KR101534170B1 - Dehumidifier - Google Patents

Abstract

The dehumidifier of the present invention is a dehumidifier having a dehumidifying passage through which the room air is sucked and dehumidified, and a regeneration passage through which the regeneration air flows, a condensation heat exchanger for exchanging heat between the room air and the regeneration air, A main drain portion in which condensed water condensed in the condensing heat exchanger is received, and a main drain portion which is located at a rear of the dehumidifying rotor and which sucks indoor air into the main body, And an auxiliary drain portion formed adjacent to the main drain portion to receive the condensed water accommodated in the main drain portion.

Therefore, when the condensed water is received in the main drain portion, there is an effect of preventing the condensed water from flowing out into the dehumidifier due to the auxiliary drain portion capable of receiving the condensed water overflowed from the main drain portion.

Dehumidifier, main drain, auxiliary drain, drain pan, bucket

Description

Dehumidifier {Dehumidifier}

The present invention relates to a dehumidifier, and more particularly, to a dehumidifier for preventing condensed water from overflowing from the main drain to other components in the dehumidifier by placing an auxiliary drain pan on one side of a main drain portion accommodating condensed condensed water in a condensing heat exchanger will be.

In general, the dehumidifier can be divided into a dehumidifier using a cooling cycle and a dehumidifier using a desiccant rotor depending on the operation mode.

In the case of a dehumidifier using a cooling cycle, there is a problem that a compressor is required, a noise of the compressor and a space in which the compressor is located are required. In recent years, a dehumidifier using a desiccant rotor has been widely used.

The desiccant rotor has a property of adsorbing moisture in the air, so that it is dehumidified while passing room air through a desiccant rotor, and the desiccant in which moisture is adsorbed is regenerated by using hot air.

Here, the air regenerated by the desiccant rotor becomes hot and humid, and the hot and humid air is discharged to the outside. However, when the high-temperature and high-humidity air is discharged to the outside, there is a problem that the dehumidifier must be located on the outer surface of the building or a separate exhaust duct must be provided in the room.

Therefore, when hot and humid air regenerated from desiccant is circulated in the dehumidifier, it is not necessary to provide a separate exhaust duct. In addition, the position of the dehumidifier can be placed at a desired position.

In order to circulate the high temperature and high humidity air, it is necessary to remove the moisture of the high temperature and high humidity air. Therefore, generally, the space between the indoor air inlet and the decanter rotor is subjected to condensation heat exchange . That is, the humidity is lowered by the heat exchange of the high temperature and high humidity air with the room temperature air to condense the moisture inside the high temperature and high humidity air.

And a drain pan for receiving condensed condensed water in the condensing heat exchanger is positioned below the condensation heat exchanger for exchanging heat between the high temperature and high humidity air and the room temperature air. The drain pan is formed with a drain hole through which condensed water is discharged downward.

However, in the conventional drain fan, when the drain hole is clogged by foreign substances or the like, there is a problem that the drain pan is filled with condensed water and overflowed, and other components are damaged by moisture.

SUMMARY OF THE INVENTION An object of the present invention is to provide a dehumidifier having an auxiliary drain pan for receiving condensed water accommodated in a main drain portion.

Another object of the present invention is to provide a dehumidifier in which a drain hole is formed in an auxiliary drain pan so that the condensed water can be discharged to a bucket under the drain pan.

According to an aspect of the present invention, there is provided a dehumidifier comprising: a main body having a dehumidification passage through which room air is sucked and dehumidified and a regeneration passage through which regeneration air flows; A condensing heat exchanger for exchanging heat between the indoor air and the regeneration air; A dehumidification rotor that is dehumidified while passing room air passing through the condensation heat exchanger, and is regenerated while the regeneration air passes; A blower which is located behind the dehumidifying rotor and sucks indoor air into the main body; And a drain pan for receiving the condensed condensed water in the condensation heat exchanger, wherein the drain pan includes a main drain portion in which condensed condensed water is accommodated in the condensation heat exchanger; An auxiliary drain portion for receiving the condensed water accommodated in the main drain portion; And a flow portion formed between the main drain portion and the auxiliary drain portion and allowing the condensed water accommodated in the main drain portion to flow over the auxiliary drain portion.

A partition wall separating the main drain portion and the auxiliary drain portion is formed, and the flow portion is formed in the partition wall.

The flow portion may be recessed from the upper surface of the partition wall. The auxiliary drain portion is formed with a discharge hole through which condensed water is discharged downward.

Meanwhile, the drain pan is formed with a blower mounting portion in which the blower is located, and a discharge hole through which moisture in the inside of the main body is discharged is formed on a lower surface of the blower mounting portion. Further, the drain pan is formed with a dehumidification rotor accommodating portion to which the dehumidification rotor is mounted, and a discharge hole through which the moisture inside the main body is discharged is formed on a lower surface of the dehumidification rotor accommodating portion.

The dehumidifier according to the present invention having the above-described configuration has the following effects.

First, a main drain portion and an auxiliary drain portion that accommodate the condensed water discharged from the condensation heat exchanger are provided. Therefore, it is possible to prevent other parts inside the dehumidifier from being damaged by the condensed water accommodated in the main drain portion.

Second, a discharge hole may be formed in the auxiliary drain portion to discharge the condensed water received in the auxiliary drain portion to the bucket under the drain pan. Therefore, it is possible to prevent damage to other parts inside the dehumidifier due to the condensed water accommodated in the auxiliary drain pan.

Thirdly, a drain hole is formed in the blower mounting portion and the dehumidifying rotor receiving portion of the drain pan, respectively, so that the moisture inside the dehumidifier can be discharged to the bucket below the drain pan. Therefore, residual moisture inside the dehumidifier accommodated in the drain pan can be removed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the embodiments, the same names and the same reference numerals are used for the same components, and further description thereof will be omitted.

FIG. 1 is a perspective view of a dehumidifier according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of a main part of the dehumidifier of FIG. 1.

1 and 2, the overall structure of the dehumidifier according to the present embodiment will be described.

The dehumidifier according to the present invention sucks indoor air to absorb moisture, and then discharges the dehumidified indoor air. Accordingly, the main body 2 is formed with the air suction portion in which the air is sucked and the air discharging portion in which the sucked indoor air is dehumidified and discharged. In the present embodiment, the air suction portion is located on the side surface of the main body 2 and is located on the upper surface of the air discharge portion.

The front panel 8, the front face of the bucket 10, the left and right panels 4 and 5, the upper panel 3, the base 8, the rear upper panel 7 and the rear lower panel 6, Thereby forming an appearance.

The front panel 8 forms the appearance of the upper front of the main body. A groove is formed in the rear surface of the front panel 8 so that the filter can be slidably mounted thereon, and a filter capable of purifying indoor air introduced through the air suction portion is mounted.

The left and right panels (4,5) form side surfaces of the main body, and a handle is provided so that the user can manually move the dehumidifier. In the lower part of the side panels 4 and 5, a hole is formed at a position where the bucket 10 is to be described, so that a separate hose capable of discharging the water contained in the bucket 10 to the outside can be connected.

The upper panel 3 forms an upper portion of the main body, and a display portion and an operating portion capable of confirming the operation state of the air discharge portion and the user of the dehumidifier and inputting the operation of the dehumidifier are located.

The rear panels (6, 7) form the rear of the main body. In particular, the lower rear panel 6 is detachably coupled to the main body, and a power cord fixing unit (not shown) is provided inside the lower rear panel 6 to fix the power cord for supplying power to the main body.

The base 8 forms a bottom surface of the main body and is provided with a wheel assembly including a wheel and a wheel support on which the wheel is rotatably supported to assist the movement of the dehumidifier. The base 8 is opened on the upper surface, and the drain pan 20 is located on the opened upper surface. A bucket 10 is slidably and detachably coupled to the inside of the base 8.

3 is a perspective view of a drain pan of an embodiment of the present invention.

Referring to FIG. 3, the drain pan 20 forms the upper surface of the base 8. The condensing heat exchanger 100, the rotor frame 43, the blower 9, and the like are mounted on the upper portion. And serves to receive condensate discharged from the condensing heat exchanger 100. That is, the drain pan 20 includes a main drain portion 23 for receiving the condensed water discharged from the condensing heat exchanger 100 and an auxiliary drain portion 24 for receiving condensed water accommodated in the main drain portion 23.

The main drain portion 23 is formed by a pair of partition walls 25 and 26 for partitioning the drain pan 20. Therefore, the condensed water is accommodated in the space formed by the partition walls 25 and 26. In the space between the partition walls 25 and 26, the condensation heat exchanger 100 is located, and the space between the partition walls 25 and 26 is formed at an interval at which the condensation heat exchanger 100 can be accommodated.

The main drain 23 is formed with a discharge hole 23a through which condensed water is discharged. The bottom surface of the main drain part 23 may be formed to be inclined upward with respect to the discharge hole 23a. Accordingly, the condensed water discharged from the condensing heat exchanger 100 flows into the discharge hole 23a along the inclined direction.

The auxiliary drain portion (24) receives condensed water accommodated in the main drain portion (23). Specifically, when the amount of the condensed water received in the main drain 23 is larger than the amount of condensed water discharged from the main drain 23 through the discharge hole 23a, the discharge hole 23a formed in the main drain 23 The condensed water can be accommodated in the main drain portion 23.

Accordingly, when the condensed water accommodated in the auxiliary drain portion 24 is accommodated, it is possible to prevent the condensed water accommodated in the main drain portion 23 from being discharged to the other portion of the dehumidifier, not the bucket 10. [

The auxiliary drain portion 24 is located adjacent to the main drain portion 23. That is, adjacent to at least one of the pair of partition walls forming the main drain portion 23. [ In this embodiment, the auxiliary drain portion 24 is located adjacent to the partition wall 25 located on the front surface of the main drain portion 23. Therefore, the size of the dehumidifier main body 2 can be reduced.

Therefore, the partition wall 25 in this embodiment divides the main drain portion 23 and the auxiliary drain portion 24. Therefore, the condensed water which has not been accommodated is not introduced into the auxiliary drain portion 24 by the partition wall 25.

On the other hand, in the partition wall 25, a floating portion 25a is formed in which condensed water can flow to the auxiliary drain pan 24 when condensed water having a predetermined height or more is accommodated in the main drain portion 23. The flow portion 25a may be formed in a position of a predetermined height or more in the partition wall 25 and may have a hole shape to flow condensed water to the auxiliary drain portion 24 when condensed water is accumulated over the height. However, the moving portion 25a in this embodiment is formed by recessing a part of the partition wall 25. [ Therefore, when the condensed water accumulates at a height equal to or higher than the height of the partially recessed floating portion 25a of the partition wall 25, the condensed water flows into the auxiliary drain portion 24.

On the other hand, the auxiliary drain portion 24 is formed with a discharge hole 24a. Accordingly, the condensed water accommodated in the auxiliary drain portion 24 is discharged to the lower portion. And the discharged condensed water is received in the bucket 10. The condensed water accommodated in the main drain portion 23 is temporarily received in the auxiliary drain portion 24 and flows to the bucket 10 through the discharge hole 24a. The bottom surface of the auxiliary drain portion 24 is formed to be upward inclined with respect to the discharge hole 24a to guide the condensed water to the discharge hole 24a.

The drain pan 20 is formed with a blower mounting portion 21 in which a blower 9 to be described later is mounted and a dehumidifying rotor accommodating portion 22 in which a dehumidifying rotor 30 is mounted.

The dehumidifying rotor accommodating portion 22 is located adjacent to the rear partition wall 26 of the pair of partition walls of the main drain portion 23. [ Therefore, the partition wall 26 separates the main drain portion 23 and the dehumidifying-rotor accommodating portion 22 from each other. The partition wall 26 is formed with a flow portion 26a which functions as the flow portion 25a of the partition wall 25 provided at the front side described above.

On the other hand, the dehumidification rotor 30 itself may be located in the dehumidification rotor mounting portion 22. However, in the present embodiment, the dehumidification rotor 30 is fixed to the rotor frame 43, and the rotor frame 43 is located in the dehumidification rotor mounting portion 22. [

In the dehumidification rotor accommodating portion 22, a discharge hole 22a for discharging the moisture inside the dehumidifier main body 2 to the bucket 10 is formed. Therefore, when the moisture generated in the process of dehumidifying while the indoor air flows is received in the dehumidification rotor accommodating portion 22, it is guided to the bucket 10 through the exhaust hole 22a. The condensed water which is accommodated in the main drain 23 and flows into the dehumidifying rotor accommodating portion 22 through the flow portion 26a is also guided to the bucket through the discharge hole 22a. The bottom surface of the dehumidification rotor accommodating portion 22 may also be inclined upward with respect to the discharge hole 22a.

The blower mounting portion 21 is formed to be recessed behind the drain pan. And the blower 9 is positioned at the depressed portion. A discharge hole 21a for discharging the moisture inside the dehumidifier main body 2 to the bucket 10 is formed on the lower surface of the blower mounting portion 21. [ Therefore, the moisture which is generated in the process of dehumidifying the room air and led to the blower mounting portion 21 is discharged to the bucket 10 through the discharge hole 21a. The lower surface of the blower mounting portion 21 may be formed with an upward inclination with respect to the discharge hole 21a.

4 is a perspective view of a bucket 10 of an embodiment of the present invention.

Referring to FIG. 4, the bucket 10 forms a space for receiving the condensed water flowing through the drain pan 14. When the condensed water is slidably coupled to the base 8 and the condensed water is accommodated to some extent, the user separates the bucket 10 from the base 8 to discharge the condensed water to the outside.

The bucket (10) includes an upper plate portion (11) sealing the upper surface.

An inlet 13 is formed in the upper plate 11 to allow the condensed water discharged from the plurality of discharge holes 21a, 22a, 23a and 24a described above to flow into the bucket 10. The upper plate 11 is formed with an upward slope with respect to the inlet 13. Accordingly, the condensed water and the moisture that have fallen to the upper plate 11 flow into the inlet 13 along the inclined direction. Meanwhile, a handle may be formed on the inflow portion so that the user can move the bucket 10.

The upper plate 13 is formed with a condensed water receiving groove 12 for guiding the condensed water discharged from the discharge hole 23a of the main drain 23 into the bucket 10. The condensed water discharged from the discharge hole 23a of the main drain 23 is guided into the bucket 10 through the discharge hole 12a formed in the receiving groove 12 through the receiving groove. Therefore, the condensed water condensed in the condensation heat exchanger 100 can be directly received in the bucket 10 without flowing through the top plate 11. [

Although not shown, the receiving groove 12 and the discharge hole 12a are formed in the respective discharge holes (not shown) so as to receive condensed water and moisture discharged from the other discharge holes 21a, 22a, and 24a formed in the drain pan 20 21a, 22a, 24a.

A blower 20, a dehumidification rotor 30, a regeneration fan 50, a regeneration air heating member 60 and a condensing heat exchanger 100 are provided in the body.

The blower 9 is a kind of dehumidification fan that sucks indoor air through the air suction unit and then discharges the air to the air discharge unit after passing through the main body. The rear fan unit 9 is connected to the rear upper panel 7, A hole is formed and an outlet portion is formed at an upper portion thereof. And a fan connected to the rotation shaft of the fan motor and the fan motor, and a discharge grill can be installed in the discharge part. The lower surface of the blower 9 is located in the blower mounting portion 21 described above.

The dehumidification rotor 30 is installed between the blower 9 and the condensing heat exchanger 100 so that moisture in the room air sucked by the blower 9 is adsorbed and regenerated at a low temperature.

The desiccant rotor 30 surrounds the desiccant 35 and the desiccant 35 is fixed to the desiccant 35. The desiccant 35 is fixed to the outer circumferential surface of the desiccant 35, ).

The desiccant 35 is formed into a disc shape as a whole, and is formed with a fixing hole for fixation at the center.

Desiccants of various shapes and materials may be used as the desiccant, but the desiccant 35 in this embodiment is a shape that alternately turns the ceramic fiber-like flat paper and the corrugated paper into a cylindrical shape. Meso-Silica (SiO2) is a well-developed nano-carbon ball (NCB) that has excellent moisture absorption and surface area and can be regenerated even at a low temperature of about 60 ° C or less.

The nano-carbon ball (NCB) is a spherical carbon structure having a spherical hollow core portion and a mesoporous carbon cell portion and having a diameter of 200 nm to 500 nm, and has pores of 2 nm to 50 nm, and has surface area BET and Mesopore Because of the large area, there is no pore clogging.

On the other hand, the desiccant 35 is disposed in a region (hereinafter referred to as a 'dehumidifying region') where moisture is adsorbed while passing room air and a region where moisture is evaporated . As the desiccant 35 rotates, the respective regions are alternately changed to adsorb / evaporate the moisture.

The regeneration area is generally formed in a fan shape. And the regeneration region can be partitioned to face the regeneration air heating member 60 to be described later.

The desiccant wheel 33 is formed in a ring shape and has a rim portion surrounding the desiccant 35, a fixing portion to which the desiccant 35 is fixed, a rim portion to connect the rim portion and the fixing portion, And a radially formed connection portion.

A rotor supporter 41 for rotatably supporting the dehumidification rotor 30 and a rotor frame 43 for mounting the rotor supporter 41 are disposed inside the main body.

A regenerating air distributing member 90, which will be described later, is coupled to the front surface of the rotor supporter 41. The rear surface of the reconditioning air distributing member 90 is opened to form a suction portion 92 into which the reconditioning air is introduced into the reconditioning air distributing member 90 while being engaged with the rotor supporter 41.

The rotor frame 43 serves as a sort of barrier that divides the inside of the main body into a space on the rear side where the blower 20 is disposed and a space on the front side on which the condensing heat exchanger 100 is disposed. In this embodiment, the rotor frame 43 is located in the dehumidification rotor accommodating portion 22 as described above. However, the dehumidification rotor 30 may be directly disposed in the dehumidification rotor accommodation portion 22 without a rotor supporter.

The front surface of the rotor frame 43 is formed with an opening so that the room air and the regeneration air passing through the desiccant 35 pass through. An opening through which the reconditioning air passed through the exhaust duct 80 to be described later passes is formed.

The upper portion of the rotor frame 43 is provided with a control box mounting portion on which a control box 22 for controlling the dehumidifier is mounted.

The regeneration fan 50 imparts a circulation force so that the regeneration air can flow while circulating in the main body. That is, the regeneration fan 50 sucks the air that has passed through the exhaust duct 80 and discharges it to the regeneration air heating member 60.

The regeneration air heating member 60 heats the regeneration air discharged from the regeneration fan 90 to supply the regeneration air of high temperature to the dehumidification rotor 30. The reconditioning air heating member 60 includes a first heater cover 65 which communicates with the regenerating fan 50 while covering the heater 63 and the heater 63 and a second heater cover 65 which is in communication with the first heater cover 65 and the dehumidifying rotor 30 And a second heater cover 61 coupled to the first heater cover 102.

The second heater cover 61 serves as a kind of air guide which prevents the air heated by the heater 63 from moving toward the dehumidification rotor 30 between the heater 63 and the dehumidification rotor 30 do.

On the other hand, the reconditioning air heated while passing through the reconditioning air heating member 60 flows into the reconditioning air distributing member 90 which has passed through the reconditioning area of the desiccant 30.

The regeneration air distributing member (90) is located between the regeneration zone and the condensing heat exchanger (100). Therefore, the regeneration air discharged from the regeneration zone enters the regeneration air distributing member 90 and is distributed to the condensing heat exchanger 100 to be introduced.

The condensing heat exchanger (100) exchanges the regeneration air via the regeneration air distributing member (90) with the room air. That is, the regeneration air that has adsorbed moisture while passing through the regeneration region of the dehumidification rotor 30 is condensed by using indoor air, and the regeneration air from which moisture is removed is discharged to the regeneration fan 50 side through the exhaust duct 80. The condensed water is discharged to the discharge hole 23a through the main drain 23.

Meanwhile, the condensation heat exchanger 100 in this embodiment is formed of a plurality of heat exchange plates to maximize the heat exchange area between the regeneration air and the room air.

The regeneration air having passed through the condensation heat exchanger 100 and having the moisture removed is sucked into the regeneration fan 50 through the exhaust duct 90 formed in communication with the condensation heat exchanger.

The condensation process of the regeneration air of the dehumidifier of the present invention, the dehumidification process of the indoor air, and the process of discharging the condensed water and the water in the main unit 2 will be described below.

First, the regeneration air circulates through the regeneration flow path by rotation of the regeneration fan 50. [ That is, the regeneration air that has passed through the regeneration fan 50 is heated by the regeneration air heating member 60 and the temperature rises. The high-temperature regeneration air regenerates the regeneration region of the dehumidification rotor 30 and flows into the condensing heat exchanger 100 via the regeneration air distributing member 90

The reconditioning air introduced into the condensing heat exchanger 100 exchanges heat with indoor air while flowing from the upper portion to the lower portion of the plurality of heat exchanging plates. The moisture in the regeneration air condenses in the heat exchange process. The condensed reclaimed air flows into the regeneration fan 50 through the exhaust duct 90 through the opening of the rotor frame 43. That is, the regeneration air circulates in the main body along the above cycle.

On the other hand, the indoor air is sucked through the air suction portion of the main body and performs heat exchange with the reconditioning air flowing through the reconditioning air passage while passing through the indoor air passage of the condensing heat exchanger 100. The room air passing through the condensation heat exchanger (100) passes through the dehumidifying region of the desiccant (35) and moisture is adsorbed and dehumidified. The indoor air to which the moisture is adsorbed passes through the blowing fan 9 and is discharged to the room through the air discharge portion of the main body.

Condensed water condensed in the condensing heat exchanger 100 is received in the bucket 10 through the main drain 23, the discharge hole 23a, the condensate receiving groove 12 and the discharge hole 12a. A part of the condensed water accommodated in the main drain part 23 passes through the auxiliary drain part 24, the discharge hole 24a, and the drain part 24 via the fluid part 25a formed in the front partition wall 25 of the main drain part 23, And is accommodated in the bucket 10 via the upper plate 11 and the inlet 13 of the bucket 10. The remaining condensed water to be accommodated is introduced into the bucket (not shown) through the rear side fluid portion 26a, the dehumidifying rotor accommodating portion 22, the discharge hole 22a, the upper plate portion 11 and the inflow portion 13 of the main drain portion 23 10).

The condensed water and the moisture introduced to the blower mounting portion 21 are introduced into the bucket 10 through the discharge hole 21a formed in the blower mounting portion, the top plate 11 and the inlet 13.

As a result, condensate and moisture inside the main body 2 are accommodated in the bucket 10. The user then removes the bucket 10 from the base 8 and drains the condensate and moisture to the outside of the product.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

1 is a perspective view of a dehumidifier according to an embodiment of the present invention;

FIG. 2 is an exploded perspective view of a main portion of the dehumidifier of FIG. 1; FIG.

FIG. 3 is a perspective view of a drain pan of an embodiment of the present invention; FIG.

4 is a perspective view of a bucket of an embodiment of the present invention;

Description of the Related Art

1: Main body 2: Front panel

3: Top panel 4,5: Left and right panel

6,7: Lower panel 8: Base

10: bucket 11: upper plate

12: Condensate receiving groove 12a: Discharge hole

13: inlet 20: drain pan

21: air blowing fan mounting portion 22: dehumidification rotor accommodating portion

23: main drain portion 24: auxiliary drain portion

25: front compartment wall 26: rear compartment wall

21a, 22a, 23a, 24a: discharge holes 25a, 26a:

41: Rotor supporter 43: Rotor frame

50: regeneration fan 60: regeneration air distribution member

80: exhaust duct 90: regeneration air distribution member

100: condensing heat exchanger

Claims (6)

A dehumidification passage through which the room air is sucked and dehumidified, and a regeneration passage through which the regeneration air flows; A condensing heat exchanger for exchanging heat between the indoor air and the regeneration air; A dehumidification rotor that is dehumidified while passing room air passing through the condensation heat exchanger, and is regenerated while the regeneration air passes; A blower which is located behind the dehumidifying rotor and sucks indoor air into the main body; And And a drain pan for receiving the condensed condensed water in the condensation heat exchanger, The drain pan A main drain portion in which condensed condensed water is accommodated in the condensation heat exchanger; An auxiliary drain portion for receiving the condensed water accommodated in the main drain portion; And a flow portion formed between the main drain portion and the auxiliary drain portion and flowing the condensed water accommodated in the main drain portion to the auxiliary drain portion. The method according to claim 1, A partition wall for partitioning the main drain portion and the auxiliary drain portion is formed, and the flow portion is formed in the partition wall. The method of claim 2, Wherein the flow portion is formed as a groove or a hole formed in the partition wall. The method according to claim 1, Wherein the auxiliary drain portion includes a discharge hole through which condensed water is discharged downward. The method according to claim 1, Wherein the drain pan is formed with a blower mounting portion in which the blower is located, And a discharge hole through which water in the main body is discharged is formed on a lower surface of the blower mounting portion. The method according to claim 1, Wherein the drain pan is formed with a dehumidification rotor accommodating portion to which the dehumidification rotor is mounted, And a discharge hole through which moisture is discharged from the inside of the main body is formed on a lower surface of the dehumidifying rotor accommodating portion.

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