KR100389422B1 - A saturation water drain structure for air conditioner - Google Patents

Abstract

The present invention relates to a condensate drainage structure of an air conditioner. In the present invention, the condensed water generated on the outer surfaces of the air guide 60 and the air guide 70 for guiding the flow of air in the interior side of the integrated air conditioner is to smoothly drain. To this end, the lower passage 67 is formed in the lower guide 60 to be stepped on the side wall 65. The lower flow path 67 is formed to be inclined toward the drain 68 of the lower air guide 60 to guide the condensate. In addition, an upper flow path 76 is formed at the lower end of the side wall 75 in the upper air guide 70 to discharge the condensed water generated at the outer surface of the side wall 75 to the drain 68. According to the present invention, the condensate is not leaked to the outside of the air conditioner, and condensate can be delivered to a desired position, and condensate can be prevented from occurring on the outer surface of the outer case.

Description

A saturation water drain structure for air conditioner

The present invention relates to an integrated air conditioner, and more particularly to a condensate drainage structure for draining the condensate generated on the outer surface of the air guide for guiding the flow of air from the indoor side.

1 is an exploded perspective view showing a main configuration of an integrated air conditioner according to the prior art. Looking at the internal structure of the integrated air conditioner with reference to this, the base fan (1) forms the bottom of the air conditioner. The front grill 3 is installed on the indoor front surface of the base fan 1.

In the front grill 3, a suction part 3i, which is a passage through which air in the room is introduced, is formed at a lower side thereof, and an upper part of the front grill 3 has a discharge grill 3e for discharging the heat exchanged inside the air conditioner to the room Is formed. Although not shown in the drawings, a suction grill (not shown) is installed in the suction unit 3i, and a filter (not shown) is installed between the suction grill and the suction unit 3i.

An indoor heat exchanger 5 is installed inside the front grill 3. The indoor heat exchanger (5) is for heat exchange between the air sucked through the suction unit (3i) and the working fluid of the air conditioning cycle, more precisely installed in the air guide (7) to be described below.

An air guide 7 is installed on the base fan 1 at the rear of the indoor heat exchanger 5. The air guide 7 serves to partition the air conditioner into the indoor side and the outdoor side as a whole. Therefore, the indoor side and the outdoor side are blocked by the air guide 7 to block the flow of air therebetween.

The air guide 7 has a support rib 7r for supporting the lower end of the indoor heat exchanger 5. Two support ribs 7r are formed side by side to support the lower end of the indoor heat exchanger 5. The support rib 7r is formed in the condensate channel 7c of the air guide 7. The condensate channel 7c is for draining the condensate generated by the indoor heat exchanger 5, and is formed to be inclined downward from the left side to the right side in front of the air guide 7 with reference to FIG. 1. A drainage guide 8 is formed at the right rear end of the air guide 7 so as to be connected to the condensate channel 7c. The drainage guide 8 drains the condensed water transferred through the condensate channel 7c to the area A of the base pan 1.

Meanwhile, a scroll 9 is installed inside the air guide 7. The scroll 9 has a flow guide surface 9g formed therein with a predetermined curvature from one side to the other side. Such a scroll guides the flow of air therein and also serves to block heat transfer between the indoor side and the outdoor side.

Next, an orifice 11 is installed to correspond to the front surface of the scroll 9, that is, the indoor heat exchanger 5. The orifice 11 is perforated with an orifice hole 12 which guides the air flowing through the indoor heat exchanger 5 to the sirocco fan 13 which will be described below. A discharge guide 11e for guiding the air heat-exchanged with the discharge grill 3e is integrally formed at the upper end of the orifice 11.

Meanwhile, a sirocco fan 13 is installed inside the scroll 9 to allow indoor air to flow through the suction unit 3i, the indoor heat exchanger 5, and the orifice hole 12. The sirocco fan 13 sucks air through the orifice hole 12 and blows it in the centrifugal direction. The blown air is guided along the flow guide surface 9g to the discharge guide 11e. Flows.

The part described so far is the indoor side of the integrated air conditioner, and now describes the configuration of the outdoor side partitioned from the indoor side by the air guide 7.

On the outdoor side of the air guide 7 is mounted a sirocco fan 13 and a motor 15 for rotating the blowing fan 17 to be described below. The motor 15 protrudes in a direction in which the rotation shafts face each other. One of the rotating shafts penetrates the air guide 7 and extends to the center of the scroll 9 to rotate the sirocco fan 13.

And the blower fan 17 is installed on the outdoor rotating shaft of the motor (15). The blower fan 17 serves to exchange heat by sucking outside air to the outdoor side of the air conditioner and passing the outdoor heat exchanger 19 to be described below. The blower fan 17 is provided with a ring 17r for connecting the wing tip thereof. The ring 17r splashes the condensed water transferred onto the base pan 1 and sprinkles it on the outdoor heat exchanger 19 which will be described below, so that the heat exchange is better.

Next, a shroud 18 for guiding the air flow formed by the blowing fan 17 is installed on the base fan 1. The shroud 18 is formed with a through hole 18 ′ communicating with the outdoor heat exchanger 19 side such that the blowing fan 17 is located.

The outdoor heat exchanger 19 is installed on the outdoor side of the base fan 1 so as to face the shroud 18. The outdoor heat exchanger 19 allows the air sucked from the outside and the working fluid of the air conditioning cycle to exchange heat. Although not shown in the drawings, the outdoor side is provided with a compressor, an expansion valve, and the like that are components of an air conditioning cycle.

Finally, the outer case 20 shields the various parts forming the air conditioner as described above from the outside. The outcase 20 as described above constitutes the appearance of the air conditioner.

In the integrated air conditioner having such a configuration is operated for cooling, condensate is generated in the indoor heat exchanger (5). The condensate is contained in the air in the space for cooling, and is generated by condensation when the air exchanges heat with the indoor heat exchanger (5).

The condensate is delivered to the condensate channel 8 at the bottom of the indoor heat exchanger 5 and moves along the slope, and finally through the drainage guide 8, to the area A of the base pan 1. do. The condensed water delivered to the area A is delivered to the rear of the base fan 1 because the air conditioner is installed so that the rear of the base fan 1 is inclined downward.

The condensed water delivered to the rear of the base fan 1 is splashed by the ring 17r of the blower fan 17 and sprinkled on the outdoor heat exchanger 19. At this time, the condensate is at a relatively low temperature, so that it is sprayed on the outdoor heat exchanger 19 to heat exchange with a relatively high temperature refrigerant passing through the outdoor heat exchanger 19 to increase heat exchange efficiency.

However, the prior art as described above has the following problems.

In the air conditioner of the above configuration, the air guide 7 is to guide the air flow of the indoor side. The air guided by this air guide 7 is relatively low temperature when the air conditioner is operated in the cooling mode. Accordingly, a large temperature difference is generated between the outer surface and the inner surface of the air guide 7, and a large amount of condensed water is generated on the side of the air guide 7 by the temperature difference.

However, the structure for draining the condensate as described above is not provided on the side of the air guide (7), the condensed water generated from the side of the air guide (7), especially in a humid environment, the air guide (7) It flows down the side of the car and happens to come out of the air conditioner. The condensed water flowing out of the air conditioner falls to the bottom of the air conditioner and becomes a user's dissatisfaction factor.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to drain the condensate generated in the outer wall of the air guide in the desired direction.

1 is an exploded perspective view showing a main configuration of an air conditioner according to the prior art.

Figure 2 is an exploded perspective view showing a preferred embodiment of the condensate drainage structure of the integrated air conditioner according to the present invention.

Figure 3 is a side perspective view showing the configuration of an embodiment of the present invention.

4 is a cross-sectional view showing the main portion of the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

60: air guide 61: flow path forming portion

62: control box seat 63: pipe seat

64: rear wall 64 ': motor mounting hole

65: side wall 66: upper flange

67: lower flow path 68: drain

69: support rib 69 ': drain hole

70: upper guide 71: top plate

72: communication part 74: rear wall

75,75 ': Sidewall 76: Upper flow path

77: drain hole 78: fastener

According to a feature of the present invention for achieving the object as described above, the present invention partitions the indoor side and the outdoor side and the air guide which is guided in the air heat exchanged in the indoor heat exchanger by suction in the space for air conditioning, The air guide layer is installed at the upper end of the lower air guide and guides the heat exchanged air guided by the lower air guide to a space for air conditioning. An air insulation layer is provided between the sidewall of the lower air guide and the outer case. A lower flow path is formed at a lower end of the side wall to guide the condensate generated from the side wall. An air insulation layer is formed between the side guide of the upper air guide and the outer case. An upper flow path is formed to guide the condensate generated in the reactor.

The lower air guide and the lower air guide sidewalls are formed to be recessed inwardly to form an air insulation layer, and the lower sidewalls and the upper channel are formed at the lower end of the sidewalls, respectively.

The upper flow path and the lower flow path are inclined toward the tip of the lower air guide.

A barrier wall is formed along the upper passage and the lower passage, respectively, to prevent the condensate from overflowing in the passage.

The condensate drainage device of the air conditioner according to the present invention having such a configuration allows the condensate water formed on the outer surface of the component for guiding the flow of air from the indoor side of the integrated air conditioner to be reliably drained to a desired place.

Hereinafter, a configuration of a preferred embodiment of a condensate drainage device of an air conditioner according to the present invention as described above will be described in detail with reference to the accompanying drawings.

2 and 3, the lower air guide 60 and the upper air guide 70 partition the indoor side and the outdoor side in the integrated air conditioner and serve to guide the air flow in the indoor side. The lower air guide 60 guides the flow of air that is sucked in the space for air conditioning and heat exchanged in the indoor heat exchanger, and the upper air guide 70 returns the air passing through the lower air guide 60 again. It is to guide the discharge to the space for air conditioning.

The lower air guide 60 is largely composed of a flow path forming part 61, a control box seating part 62, and a pipe seating part 63. The flow path forming portion 61 is installed therein and serves to guide the air formed by the turbo fan. A guide surface 61 ′ for guiding air is formed in the flow path forming portion 61. Since the control box seating part 62 and the pipe seating part 63 are not related to the gist of the present invention, description thereof will be omitted.

The rear end of the flow path forming portion 61 is formed by the rear wall 64, the rear wall 64 serves to partition the indoor side and the outdoor side. In the center of the rear wall 64, a motor seating hole 64 'is formed on which a motor for rotating the turbo fan is mounted.

The side wall 65 forms one side of the flow path forming part 61. An upper flange 66 is formed at an upper end of the side wall 65, and a fastening hole 66 ′ is formed at the upper flange 66 for fastening with the upper guide 70.

In addition, the side wall 65 is formed to be stepped so that the upper end thereof is relatively recessed relative to the portion corresponding to the outside of the guide surface 61 ′, and a lower flow path 67 is formed in the stepped portion. . The lower passage 67 is preferably formed to be inclined downward toward the drain portion 68 to be described below. A blocking wall 67 ′ is formed along the lower channel 67 to prevent condensate from overflowing in the lower channel 67 and flowing along the lower portion of the side wall 65.

As the side wall 65 is formed to be recessed as described above, a space is formed between the recessed side wall 65 and an outer case (not shown) constituting the exterior of the air conditioner. The air insulation layer is formed.

Next, a drain 68 is formed at the lower end of the lower air guide 60. The drain portion 68 is configured to drain the condensate generated in the indoor heat exchanger, and is formed at the tip of the lower air guide 60 corresponding to the flow path forming portion 61 and the pipe seating portion 63.

The drainage portion 68 has a support rib 69 for supporting the lower end of the indoor heat exchanger is formed long side by side from one side to the other side. One end of the drain portion 68 is formed with a drain hole 69 ′ for draining the condensed water through the lower portion of the pipe seating portion 63.

Meanwhile, the drain portion 68 is formed to be inclined toward the other side, in detail, the drain hole 69 'from the one side. In this way, the inclined drainage portion 68 is formed so that the drainage of the condensate can be made more smoothly.

Next, the configuration of the upper guide 70 will be described. The upper air guide 70 is to be installed on the upper end of the lower air guide (60). The upper plate 71 of the upper air guide 70 shields the upper end of the lower air guide 60, which communicates the inside of the upper air guide 70 with the inside of the lower air guide 60. The communication part 72 is formed.

The rear wall 74 is formed at the rear end of the upper air guide 70, and the rear wall 74 serves to partition the indoor side and the outdoor side from the air guide 70. Side walls 75 and 75 ′ are provided at both ends of the rear wall 74 to form an inner space of the upper guide 70. The front and top surfaces of the air guide 70 between the side walls 75 and 75 'are open.

An upper flow path 76 is formed at a lower end of the side wall 75 to protrude from the side wall 75. The upper channel 76 guides the flow of condensate generated from the outer surface of the side wall 75, and its configuration is similar to that of the lower channel 67. In addition, the upper flow path 76 is formed to be inclined toward the drain portion 68, and a drain hole 77 is drilled at a position corresponding to the drain portion 68 in the upper flow path 76. Therefore, the condensate falls directly into the drain 68 along the drain hole 77. A blocking wall 76 ′ is formed along the upper channel 76 to prevent the condensate from overflowing from the upper channel 76. In the drawing, reference numeral 78 is a fastening hole for fastening with the lower air guide 60.

On the other hand, the side wall 75 of the upper air guide 70 is also formed to be recessed inside to form a predetermined space between the outer case. The space thus formed forms an air insulation layer.

Hereinafter, the operation of the condensate drainage structure according to the present invention having the configuration as described above will be described in detail.

The upper air guide 70 is installed at an upper end of the lower air guide 60, and the lower air guide 60 is sucked in a space for air conditioning and installed at the front end of the upper air guide 70. The air passing through the plane is delivered.

When the air conditioner is operated in the cooling mode, the air passing through the indoor heat exchanger is brought to a relatively low temperature. Therefore, the air flowing in the flow path forming portion 61 of the lower air guide 60 and the air on the outer surface of the lower air guide 60 have a relatively large temperature difference.

Meanwhile, the air passing through the lower air guide 60 is guided into the upper air guide 70 through the communicating portion 72 and is discharged from the upper air guide 70 into a space for air conditioning. do. At this time, the air flowing inside the air guide 70 and the air around the air guide 70 has a significant temperature difference.

Due to the difference in temperature between the inside of the upper and lower air guides 60 and 70 and the surrounding air as described above, a large amount of condensate is formed on the outer surface of the side walls 65 and 75 which are adjacent to the cabinet forming the exterior of the air conditioner. Will occur.

First, the condensed water formed on the side wall 65 of the lower air guide 60 flows down the side wall 65 to the lower flow path 67. The lower portion of the lower sidewall 65 of the air guide 60, that is, the portion corresponding to the guide surface 61 ′, is shown in FIG. 2, and the surface and the sidewall 65 of the guide surface 61 ′. ) Due to the thick thickness between the lower surfaces, there is relatively no condensation.

The condensed water delivered to the lower passage 67 flows along the inclination of the lower passage 67 and is transferred from the end of the lower passage 67 to the drain portion 68 along the tip of the side wall 65. . As such, the condensed water delivered to the drain portion 68 is transferred to the outdoor base pan through the drain hole 69 'together with the condensed water generated in the indoor heat exchanger.

In addition, a lot of condensate is also generated on the outer surface of the side wall 75 of the upper guide 60, the condensate is delivered to the upper flow path 76 formed on the lower side of the side wall (75). The condensed water delivered to the upper flow path 76 flows along the inclination of the upper flow path 76 and then falls down to the drain portion 68 through the drain hole 77.

The condensed water dropped to the drain portion 68 flows along the drain portion 68 together with the condensed water generated in the indoor heat exchanger and is discharged through the drain hole 69 '.

On the other hand, the air insulation layer is formed between the side wall 65 and the outer case of the lower air guide 60 and the side wall 75 and the outer case of the upper guide 70 to be recessed. Is formed. The air insulation layer acts as a thermal insulation between the lower air guide 60 and the upper air guide 70 and the outer case, and in particular, prevents condensation from forming on the outer surface of the outer case.

Condensate drainage of the integrated air conditioner according to the present invention as described in detail above to smoothly drain the condensate generated by the temperature difference between the inside and outside of the air guide and the air guide to guide the flow of air from the indoor side It is configured to be possible. Therefore, the condensed water generated inside the air conditioner can be delivered to the base pan of the outdoor side through the drainage portion so that the condensed water can be drained to a desired position, thereby preventing the leakage of the condensed water generated from the air conditioner.

In addition, the condensate can be prevented from occurring on the outer surface of the outer case by the temperature difference between the inside of the air guide and the outer case.

In addition, the condensed water delivered to the base fan of the outdoor side as described above can also be expected to reduce the temperature of the outdoor heat exchanger to increase the efficiency of the air conditioner.

Claims (4)

A air guide which divides the indoor side and the outdoor side and guides the air that is sucked in the space for air conditioning and heat exchanged in the indoor heat exchanger; Installed in the upper of the lower air guide and consists of an upper air guide for guiding the heat exchanged air guided from the lower air guide to the space for air conditioning, An air insulation layer is formed between the side wall of the lower air guide and the outer case, and a lower flow path is formed at the lower end of the side wall to guide the condensate generated from the side wall, and between the side wall of the air guide and the outer case. An air insulation layer is formed, and a condensate drainage structure of the air conditioner, characterized in that the upper flow path is formed to guide the condensate generated in the side wall at the bottom of the side wall of the upper guide. According to claim 1, wherein the lower air guide and the side wall of the lower air guide is formed so as to form an air insulation layer, and the lower side and the upper flow path is formed at the bottom of the side wall by the side wall is formed to be recessed, respectively. A condensate drainage structure of an air conditioner. The condensate drainage structure of claim 1 or 2, wherein the upper flow path and the lower flow path are inclined toward the tip of the lower air guide. 4. The condensate drainage structure of claim 3, wherein a barrier wall is formed along the upper flow path and the lower flow path, respectively, to prevent condensate from overflowing in the flow path.