by the rib 56r with respect to the flow of air leading to the intake port 68a.

(7) Modifications

(7-1)

In the third embodiment, as shown in Fig. 17, a pair of air conditioner 10 is described in which one outdoor unit 30B is connected to one indoor unit 20. However, The types of air conditioners that can be applied are not limited to the pair type. For example, the present invention can be applied to a multi-type air conditioner in which a plurality of indoor units are connected to one outdoor unit.

(7-2)

Although the third embodiment has described the case where the inside of the casing 40B of the outdoor unit 30B is divided into the blower room 41B and the machine room 42B, the blower room 41B is provided therein A space may be formed in addition to the blower chamber 41B and the machine room 42. For example, the machine room 42 may be provided with another Or may be provided as a thread.

(7-3)

In the third embodiment, the outdoor heat exchanger 33 has an L-shape when viewed from the top, but the outdoor heat exchanger constituting the outdoor unit of the present invention is not limited to the above-described shape. For example, the outdoor heat exchanger may have an I-shape when viewed from the top.

(7-4)

The exhaust duct 80 such as the humidifying unit 60 shown in Fig. 5 may be provided for the humidifying unit 60B.

(7-5)

Although the outdoor fan 39B has the propeller 39Bb in the third embodiment, it is not limited to the one having the propeller 39Bb. The outdoor unit of the present invention can also be constituted by an outdoor fan having a blade of a type other than the propeller type.

(7-6)

In the third embodiment, a dedicated fan for guiding the outside air to the moisture absorption portion 61 or a motor for driving the fan is omitted. However, a dedicated fan or a motor for a dedicated fan may be mounted. Even in such a case, since the air blowing to the moisture absorption portion 61 is performed by the outdoor fan 39B, it is possible to reduce the size of the dedicated fan or the motor for the exclusive fan only by introducing the outside air into the moisture absorption portion 61 The outdoor unit can be made more compact than the conventional one.

(7-7)

In the third embodiment, the case where the partition plate 43B divides the space between the turbo fan 75B and the air supply duct 18 has been described. As described in the first embodiment or the second embodiment, , Or partition the other places.

(7-8)

22 and 23, the grill 56B of the third embodiment has a structure in which the rib 56s is located only at a portion excluding the overlap portion 56Bb2 of the guide structure 56Bb with the air outlet 44 . However, the guide structure may have a baffle member which obstructs the flow of air from the inlet port toward the outlet port in the vicinity of the end near the rotation center of the outdoor fan. The grill 56C shown in Fig. 24 is used in place of the grill 56B shown in Fig. 22 for example to prevent the flow of air from the inlet port 68a toward the outlet port 44 The rib 56t may be formed as a baffle member at the end portion 56Cb3 of the guide structure 56Cb near the rotation center 39Bb1 of the outdoor fan 39B. In this case, since the flow of air from the intake port 68a toward the air outlet port 44 in the rib 56t can be suppressed, the amount of air introduced into the air inlet port 68a is increased compared with the grill 56B . Further, the grill 56C has the same structure as the grill 56B except for the structure of the ribs 56s. The baffle member is not limited to the rib structure such as the rib 56t but may be formed by other members such as a plastic film or a sponge. However, the baffle member may be integrally formed with the grille 56B like the rib 56t Structure is preferable.

(7-9)

As shown in Fig. 24, the grill 56C of the third embodiment has the inner surface of the guide structure 56Cb formed flat. However, a rectifying member disposed between the guide structure and the front plate and extending smoothly from the outlet to the inlet port may be provided. The grill 56D shown in Fig. 25 and Fig. 26 is used instead of the grill 56B shown in Fig. 22 so that the inner surface of the guide structure 56Db, that is, the guide structure 56Db and the front plate 46B And a rib 56u extending smoothly from the air outlet 44 toward the air inlet 68a may be provided as the rectifying member. With this structure, since the air flows along the ribs 56u toward the intake port 68a, the flow of air is regulated and the sound generated due to the flow of air toward the intake port 68a can be suppressed to a low level. The grill 56D also has the same structure as the grill 56B except for the structure of the ribs 56s and ribs 56u. The rectifying member is not limited to the rib structure such as the ribs 56u, but it is preferable that the rectifying member is integrally formed with the grill 56B like the rib 56u.

10 Air conditioner
20 indoor unit
30, 30B outdoor unit
33 outdoor heat exchanger
39, 39B outdoor fan
40, 40B casing
41, 41B blower room
56, 56A, 56B, 56C, 56D grill
60, 60B Humidification unit
63 Humidification rotor
68 Suction duct
73 Air duct for humidification
75, 75B Turbo Fans

Claims (10)

A casing (40) having a blower chamber (41) through which outside air passes,
An outdoor heat exchanger (33) installed in the blower room and performing heat exchange with the outside air,
An outdoor fan (39, 39B) installed in the blower room for blowing outside air to the outdoor heat exchanger,
Guide structures (56b, 56Ab, 56Bb, 56Cb, 56Db) formed on the downstream side of the outdoor fan and changing the direction of a part of the air blown by the outdoor fan,
A moisture absorbing portion 61 for absorbing moisture from the outside air; a moisture-proof portion 62 for moisture-proofing and humidifying the air; an air inlet 68a and an air outlet 69 for the outside air to be supplied to the moisture- And a humidifying unit (60) configured so that air, which is directed to the guide structure on the downstream side of the outdoor fan, is directed from the inlet port to the exhaust port via the moisture absorber, The outdoor unit of the air conditioner. The method according to claim 1,
Wherein all of the air drawn in from the inlet port is the air guided along the guide structures (56b, 56Bb, 56Cb, 56Db) via the outdoor fan. The method according to claim 1,
Wherein the humidifying unit sucks air introduced into a first path (r1) along the guide structure and air introduced into a second path (r4) different from the first path together at the intake port Outdoor unit. The method according to any one of claims 1 to 3,
The casing is provided with a front plate (46, 46B) having a blow-out port (44) for blowing outside air blown by the outdoor fan,
And the guide structure is mounted on the front plate so as to cover a part of the air outlet. A casing (40) having a blower chamber (41) through which outside air passes,
An outdoor heat exchanger (33) installed in the blower room and performing heat exchange with the outside air,
An outdoor fan (39, 39B) installed in the blower room for blowing outside air to the outdoor heat exchanger,
Guide structures (56b, 56Ab, 56Bb, 56Cb, 56Db) for changing the direction of a part of the air blown by the outdoor fan,
A moisture absorbing portion 61 for absorbing moisture from the outside air; a moisture-proof portion 62 for moisture-proofing and humidifying the air; an air inlet 68a and an air outlet 69 for the outside air to be supplied to the moisture- And a humidifying unit (60) in which the exhaust port is arranged facing the space, and the air whose direction is changed to the guide structure is made to pass from the intake port to the exhaust port via the moisture absorption portion,
The casing is provided with a front plate (46, 46B) having a blow-out port (44) for blowing outside air blown by the outdoor fan,
Wherein the guide structure is mounted on the front plate so as to cover a part of the outlet,
The casing further includes grills (56, 56Ab, 56Bb, 56Cb, 56Db) mounted on the front plate and covering the outlet of the front plate,
Wherein the guide structure is formed in the grill. A casing (40) having a blower chamber (41) through which outside air passes,
An outdoor heat exchanger (33) installed in the blower room and performing heat exchange with the outside air,
An outdoor fan (39, 39B) installed in the blower room for blowing outside air to the outdoor heat exchanger,
Guide structures (56b, 56Ab, 56Bb, 56Cb, 56Db) for changing the direction of a part of the air blown by the outdoor fan,
A moisture absorbing portion 61 for absorbing moisture from the outside air; a moisture-proof portion 62 for moisture-proofing and humidifying the air; an air inlet 68a and an air outlet 69 for the outside air to be supplied to the moisture- And a humidifying unit (60) in which the exhaust port is arranged facing the space, and the air whose direction is changed to the guide structure is made to pass from the intake port to the exhaust port via the moisture absorption portion,
The casing is provided with a front plate (46, 46B) having a blow-out port (44) for blowing outside air blown by the outdoor fan,
Wherein the guide structure is mounted on the front plate so as to cover a part of the outlet,
And a partition wall which is disposed between the guide structure (56Bb) and the front plates (46, 46B) to divide a space sandwiched between the guide structure and the front plate, the channel surrounding the flow of air from the outlet to the air inlet (68a) Further comprising a partition member (56r) for forming the partition member (56r). The method of claim 6,
And the partition member extends in the rotating direction of the outdoor fan. A casing (40) having a blower chamber (41) through which outside air passes,
An outdoor heat exchanger (33) installed in the blower room and performing heat exchange with the outside air,
An outdoor fan (39, 39B) installed in the blower room for blowing outside air to the outdoor heat exchanger,
Guide structures (56b, 56Ab, 56Bb, 56Cb, 56Db) for changing the direction of a part of the air blown by the outdoor fan,
A moisture absorbing portion 61 for absorbing moisture from the outside air; a moisture-proof portion 62 for moisture-proofing and humidifying the air; an air inlet 68a and an air outlet 69 for the outside air to be supplied to the moisture- And a humidifying unit (60) in which the exhaust port is arranged facing the space, and the air whose direction is changed to the guide structure is made to pass from the intake port to the exhaust port via the moisture absorption portion,
The casing is provided with a front plate (46, 46B) having a blow-out port (44) for blowing outside air blown by the outdoor fan,
Wherein the guide structure is mounted on the front plate so as to cover a part of the outlet,
The guide structure (56Cb) has a baffle member (56t) which obstructs the flow of air from the inlet port toward the outlet port in the vicinity of the end near the center of rotation of the outdoor fan. A casing (40) having a blower chamber (41) through which outside air passes,
An outdoor heat exchanger (33) installed in the blower room and performing heat exchange with the outside air,
An outdoor fan (39, 39B) installed in the blower room for blowing outside air to the outdoor heat exchanger,
Guide structures (56b, 56Ab, 56Bb, 56Cb, 56Db) for changing the direction of a part of the air blown by the outdoor fan,
A moisture absorbing portion 61 for absorbing moisture from the outside air; a moisture-proof portion 62 for moisture-proofing and humidifying the air; an air inlet 68a and an air outlet 69 for the outside air to be supplied to the moisture- And a humidifying unit (60) in which the exhaust port is arranged facing the space, and the air whose direction is changed to the guide structure is made to pass from the intake port to the exhaust port via the moisture absorption portion,
The casing is provided with a front plate (46, 46B) having a blow-out port (44) for blowing outside air blown by the outdoor fan,
Wherein the guide structure is mounted on the front plate so as to cover a part of the outlet,
Further comprising a rectifying member (56u) disposed between the guide structure (56Db) and the front plate and extending from the outlet to the inlet port (56u). A casing (40) having a blower chamber (41) through which outside air passes,
An outdoor heat exchanger (33) installed in the blower room and performing heat exchange with the outside air,
An outdoor fan (39, 39B) installed in the blower room for blowing outside air to the outdoor heat exchanger,
Guide structures (56b, 56Ab, 56Bb, 56Cb, 56Db) for changing the direction of a part of the air blown by the outdoor fan,
A moisture absorbing portion 61 for absorbing moisture from the outside air; a moisture-proof portion 62 for moisture-proofing and humidifying the air; an air inlet 68a and an air outlet 69 for the outside air to be supplied to the moisture- And a humidifying unit (60) in which the exhaust port is arranged facing the space, and the air whose direction is changed to the guide structure is made to pass from the intake port to the exhaust port via the moisture absorption portion,
Wherein the humidifying unit further comprises a moisture absorption duct disposed above the outdoor fan for guiding ambient air to the moisture absorption section from the intake port, wherein the moisture absorption duct is curved downward Outdoor units of harmonics.

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