KR100597957B1 - Drain pan structure for air-conditioner - Google Patents

Abstract

The present invention relates to a drain fan structure for an air conditioner, and the present invention relates to a drain fan provided in an air conditioner having a blower fan provided in an outer casing and a heat exchanger disposed inclined to an upper portion of the blower fan to exchange heat. A support portion receiving the drain water generated during the discharge; A discharge part provided below the support part to discharge drain water collected in the support part; It characterized in that it comprises a flow path guide for uniformly distributing air discharged from the discharge end of the blowing fan throughout the heat exchanger.

As described above, the present invention has a small thickness of the outer casing to make the air conditioner compact, so that even if the heat exchanger is arranged to have a relatively large inclination angle, the air from the blower fan is evenly distributed throughout the heat exchanger so that heat exchange efficiency can be increased. Will be.

Air Conditioner, Drain Fan, Euro Guide, Duct

Description

Drain pan structure for air conditioner

1 is an internal side view of a conventional air conditioner,

2 is a perspective view of the drain pan employed in FIG.

3 is a side view of FIG.

4 is an internal side view of an air conditioner equipped with a drain pan according to the present invention;

Explanation of symbols on the main parts of the drawings

10: outer casing 12: heat exchanger

14: blower fan 20: front cover

30: drain pan 31: support portion

32: discharge part 33: euro guide

The present invention relates to a drain fan structure for an air conditioner, and more particularly, in order to make the air conditioner compact, the thickness of the outer casing is made small so that the heat from the blower fan is exchanged even if the heat exchanger is arranged to have a relatively inclined angle. The present invention relates to a drain fan structure for an air conditioner that is evenly distributed throughout the machine to increase heat exchange efficiency.

In general, air conditioners are classified into a wall-mounted air conditioner and a stand-type air conditioner according to an installation method.In accordance with the structure, an air conditioner is an integrated air conditioner in which an indoor unit and an outdoor unit are integrated, and a separate air conditioner that separates an indoor unit and an outdoor unit separately. Divided.

Among the separate air conditioners, a compressor for compressing a refrigerant at high temperature and high pressure is installed in the outdoor unit, and a first heat exchanger for condensing the compressed refrigerant is provided, and a second heat exchanger for heat-exchanging the condensed refrigerant is provided in the indoor unit. .

Hereinafter, the air conditioner specified in the present invention will be described by referring to the indoor unit and the heat exchanger of the stand type in the second heat exchanger.

As shown in FIG. 1, a conventional air conditioner is provided with a predetermined component part therein and is coupled to an outer casing 110 having an open front surface and an outer casing 110 to form a front surface of the air conditioner. Has a front cover 120.

Discharge ports 122 and suction ports 121 are formed in upper and lower regions of the front cover 120, respectively.

In the outer casing 110 is provided with a blowing fan 114 for guiding the air sucked into the outer casing 110 through the suction port 121 to the upper side.

An upper side of the blower fan 114 is provided with a heat exchanger 112 for contacting and heat-exchanging the air floating upward through the blower fan 114.

A drain pan 130 is provided below the heat exchanger 112 to collect drain water generated during heat exchange of air.

As shown in FIG. 2 and FIG. 3, the drain pan 130 includes a support part 131 that receives drain water generated during heat exchange, and a drain water provided at a lower part of the support part 131. It has a discharge part 132 for discharging the discharge portion, and a flow path guide 133 formed on the side of the support 131.

However, in the conventional air conditioner having the structure of the drain pan 130, when the thickness (L) of the outer casing 110 is made small in order to manufacture the air conditioner compactly, the heat exchanger 112 is relatively In this case, air from the blower fan 114 is not evenly distributed throughout the heat exchanger 112 due to the flow guide 133 formed in the drain pan 130.

In particular, there is a disadvantage that the heat exchange is not performed in this region because air is not delivered to the lower end region of the heat exchanger 112 (see arrows in the outer casing 110 of FIG. 1).

The present invention has been made to solve the above problems, an object of the present invention is to form a small thickness of the outer casing to make the air conditioner compact, even if the heat exchanger is arranged so that the inclination angle is relatively large from the blower fan The present invention provides a drain fan structure for an air conditioner, in which air is evenly distributed throughout the heat exchanger to increase heat exchange efficiency.

The present invention for achieving the above object is a drain fan provided in the air conditioner having a blower fan provided in the outer casing and a heat exchanger disposed inclined to the upper portion of the blower fan to heat exchange the air, drain water generated during heat exchange Receiving part receiving; A discharge part provided below the support part to discharge drain water collected in the support part; It is achieved by providing a drain fan structure for an air conditioner including a flow path guide for uniformly distributing air discharged from the discharge end of the blowing fan throughout the heat exchanger.

Here, the flow guide is advantageously of a duct shape so that the air discharged from the discharge end of the blowing fan is guided to the lower end region of the heat exchanger.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

4 is an internal side view of an air conditioner equipped with a drain pan according to the present invention. As shown in this figure, the air conditioner according to the present invention is coupled to the front surface of the outer casing 10 and the outer casing 10, which is equipped with a predetermined component part therein and is opened in front of the air conditioner. It has a front cover 20 forming a front surface.

In the lower region of the front cover 20, a suction port 21 for sucking air in the room is formed.

In the upper region of the front cover 20 facing the suction port 21, a discharge port 22 through which air (cool air) heat exchanged by the heat exchanger 12 to be described later is formed.

A filter 23 is mounted on an inner surface of the inlet 21 to filter the air sucked into the outer casing 10.

An operation panel is provided between the suction port 21 and the discharge port 22 to operate and stop the air conditioner, and to control the strength and blowing direction of the heat-exchanged air, the operation of the discharge port shutter (not shown), and the like.

In the outer casing 10, a blowing fan 14 for discharging upwardly hot air of the room sucked into the outer casing 10 through the suction port 21 to the heat exchanger 12 is provided.

The blower fan 14 is employed as a cross-flow fan rather than an axial fan that is employed as a normal fan, and is mounted in a predetermined fan casing 15.

An upper side of the blower fan 14 is provided with a heat exchanger 12 for directly exchanging heat by directly contacting the air floating upward through the blower fan 14.

The heat exchanger 12 is composed of a plurality of fins formed at a predetermined pitch interval along the transverse direction in the supply direction of air guided from the blower fan 14 and tubes connecting the fins to form cold air.

As shown, the heat exchanger 12 is inclined obliquely to increase the contact area with air.

Of course, for the cooling function of the air conditioner, in addition to the heat exchanger 12 and the blower fan 14, many separate parts or configurations are required but omitted.

The lower part of the heat exchanger 12 is provided with a drain pan 30, which serves to collect the drain water generated during heat exchange of air.

The drain pan 30 partially accommodates the lower end of the heat exchanger 12 but receives the drain water generated during the heat exchange, and is provided at the lower part of the support part 31 to be collected at the support part 31. A discharge part 32 which discharges drain water, and the flow path guide 33 are provided.

The flow guide 33 according to the present invention has a duct shape so that the air discharged from the discharge end of the blower fan 14 can be uniformly distributed throughout the heat exchanger (12).

In particular, the air discharged from the discharge end of the blower fan 14 has a duct shape to be directed to the lower end region of the heat exchanger (12).

That is, when forming the thickness (L) of the outer casing 10 to make the air conditioner compact, the heat exchanger 12 should be arranged so that the inclination angle is relatively large.

However, even in such a case, in the present invention, the blower fan 14 has a duct shape through structural improvement and the flow path guide 33 takes the structure of the drain pan 30 attached to the left and right plates at the lower end of the heat exchanger 12. Air from is evenly distributed throughout the heat exchanger 12.

In particular, air is also supplied to the lower end region of the heat exchanger 12 to exchange heat.

Therefore, the heat exchange efficiency can be increased (see the arrow in the outer casing 10 of FIG. 4).

With this configuration, when the cooling function is selected through the corresponding button on the operation panel, the blower fan 14 is operated so that indoor air flows into the outer casing 10 through the inlet 21.

Then, it is directed to the heat exchanger 12 through the blower fan 14. At this time, a part of the air discharged from the blower fan 14 is introduced into the lower end region of the heat exchanger 12 by the flow path guide 33 having a duct shape, the remaining discharged air is the duct-shaped flow path guide 33 As it flows into the upper end region of the heat exchanger through the outer circumferential surface of), it can be evenly distributed throughout the heat exchanger (12).

When the air is introduced into the heat exchanger 12, the introduced air is formed as cold in the heat exchanger 12, and then discharged back into the room through the discharge port 22 by the blowing force of the blower fan 14. As a result, the indoor air can be kept cold.

As described above, according to the present invention, in order to manufacture the air conditioner compactly, the thickness L of the outer casing 10 is made small so that even if the heat exchanger 12 is arranged to have a relatively inclined angle from the blower fan 14. Air is evenly distributed throughout the heat exchanger 12 to increase the heat exchange efficiency.

Although the present invention has been described in detail with reference to the drawings, the present invention is not limited thereto.

As described above, according to the present invention, even if the thickness of the outer casing is made small so that the heat exchanger is relatively inclined in order to manufacture the air conditioner compactly, the air from the blower fan is uniformly distributed throughout the heat exchanger, thereby exchanging heat exchange efficiency. This has the effect of being higher.

Claims (2)

delete A blower fan provided in the outer casing, a heat exchanger disposed at an upper portion of the blower fan to be inclined to heat exchange air, a support part receiving drain water generated during heat exchange, and a drain water provided at the lower part of the support part In the drain fan structure for an air conditioner comprising a discharge part for discharging, and a flow path guide for uniformly distributing air discharged from the discharging end of the blowing fan throughout the heat exchanger, The flow guide has a duct shape so that air discharged from the discharge end of the blower fan is guided to the lower end region of the heat exchanger, and is attached to the left and right plates of the heat exchanger, and the drain fan structure for an air conditioner is used.

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