KR20210020445A - Clothes treating apparatus - Google Patents

Abstract

The present invention is to optimize a structure of a water cover so that condensed water generated from air discharged from a drum does not accumulate on an upper surface of the water cover. The present invention provides a clothing treatment apparatus, which comprises: a drum for housing clothing; an evaporator located outside the drum; a water cover positioned below the evaporator to support the evaporator; and a circulation passage forming a path through which the air discharged from the drum moves from one side of the evaporator toward the other side opposite to the one side. The water cover includes: an opening portion formed through the water cover in a vertical direction; and an inclined portion formed around the opening portion and inclined downward toward the downstream side of the circulation passage.

Description

Clothing processing device {CLOTHES TREATING APPARATUS}

The present invention relates to a clothes treatment apparatus having a function of drying clothes or bedding, and more particularly, to a clothes treatment apparatus including a water cover having an inclined surface.

The clothes handling device refers to all devices that manage or process clothes, such as washing, drying, or removing wrinkles from clothes or bedding in a home or in a laundry. Clothes handling apparatuses include washing machines, dryers, washing machines and dryers.

A washing machine is a device for washing clothes or bedding, and a dryer is a device for removing moisture from clothes or bedding and drying it. A washing machine and dryer is a device that has both a washing function and a drying function.

Among these, the dryer in particular supplies hot air to the object to be treated, such as clothes or bedding, which is put into the drum (or tub) to evaporate moisture contained in the object to be treated. The moisture of the object to be treated evaporates from the drum, and the air exiting the drum retains the moisture of the object to be treated, resulting in a high temperature and high humidity state. At this time, the type of dryer is classified into a condensing type and an exhaust type according to the method of treating the high-temperature and humid air.

The condensing dryer does not discharge hot and humid air to the outside, but condenses moisture contained in the hot and humid air through heat exchange while circulating. In contrast, the exhaust type dryer directly discharges hot and humid air to the outside. The condensed dryer has a structure for treating condensed water, and the exhaust dryer has a structure for exhausting air.

The condensing dryer has a circulation passage that removes moisture from the air discharged from the drum and heats it to flow into the drum. The air discharged from the drum passes through the evaporator and condenser. The air discharged from the drum is high-temperature and humid air, and the temperature decreases as it passes through the evaporator to discharge moisture, and the dry air that has passed through the evaporator is heated again while passing through the condenser and flows into the drum.

At this time, the evaporator and the condenser are supported by the water cover, and the moisture discharged from the evaporator is discharged downward along the drain hole formed in the surface where the evaporator and the water cover contact each other. The water cover of a conventional clothing treatment apparatus is configured in such a manner that the flat surface of the water cover supports the evaporator, and a plurality of holes for drainage are formed on the surface, and the condensate water generated by the evaporator is drained through the hole. . In this case, the condensed water accumulates on the flat surface around the hole, and as the accumulated condensate dries, lint contained in the condensed water accumulates in the water cover. This may impart a perception that when the user partially disassembles the clothing treatment device and checks the state of the water cover, it is not good in terms of aesthetics, and that the sanitary state of the clothing treatment device is not good.

In order to solve this problem, it is necessary to minimize the side where condensate may accumulate in the water cover, and for this purpose, it is necessary to adopt a slope structure capable of effectively draining the condensed water without accumulating on the surface of the water cover in contact with the evaporator.

In addition, the high-temperature and humid air is discharged from the drum, passed through the evaporator, passed through the condenser, and circulated back to the drum, and it is necessary to appropriately form the inclined structure in consideration of the flow direction of air.

On the other hand, in order to minimize the accumulation of condensed water between the water cover and the evaporator, it is necessary to minimize the area in contact with the water cover and the evaporator. To this end, it is necessary to form the water cover and the evaporator in line contact.

An object of the present invention is to optimize the structure of the water cover so that condensed water generated from air discharged from the drum does not accumulate on the upper surface of the water cover.

In addition, an object of the present invention is to smoothly drain the condensed water flowing into the upper surface of the water cover by employing an opening and an inclined structure in the water cover.

In addition, an object of the present invention is to smoothly drain the condensed water introduced to the upper surface of the water cover by setting the inclined direction of the inclined structure to be inclined downward toward the flow direction of air.

In addition, an object of the present invention is to form a curved surface curved toward the downstream side on the downstream side of the upper surface of the evaporator seating unit based on the direction in which air is moved in the base flow path, so that condensed water is smoothly drained along the curved surface. have.

In addition, while providing a space in which the evaporator and condenser are settled apart from the bottom surface, it is provided to provide a water cover of a structure that restricts the condensed water from the bottom surface of the circulation passage from scattering backward by the suction power of the circulation fan. have.

A clothing treatment apparatus for achieving the object of the present invention includes: a drum for receiving clothing; An evaporator located outside the drum; A water cover located below the evaporator and supporting the evaporator; And a circulation passage forming a path through which the air discharged from the drum moves from one side of the evaporator to the other side opposite to the one side, wherein the water cover is formed through the water cover in the vertical direction. Opening; And an inclined portion formed around the opening and inclined downward toward the downstream side of the circulation passage.

The opening may include an upper opening through which condensed water formed from the air is introduced; And

A lower opening through which the introduced condensate water is discharged may be provided, and a center of the lower opening may be eccentric by a predetermined distance from the center of the upper opening toward a downstream side of the circulation passage.

The inclined portion includes a first inclined portion and a second inclined portion sequentially positioned toward a downstream side of the circulation passage, and the first inclined portion may be inclined more gently than the second inclined portion.

The water cover includes a first region, a second region, and a third region sequentially positioned along a direction crossing a direction in which the air moves, and the openings are formed in plurality, and the plurality of openings are A peripheral inclined portion may be formed in the second region and inclined upward toward the second region in the first region and the third region.

The evaporator may be supported in line contact with the circumferences of the plurality of upper openings.

A plurality of the openings are sequentially positioned toward the downstream side based on the direction in which the air moves in the circulation passage, and around the openings located at the downstream side among the plurality of openings, the plurality of openings are sequentially positioned toward the downstream side. A first inclined portion and a second inclined portion may be formed, and a curved surface curved toward a downstream side may be formed at an upper end of the second inclined portion.

In a portion where the first region and the third region are in contact with the second region, a support rib is formed to protrude in a predetermined length along a direction crossing a direction in which the air is moved, and the support rib is formed with a circumference of the upper opening Together can support the evaporator.

The water cover may include an evaporator seating portion supporting the evaporator; A condenser seating portion spaced a predetermined distance from the evaporator seating portion to a downstream side based on a direction in which air is moved in the circulation passage; And a connecting portion connecting the evaporator seating portion and the condenser seating portion, and the connecting portion may be formed in a plate shape having both sides parallel to a direction in which the air is moved.

An upwardly extending rib may protrude along a direction crossing a direction in which the air is moved on a downstream side of the circulation passage of the condenser seating portion.

A drain hole may be formed in the condenser seating portion, and the drain hole may be positioned at a predetermined distance apart from the upwardly extending rib toward a downstream side of the circulation passage.

The clothing treatment apparatus further includes a base cabinet disposed below the drum and providing a heat exchanger receiving unit to which components constituting the flow path and the water cover are mounted, and the condensed water is provided on a bottom surface of the heat exchanger receiving unit. The water collecting part is formed at a position lower than the peripheral area so that the heat exchanger may be formed, and the inner peripheral surface of the heat exchanger receiving part may be formed to be inclined downward toward the water collecting part.

The water cover may include a plurality of support portions extending from the condenser seating portion and the evaporator seating portion toward the inner peripheral surface of the heat exchanger receiving portion.

The evaporator seating portion and the condenser seating portion have a blocking rib protruding downward along a direction crossing the direction in which the air is moved, and a lower end of the blocking rib may be formed to be spaced apart a predetermined distance from the inner peripheral surface of the heat exchanger receiving portion. have.

In addition, a laundry treatment apparatus for achieving the object of the present invention includes: a drum for receiving clothes; An evaporator located outside the drum; A circulation passage defining a path through which the air discharged from the front opening of the drum passes through the evaporator and moves to the rear opening of the drum; A water cover located below the evaporator and supporting the evaporator; And a base cabinet providing a space for accommodating the water cover and components constituting the flow path, wherein the water cover includes: an upper opening through which condensate water generated from the air is introduced; A lower opening through which the introduced condensed water is discharged; And an inclined portion connecting a circumference of the upper opening and a periphery of the lower opening, wherein the inclined portions are sequentially positioned based on a direction in which air is moved in the circulation passage, and first and second inclined downwards. It can have 2 inclined parts.

The first inclined portion may be formed smoother than the second inclined portion.

The effects of the present invention obtained through the above-described solution are as follows.

A plurality of openings are formed in the evaporator seating portion, and the bottom surface of the evaporator is configured to be supported in line contact with the upper circumference of the opening, so that condensed water is not collected on the upper surface of the evaporator seating portion and is drained downward.

In addition, by forming an inclined structure around the opening, condensed water flowing into the upper surface of the water cover can be smoothly drained.

In addition, by setting the inclined direction of the inclined structure to be inclined downward toward the direction in which the air moves, the condensed water flowing into the upper surface of the water cover is smoothly drained.

In addition, by forming the inclined surface facing the direction in which air is moved to be inclined sharply than the inclined surface in the direction in which the air is moved, the condensed water located on the inclined surface is strongly pressed downward by the air colliding with the inclined surface, and the condensed water located on the inclined surface Can be drained smoothly to the lower side.

In addition, by forming a curved surface curved toward the downstream at the downstream end of the upper surface of the evaporator seating unit based on the direction in which the air is moved in the base flow path, condensate water continues with the curved surface to reduce the surface energy. It flows in the direction of contact with, and condensed water can be smoothly drained along the curved surface.

In addition, while providing a space in which the evaporator and condenser are settled apart from the bottom surface, it is provided to provide a water cover of a structure that restricts the condensed water from the bottom surface of the circulation passage from scattering backward by the suction power of the circulation fan. have.

In addition, by forming a blocking rib protruding downward from the bottom surface of the water cover, the flow path through which air flows between the water cover and the bottom surface of the heat exchanger accommodating part is sealed, and most of the air discharged from the front opening of the drum is Can pass. Through this, it is possible to improve the condensation efficiency of air containing moisture.

In addition, a blocking rib protrudes downwards between the evaporator seating portion and the connecting portion, and an upwardly extending rib protrudes upwardly between the connecting portion and the condenser seating portion, so that it is located on the bottom surface of the circulation passage by the suction force of the circulation fan. Condensate can be restricted from scattering backwards

1 is a perspective view illustrating a laundry treatment apparatus according to an embodiment of the present invention.
FIG. 2 is a conceptual diagram illustrating circulation of air through the drum and circulation passage shown in FIG. 1.
3 is a perspective view showing the base cabinet shown in FIG. 1 and main parts mounted on the base cabinet.
4 is an exploded view showing the main components shown in FIG. 3 separated from the base cabinet.
5 is a plan view showing a state in which a water cover is mounted on the base cabinet shown in FIG. 4.
6 is a perspective view of the water cover shown in FIG. 4.
7 is a plan view of the water cover shown in FIG. 6.
8 is a right side view of the water cover shown in FIG. 6.
9 is a front view of the water cover shown in FIG. 6.
10 is a cross-sectional view taken along line AA of FIG. 5.
11 is a cross-sectional view taken along line BB of FIG. 5.

Hereinafter, a laundry treatment apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the present specification, the same or similar reference numerals are assigned to the same or similar configurations even in different embodiments, and redundant descriptions thereof will be omitted.

In the following description, descriptions of some constituent elements may be omitted to clarify features of the present invention.

In addition, a structure applied to one embodiment may be equally applied to another embodiment, as long as different embodiments do not contradict structurally and functionally.

Singular expressions include plural expressions unless the context clearly indicates otherwise.

The accompanying drawings are only for making it easier to understand the embodiments disclosed in the present specification, and the technical idea disclosed in the present specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and scope of the present invention It should be understood to include water or substitutes.

Hereinafter, with reference to FIGS. 1 to 5, the configuration and operation process of the laundry treatment apparatus according to an embodiment of the present invention will be described in detail.

Hereinafter, a water cover according to an embodiment of the present invention will be described in detail with reference to FIGS. 6 to 11.

1 is a perspective view illustrating a laundry treatment apparatus 1000 according to an embodiment of the present invention.

The cabinet 1010 forms the exterior of the laundry treatment apparatus 1000. The cabinet 1010 includes a plurality of sub cabinets constituting at least one of the front, rear, left and right sides, upper and lower surfaces of the laundry treatment apparatus 1000. The sub-cabinet may be composed of a metal plate, and may be composed of a synthetic resin material.

The sub-cabinet forming the base of the laundry treatment apparatus 1000 may be referred to as a base cabinet 1310. The base cabinet 1310 is formed of a synthetic resin material, and various parts are mounted in a space provided therein. The base cabinet 1310 may itself form a bottom surface of the laundry treatment apparatus 1000, and a base plate formed of a metal material may be mounted under the base cabinet 1310 and placed on the floor surface.

A clothing inlet 1011 is formed in the front portion of the cabinet 1010. The clothes inlet 1011 is configured to communicate with an opening on the front side of the drum 1030 so that an object to be treated such as clothes or bedding can be put into the drum 1030.

The door 1020 is formed to close the clothing inlet 1011. The door 1020 may be rotatably connected to the cabinet 1010 by a hinge 1021. The door 1020 may include a light transmitting part. Accordingly, even when the door 1020 is closed, the inside of the drum 1030 may be visually exposed through the light transmitting part.

The drum 1030 is rotatably installed inside the cabinet 1010. The drum 1030 is formed in a cylindrical shape with an empty inside open to the front and the rear, and the front opening 1030' of the drum 1030 communicates with the clothes inlet 1011, so that the object to be treated inside the drum 1030 It is configured to be acceptable.

A circulation passage 1200 is connected to the front opening 1030' and the rear opening 1030' of the drum 1030, so that air is formed by the inside of the drum 1030 and the circulation passage 1200. It is configured to cycle through the loop. The humid air discharged through the front opening 1030 ′ of the drum 1030 passes through the evaporator 1110 on the circulation passage 1200 to remove moisture and is heated through the condenser 1130. The high-temperature dried air is introduced into the drum 1030 through the rear opening 1030 ″ of the drum 1030 to dry the object to be treated.

The drum 1030 is rotatably supported by the front supporter 1040 and the rear supporter 1050. The front supporter 1040 and the rear support 1050 are disposed at the front and rear sides of the drum 1030, respectively, and rotatably support the drum 1030.

Rollers 1060 may be installed on the front supporter 1040 and the rear supporter 1050, respectively. The roller 1060 is disposed immediately below the drum 1030 and contacts the outer circumferential surface of the drum 1030. The roller 1060 is rotatably formed and assists the rotation of the drum 1030 while rotating in a direction opposite to the rotation direction of the drum 1030. The outer peripheral surface of the roller 1060 contacting the outer peripheral surface of the drum 1030 may be formed of an elastic material.

Heat pump cycle devices 1100 are disposed on the lower shaft of the drum 1030. Here, the lower side of the drum 1030 refers to a space between the lower portion of the drum 1030 and the base cabinet 1310. The heat pump cycle devices 1100 refer to devices constituting a cycle of sequentially evaporating-compressing-condensing-expanding the refrigerant. When the heat pump cycle devices 1100 are operated, air is dried at high temperature while sequentially exchanging heat with the evaporator 1110 and the condenser 1130. The evaporator 1110 and the condenser 1130 are used as heat exchangers.

An evaporator 1100 and a condenser 1100 for heat exchange with air flowing along the circulation flow path 1200 are disposed on the circulation passage 1200. In the base cabinet 1310, a base flow path part 1310 ′ forming a part of the circulation flow path 1200 is formed.

A heat exchanger accommodating part 1312 in which an evaporator 1110 for heat exchange and a condenser 1130 are disposed is provided in the base passage part 1310 ′. A guide part 1311 for guiding the inflow of air into the heat exchanger receiving part 1312 is provided in front of the heat exchanger receiving part 1312, and a heat exchanger receiving part 1312 at the rear of the heat exchanger receiving part 1312 A circulation fan accommodating part 1313 is provided in which a circulation fan 1710 that sucks and blows air that has passed through is accommodated. That is, the base flow path part 1310' includes a guide part 1311, a heat exchanger receiving part 1312, and a circulation fan receiving part 1313, which are provided in sequence from the front to the rear.

The evaporator 1110 and the condenser 1130 are disposed to cover a portion of the base passage part 1310 ′ that is opened upward. In addition, after the circulation fan is installed in the circulation fan accommodating portion, the cover member 1330 is disposed to cover a portion opened to the rear of the circulation fan accommodating portion. Through this, a flow path leading from the opening 1311 ′ of the guide part 1311 to the exhaust port 1313 ″ of the circulation fan accommodating part 1313 is completed. Since the flow path connects the outlet duct 1210 and the inlet duct 1220, it may be referred to as a connection duct 1230 (see FIG. 2 ).

The front duct connector 1210 is configured to connect the front opening 1030' of the drum 1030 and the guide portion 1311, and the rear duct connector 1220 is the rear opening 1030" of the drum 1030. And the circulation fan accommodating part 1313. The front duct connector 1210 may be referred to as an outlet duct in that it forms a flow path through which air inside the drum 1030 is discharged. 1220 may be referred to as an inlet duct in that it forms a flow path through which air is introduced into the drum 1030.

Drying the object to be treated inside the drum 1030, and the humidified air is introduced into the heat exchanger accommodating part 1312 through the front duct connector 1220 and the guide part 1311 of the base flow path part 1310'. Moisture is removed from the heat exchanger accommodating part 1312 and the heated air is introduced into the drum 1030 through the rear duct connector 1220 by the circulation fan 1710.

When the air flowing along the circulation passage 1200 exchanges heat with the evaporator 1110, condensed water is generated. More specifically, when the temperature of air is lowered by heat exchange performed in the evaporator 1110, the amount of saturated water vapor that the air can contain decreases. Since the air recovered through the front duct connector 1210 contains moisture exceeding the amount of saturated water vapor, condensed water is inevitably generated.

A water pump 1440 (refer to FIG. 3) is provided inside the laundry treatment apparatus 1000. The water pump 1440 may be installed in the base cabinet 1310. The water pump 1440 moves the condensed water to the water tank 1410, and the condensed water is collected in the water tank 1410.

The water tank 1410 is disposed in the upper left or right upper part of the drum 1030. In other words, the water container 1410 is disposed in the upper left empty space or the upper right empty space between the upper part of the drum 1030 and the cabinet 1010. In FIG. 1, the bucket 1410 is shown to be disposed on the upper left side of the drum 1030.

The water container cover 1420 is disposed at the upper left or upper right of the front part of the laundry treatment apparatus 1000 so as to correspond to the position of the water container 1410. The water container cover 1420 is formed to be grasped by hand, and is exposed to the front surface of the clothing treatment apparatus 1000. When the user pulls the bucket cover 1420 to empty the condensed water collected in the bucket 1410, the bucket 1410 is pulled out from the bucket support frame 1430 together with the bucket cover 1420.

The bucket support frame 1430 is formed to support the bucket 1410 in the cabinet 1010. The bucket support frame 1430 extends along the insertion/retraction direction of the bucket 1410 to guide the insertion and extraction of the bucket 1410.

An input/output panel 1500 is provided on the front or upper surface of the laundry treatment apparatus 1000. In FIG. 1, the input/output panel 1500 is shown to be disposed next to the bucket cover 1420. The input/output panel 1500 may include an input unit 1510 for receiving approval of a selection of a clothing treatment course from a user, and an output unit 1520 for visually displaying an operating state of the clothing treatment apparatus 1000.

The input unit 1510 may be formed as a jog dial, but is not limited thereto. The output unit 1520 may be formed to visually display an operating state of the clothing treatment apparatus 1000. The clothing processing apparatus 1000 may have a separate component for an audible display in addition to the visual display.

The controller 1600 is formed to control the operation of the clothing processing apparatus 1000 based on a user's input applied through the input unit 1510. The controller 1600 may include a circuit board and elements mounted on the circuit board. When the user selects a clothing treatment course through the input unit 1510, the controller 1600 controls the operation of the clothing treatment apparatus 1000 according to a preset algorithm.

A circuit board constituting the control unit 1600 and elements mounted on the circuit board may be disposed on the upper left or the upper right side of the drum 1030. In FIG. 1, it is shown that the circuit board is installed on the side wall of the cabinet 1010 corresponding to the upper right side of the drum 1030 opposite the bucket 1410. Considering that condensed water is collected in the water container 1410, air containing moisture flows through the circulation passage 1200, and electrical products such as circuit boards and devices are vulnerable to water, circuit boards and devices It is preferable to be spaced apart from the water tank 1410 or the circulation passage 1200 as far as possible.

FIG. 2 is a conceptual diagram illustrating circulation of air through the drum 1030 and the circulation passage 1200 illustrated in FIG. 1. In FIG. 2, the left side corresponds to the front F of the drum 1030, and the right side corresponds to the rear R of the drum 1030.

In order to dry the object to be treated put into the drum 1030, hot dry air is supplied to the inside of the drum 1030, the air that has dried the clothes is collected again to remove moisture, and then heat the drum 1030. The resupply process must be repeated. In order to repeat this process in the condensing dryer, air must continuously circulate through the drum 1030. The air is circulated through the drum 1030 and the circulation passage 1200.

The circulation passage 1200 is formed by an inlet duct 1220, an outlet duct 1210, and a connection duct 1230 disposed between the inlet duct 1220 and the outlet duct 1210. Each of the inlet duct 1220, the outlet duct 1210, and the connection duct 1230 may be formed by combining a plurality of members.

Based on the flow of air, the drum 1030, the outlet duct 1210, the connection duct 1230, and the inlet duct 1220 are sequentially connected, and the inlet duct 1220 is again connected to the drum 1030 to provide a waste flow path. (closed flow path) is formed.

The front supporter 1040 has an opening 1040 ′ corresponding to the front opening 1030 ′ of the drum for inputting the object to be treated, and a communication hole 1040 communicating with the outlet duct 1210 in the lower circumferential portion. ") is formed.

The outlet duct 1210 extends downward from the front supporter 1040 to the connection duct 1230. Air that has dried the object to be treated in the drum 1030 is recovered to the connection duct 1230 through the outlet duct 1210.

An evaporator 1110 and a condenser 1130 among the heat pump cycle devices 1100 are installed inside the connection duct 1230. Further, a circulation fan 1710 for supplying hot dry air to the inlet duct 1220 is also installed inside the connection duct 1230.

The evaporator 1110 is disposed on the upstream side of the condenser 1130 based on the flow of air, and the circulation fan 1710 is disposed on the downstream side of the condenser 1130. The circulation fan 1710 generates wind in a direction that sucks air from the condenser 1130 and supplies it to the inlet duct 1220.

The inlet duct 1220 extends upward from the connection duct 1230 and is disposed to cover the rear surface of the rear supporter 1050, and communicates with a vent 1050' formed in the rear supporter 1050. The rear surface of the rear supporter 1050 refers to a surface facing the rear of the laundry treatment apparatus 1000. The hot dry air is supplied into the drum 1030 through a vent 1050'.

Since the drum 1030 and the connection duct 1230 are disposed to be spaced apart from each other in the vertical direction, the inlet duct 1220 is directed toward the rear of the drum 1030 from the connection duct 1230 disposed under the drum 1030. It extends upward. Like the outlet duct 1210, the inlet duct 1220 may also extend in the vertical direction, but due to the connection structure, the inlet duct 1220 has a length extending in the vertical direction compared to the outlet duct 1210.

FIG. 3 is a perspective view showing the main parts mounted on the base cabinet 1310 and the base cabinet 1310 shown in FIG. 1, and FIG. 4 is a view showing the main parts shown in FIG. 3 divided into a base cabinet 1310. It is a drawing. 5 is a plan view of the base cabinet 1310 shown in FIG. 4.

3 to 5, a base cabinet 1310 is disposed under the drum 1030 to provide a space in which various components including the heat pump cycle devices 1100 are mounted. The bottom surface of the base cabinet 1310 may form the bottom surface of the laundry treatment apparatus 1000.

The base cabinet 1310 includes a drum motor mounting part 1314, a compressor mounting part 1315, a base flow path part 1310 ′, and a condensed water recovery part 1316. The drum motor mounting portion 1314 and the compressor mounting portion 1315 are disposed on one side of the base passage portion 1310'. In this embodiment, it is shown that the drum motor mounting portion 1314 and the compressor mounting portion 1315 are disposed at the left front and rear sides of the base flow passage 1310', respectively.

A drum motor 1800 that generates a driving force for rotation of the drum 1030 is mounted on the drum motor mounting portion 1314. A belt (not shown) for transmitting the driving force of the drum motor 1800 to the drum 1030 may be connected to the drum motor 1800. The belt is disposed to surround the outer periphery of the drum 1030.

A pulley 1810 and a spring (not shown) may be used to adjust the tension applied to the belt.

The pulley 1810 may be configured to apply a certain tension to the belt. The pulley 1810 is configured to be rotatable on a drum motor mounting portion 1314 or a bracket (not shown) mounted on the drum motor mounting portion 1314.

In order to adjust the tension of the belt, the drum motor 1800 may be configured to be rotated around one axis within a certain angle range and then returned to an initial position by the elastic force of the spring. To this end, the drum motor 1800 is configured to be rotatable about one axis to the drum motor mounting portion 1314, and the spring may be connected to the drum motor mounting portion 1314 and the drum motor 1800, respectively.

A blowing fan 1820 may be mounted on the shaft of the drum motor 1800. In this embodiment, it is shown that a belt is connected to a shaft provided on one side of the drum motor 1800 and a blowing fan 1820 is mounted on a shaft provided on the other side of the drum motor 1800. Shafts provided on both sides of the drum motor 1800 are rotated in the same direction and at the same speed.

When two shafts are provided in one drive motor 1730, there are many advantages in terms of improving power consumption of the clothing treatment apparatus 1000. Basically, compared to the case in which the drive motor 1730 for rotation of the drum 1030 and the drive motor 1730 for rotation of the blowing fan 1820 are respectively provided, power consumption is reduced by half.

In particular, the time point at which the blowing fan 1820 needs to rotate is the same as the time point at which the drum 1030 rotates. This is because hot dry air is supplied to the drum 1030 while the drum 1030 is rotating, and hot and humid air may leak from the drum 1030. Accordingly, a state in which rotation of any one of the drum 1030 and the blowing fan 1820 is unnecessary does not occur.

In this embodiment, it is shown that the blowing fan 1820 is configured as an axial fan and configured to blow air toward the front of the cabinet 1010. However, the present invention is not necessarily limited thereto. For example, the blowing fan 1820 may be configured as a sirocco fan.

The blowing fan 1820 is rotated according to the driving of the drum motor 1800 to blow air in the inner space between the cabinet 1010 and the drum 1030. Accordingly, air that leaks finely into the gap between the drum 1030 and the front supporter 1040 and the gap between the drum 1030 and the rear supporter 1050 flows through the inner space by the blowing fan 1820. do. Thus, the occurrence of condensation caused by air stagnation can be reduced.

Meanwhile, a heat dissipation fan may be mounted on a circuit board constituting the control unit. The heat dissipation fan forms a circulation flow for circulating air in the inner space between the cabinet 1010 and the drum 1030 together with the blowing fan 1820 while dissipating elements mounted on the circuit board. The heat dissipation fan is located above the base flow path part 1310 ′, and may be configured to blow air downward, that is, toward the base flow path part 1310 ′.

The heat dissipation fan may be disposed on the opposite side of the blowing fan 1820 based on the center of the drum 1030 to form a circulation flow surrounding the drum 1030 together with the blowing fan 1820. For example, a blowing fan 1820 may be disposed at the lower left of the drum 1030, and a heat dissipating fan may be disposed at the upper right of the drum 1030.

An exhaust fan 1730 is installed in the cabinet 1010 and is configured to discharge air in the space between the cabinet 1010 and the drum 1030 to the outside. That is, the air leaked from the drum 1030 is exhausted to the outside while continuously flowing by the blowing fan 1820 and a heat dissipating fan (not shown). The exhaust fan 1730 may be located behind the heat dissipation fan. In this embodiment, it is shown that the exhaust fan 1730 is installed on the rear wall of the cabinet 1010 located behind the heat dissipation fan.

A compressor 1120 that generates compressed air for heat exchange is mounted on the compressor mounting part 1315. The compressor 1120 is an element constituting the heat pump cycle devices 1100, but does not directly heat exchange with air, and thus does not need to be installed in the base flow path 1310'. Rather, if the compressor 1120 is installed in the base flow path 1310 ′, it may interfere with the flow of air. Therefore, the compressor 1120 is preferably installed outside the base flow path 1310 ′.

The refrigerant is evaporated (liquid -> gaseous) while absorbing heat in the evaporator 1110, becomes a low-temperature, low-pressure gaseous state, and is sucked into the compressor 1120. Based on the flow of the refrigerant, a gas-liquid separator 1140 is installed on the upstream side of the compressor 1120. The gas-liquid separator 1140 separates the refrigerant flowing into the compressor 1120 into a gas phase and a liquid phase so that only the gaseous refrigerant flows into the compressor 1120. Accordingly, a problem in which a liquid refrigerant flows into the compressor 1120 and causes a malfunction or a decrease in efficiency can be prevented.

The compressor mounting part 1315 is provided with fixing ribs 1315' for fixing the compressor 1120 at at least three locations. In order to reduce vibration, the fixing rib 1315 ′ may extend through the compressor mounting portion 1315 and extend toward the rear surface. The fixing rib 1315 ′ extending to the rear surface is configured not to touch the bottom surface.

The compressor mounting portion 1315 may be provided with a support rib 1315" for supporting the compressor 1120. The support rib 1315" is a center of a virtual polygon formed by connecting a plurality of fixed ribs 1315'. It may be composed of a combination of a portion extending radially from and forming a concentric circle with respect to the center.

A compressor cooling fan 1720 may be installed adjacent to the compressor 1120. The compressor cooling fan 1720 is configured to generate wind toward the compressor 1120 or to suck and blow air around the compressor 1120. The temperature of the compressor 1120 may be lowered by the compressor cooling fan 1720, and as a result, compression efficiency may be improved. In this embodiment, it is shown that the compressor cooling fan 1720 is installed on the rear wall of the cabinet 1010 located behind the compressor 1120.

The base passage part 1310 ′ forms a part of the circulation passage 1200. Based on the flow of air, the base passage part 1310 ′ is divided into a guide part 1311, a heat exchanger accommodation part 1312, and a circulation fan accommodation part 1313. The evaporator 1110 and the condenser 1130 are disposed in the heat exchanger receiving part 1312, and the circulation fan 1710 is disposed in the circulation fan receiving part 1313 to face the condenser 1130.

The guide part 1311 corresponds to a portion into which air discharged from the front opening 1030 ′ of the drum 1030 is introduced. The guide portion 1311 is formed with an opening that is open upward, and the opening communicates with the front duct connector 1210. Air flowing downward through the front duct connector 1210 is changed from the guide portion 1311 to the rear of the base cabinet 1310 and flows into the heat exchanger accommodating portion 1312.

The heat exchanger accommodating part 1312 corresponds to a part in which an evaporator 1110 for removing moisture from the air introduced from the guide part 1311 and a condenser 1130 for heating the removed air are installed. The heat exchanger accommodating part 1312 may extend in a straight line from the front to the rear of the base cabinet 1310.

The refrigerant compressed by the compressor 1120 becomes a high temperature and high pressure state and flows to the condenser 1130. In the condenser 1130, the refrigerant is liquefied while releasing heat. The liquefied high-pressure refrigerant is depressurized in an expander (not shown). The low temperature and low pressure liquid refrigerant enters the evaporator 1110.

The circulation fan accommodating portion 1313 corresponds to a portion accommodating a circulation fan 1710 that sucks and blows air that has passed through the heat exchanger accommodating portion 1312. The circulation fan 1710 is disposed so that the rotating shaft faces the condenser 1130 and the evaporator 1110, and is composed of a sirocco fan that blows air in front, that is, heated air through the condenser 1130 to the side.

The hot dry air that has passed through the condenser 1130 is supplied to the drum 1030 through the rear duct connector 1220 through the receiving portion of the blowing fan 1820. The high-temperature dry air supplied to the drum 1030 evaporates the moisture of the object to be treated and becomes hot and humid air. The hot and humid air is recovered through the front duct connector 1210, and heat exchanged with the refrigerant in the evaporator 1110 to become low-temperature air. At this time, as the air temperature decreases, the amount of saturated water vapor in the air decreases, and moisture contained in the air is condensed. Subsequently, the low-temperature dry air exchanges heat with the refrigerant in the condenser 1130 to become high-temperature dry air and is supplied to the drum 1030 again.

The evaporator 1110, the condenser 1130, and the circulation fan 1710 mounted on the base passage part 1310' are positioned eccentrically from the center of the base cabinet 1310 to one side. That is, in the base flow path part 1310 ′, the flow path after the guide part 1311 extends backward from a position eccentric from the center of the base cabinet 1310 to one side.

A condensed water recovery part 1316 is provided between the base flow path part 1310 ′ and the compressor mounting part 1315. The condensed water recovery unit 1316 communicates with the base flow path 1310' to form a space in which condensed water generated in the evaporator 1110 is recovered. In this embodiment, it is shown that the condensed water recovery unit 1316 is configured to communicate with the heat exchanger receiving unit 1312.

A water pump 1440 is installed in the condensed water recovery unit 1316. The water pump 1440 is configured to transfer the condensed water collected by the condensed water recovery unit 1316 to the water tank 1410. The condensed water transferred to the water tank 1410 may be transferred by the water pump 1440 and used for cleaning the evaporator 1110.

The condensed water recovery part 1316 may be formed to protrude from one surface of the base cabinet 1310 in the form of a partition wall, or may be formed in a form recessed from one surface of the base cabinet 1310 as in the present embodiment.

A communication hole 1316 ′ communicating the heat exchanger accommodating part 1312 and the condensed water recovery part 1316 may be formed at one rear end of the condenser 1130. The condensate generated in the evaporator 1110

It falls to the bottom surface of the heat exchanger accommodating part 1312.

On one side of the bottom surface of the heat exchanger accommodating portion 1312, a water collecting portion 1312' having a height lower than that of the surrounding bottom surface is formed. The water collecting part 1312' is located at the lowest position from the bottom surface of the heat exchanger receiving part 1312, and the bottom surface is formed to incline downward toward the water collecting part 1312'. The condensed water collected in the water collecting part 1312 ′ flows into the condensed water recovery part 1316 through a communication hole 1316 ′ communicating with the water collecting part 1312 ′. That is, the heat exchanger accommodating part 1312 is formed to be inclined toward the communication hole 1316' so that the condensed water can be moved to the communication hole 1313a" by gravity.

The circulation passage 1200 forms a path through which air discharged from the front opening 1030 ′ of the drum 1030 flows into the rear opening 1030 ″ of the drum 1030 through heat exchange. 1310 is disposed under the drum 1030 to provide a space in which various components are mounted, and forms a part of the circulation passage 1200.

The base flow path part 1310' is divided into a guide part 1311, a heat exchange part 1312, and a circulation fan receiving part 1313. The guide part 1311 corresponds to a part into which air discharged from the front opening 1030 ′ of the drum 1030 is introduced, and the heat exchange part 1312 removes moisture from the air introduced from the guide part 1311. The evaporator 1110 and the condenser 1130 for heating the air from which moisture has been removed are installed, and the circulation fan accommodating part 1313 is a circulation fan 1710 that sucks and blows air that has passed through the heat exchange part 1312 ) Is the part that is accepted.

A water cover 1900 is mounted on the bottom surface of the heat exchanger 1312 of the base flow path 1310'. The water cover 1900 provides a space in which the evaporator 1110 and the condenser 1130 are seated, but is configured to separate the evaporator 1110 and the condenser 1130 from the bottom surface.

That is, the water cover 1900 causes the condensed water generated in the evaporator 1110 and dropped to the bottom surface of the heat exchange unit 1312 to reach the evaporator 1110 and the condenser 1130. In addition, the water cover 1900 is configured to limit contact with the condenser 1130 by scattering condensed water on the bottom surface of the heat exchanger 1312 by the suction force of the circulation fan 1710.

Hereinafter, a structure of a water cover according to an embodiment of the present invention will be described in detail with reference to FIGS. 6 to 11.

6 is a perspective view of the water cover shown in FIG. 4.

The water cover 1900 is configured to support the evaporator 1110 and the condenser 1130, and is located in the base passage part 1310' of the base cabinet 1310. In particular, it is located in the heat exchanger accommodating portion 1312 provided in the base cabinet 1310 to accommodate the evaporator 1110 and the condenser 1130.

Based on the direction in which air is moved in the base flow path part 1310', the water cover 1900 includes an evaporator seating portion 1901 positioned on the upstream side, a condenser seating port 1905 positioned downstream, and It includes a connection part 1903.

The evaporator seating portion 1901 supports the evaporator 1110. A fixing rib 1916 for limiting the installation position of the evaporator 1110 is provided on the upper surface of the evaporator seating part 1901. The fixed rib 1916 is formed in a'a' or'T' shape, and is configured to be caught in the corner of the evaporator 1110.

When the evaporator mounting part 1901 supports the evaporator 1110, the upper surface of the evaporator mounting part 1901 and the lower surface of the evaporator 1110 are in contact with each other.

The evaporator seating portion 1901 may be formed with an opening 1910 penetrating in the vertical direction, and a plurality of the openings 1910 may be formed.

The opening 1910 includes an upper opening 1910 ′ formed on the upper side thereof and a lower opening 1910 ″ formed on the lower side thereof. The high-temperature and humid air discharged from the front drum exchanges heat with the evaporator 1110 to discharge condensed water, and the condensed water flows in through the upper opening 1910 ′, and the condensed water is introduced through the lower opening 1910 ″. Is discharged.

An inclined portion 1911 is formed around the opening 1910. The inclined portion 1911 may be formed in plural. A surface connecting the upper opening 1910 ′ and the lower opening 1910 ″ may be formed of an inclined portion 1911. In an embodiment of the present invention, when the upper opening 1910 ′ and the lower opening 1910 ″ are formed in a square shape, a surface connecting the circumferences of the upper opening 1910 ′ and the lower opening 1910 ″ is It can be composed of four slopes.

Condensed water flowing into the upper opening 1910' flows down along the inclined portion 1911, and is discharged downward through the lower opening 1910'.

The inclined portion 1911 may include an inclined portion that inclines downward toward the downstream side based on the direction in which the air moves in the base passage portion 1310 ′. The first inclined portion 1911a and the second inclined portion 1911b are sequentially arranged toward the downstream side, and are inclined downward toward the downstream side.

Condensed water discharged from the air passing through the evaporator 1110 is located on the first inclined portion 1911a and the second inclined portion 1911b, and is moved to the lower opening 1910'' along the inclined surface by gravity.

The hot and humid air discharged from the front side of the drum is sucked in by the circulation fan 1710, and is moved to a path flowing into the rear side of the drum through the evaporator and the condenser in sequence. That is, the movement direction of the air and the direction in which the first inclined portion 1911a and the second inclined portion 1911b are inclined are the same, so that the first inclined portion 1911a and the second inclined portion 1911b are The condensed water located on the inclined surface may be pressurized by air in the direction of the lower opening 1910 ″. Through this, the condensate can be drained more smoothly.

The first inclined portion 1911a and the second inclined portion 1911b may have the same inclination.

Further, the first inclined portion 1911a may be inclined more gently than the second inclined portion 1911b.

Based on the direction in which the air moves in the base flow path 1310', the inclined surface in which the condensed water flows in the first inclined portion 1911a is inclined while facing the direction in which the air moves, and the condensed water in the second inclined portion 1911b The slope that flows through is inclined looking toward the vast direction of the direction in which the air moves.

The condensed water located on the inclined surface of the first inclined part 1911a is pressurized by the air flowing along the inclined surface and moved to the lower opening 1910'', and the condensed water located on the inclined surface of the second inclined part 1911b is While pressing the inclined surface, it is pressurized by air flowing along the inclined surface and moved to the lower opening 1910''.

Forming the inclination of the second inclined portion 1911b inclined downward toward the downstream side more rapidly increases the pressing area for the air to press the second inclined portion 1911b, and the second inclined portion ( The condensed water located on the inclined surface of 1911b) can be moved to the lower opening 1910'' by pressing more strongly.

The inclined surface of the second inclined portion 1911b through which condensed water flows may be formed vertically toward the lower side.

A third inclined portion 1911c and a fourth inclined portion 1911d may be formed around the first inclined portion 1911a and the second inclined portion 1911b. The third inclined portion 1911c and the fourth inclined portion 1911d surround the upper opening 1910' and the lower opening 1910' together with the first inclined portion 1911a and the second inclined portion 1911b. And formed to be inclined toward the lower opening 1910 ″.

The third and fourth inclined portions 1911c and 1911d face each other and are inclined toward the lower opening 1910 ″ along a direction intersecting the direction in which air is moved in the base flow path 1310 ′.

Condensed water introduced through the upper opening 1910' and located at the third and fourth inclined portions 1911c and 1911d is moved along the inclined surfaces of the third and fourth inclined portions 1911c and 1911d by gravity (1910''), or pressurized by air moving from the downstream side to the upstream side and moved to the second inclined portion 1911b, and then received a force by gravity along the inclined surface of the second inclined portion 1911b or It is pressurized by air and discharged to the lower opening 1910''.

Peripheral inclined portions 1912 may be formed on both sides of the evaporator seating portion 1901 based on a direction crossing a direction in which air is moved in the base flow path 1310 ′. The peripheral inclined portion 1912 may be formed to incline upward toward the center from both ends of the evaporator seating portion 1901.

End plates are provided at both ends of the evaporator 1110, and the refrigerant pipe through which the refrigerant flows in the evaporator protrudes in the direction of one end plate of the evaporator, and then is curved 180° and extends in the direction of the other end plate of the evaporator, After protruding in the direction of the end plate on the other side of the evaporator 1110, it is curved 180° and extends in the direction of the end plate on the other side of the evaporator 1110.

That is, the curved portions of the refrigerant pipe protrude from both ends of the evaporator 1110, and the condensed water discharged from the air in contact with the curved portion falls on the inclined surface of the peripheral inclined portion 1912. The condensed water dropped on the inclined surface is moved toward both sides of the evaporator seating portion 1901 by receiving force by gravity, and falls out of the evaporator seating portion 1901.

Based on the direction crossing the direction in which air moves in the base flow path 1310 ′, the upper surface of the evaporator seating part 1901 is sequentially placed in a first area D1, see FIG. 7, and a second area D2. 7) and a third area (D3, see FIG. 7), the first and third areas D1 and D3 have peripheral inclined portions 1912a inclined upward toward the second area D2, 1912b) may be formed, and a plurality of openings 1910 may be formed in the second region D2. The bottom surface of the evaporator 1110 may be supported in line contact with the upper circumference 1910' of the plurality of openings 1910 formed in the second region D2. This will be described in detail later.

The peripheral inclined portion 1912a of the first region D1 and the third inclined portion 1911c of the opening 1910 in contact therewith have an upper side along a direction intersecting the direction in which air is moved in the base flow path portion 1310'. A support rib 1915 protruding into the groove may be formed.

In addition, the peripheral inclined portion 1912b of the third region D3 and the fourth inclined portion 1911d of the opening 1910 in contact therewith have a direction intersecting the direction in which air is moved in the base flow path 1310'. Accordingly, a support rib 1915 protruding upward may be formed.

The support ribs 1915a and 1915b protrude to the same height as the circumference of the upper opening 1910', and support the evaporator together with the circumference of the upper opening 1910'.

As the support rib 1915 supports the evaporator at the peripheral inclined portion 1912, the evaporator seating portion 1901 can support the evaporator more stably.

A condenser seating portion 1902 is positioned on the downstream side of the evaporator seating portion 1901 based on the direction in which air is moved in the base flow path portion 1310'.

The condenser seating part 1902 supports the condenser, and a fixing rib 1956 for limiting the installation position of the condenser 1130 is provided on the upper surface of the condenser seating part 1905. The fixing rib 1956 is formed in a'A' shape or a'T' shape, and is configured to be caught in the corner of the condenser 1130.

After passing through the evaporator 1110, the temperature decreases and the dried air is heated in the condenser 1130 and flows into the rear opening of the drum.

An upwardly extending rib 1951 is formed on the upstream side of the condenser seating part 1905 based on the direction in which air is moved in the base flow path part 1310'.

The upwardly extending rib 1951 protrudes upward from the upper surface of the condenser seat 1905 along a direction crossing the direction in which air is moved.

The upwardly extending ribs 1951 heat exchange with the evaporator to limit the flow of condensed water generated from the air into the condenser seat 1905.

A drain hole 1952 is positioned on the downstream side of the upwardly extending rib 1951 based on the direction in which air is moved within the base flow path 1310'. The drain hole 1952 is formed to penetrate the condenser seat 1905 in the vertical direction, and is formed to be adjacent to the upwardly extending rib 1951.

Condensed water flowing into the condenser seating portion 1905 over the upwardly extending rib 1951 flows into the drainage hole 1952 adjacent to the upwardly extending rib 1951 and is discharged downward.

When the direction in which the air moves in the base flow path 1310' is the length direction of the condenser seating portion 1905, and the direction crossing the direction in which the air moves is the width direction of the condenser seating portion 1905, drainage The holes 1952 may be repeatedly arranged at a recognized interval along the length direction and the width direction of the condenser seating portion 1905. The two drainage holes 1952 adjacent in the longitudinal direction may be arranged so as to completely overlap in the longitudinal direction.

In addition, the two drainage holes 1952 adjacent in the longitudinal direction may be formed to partially overlap in the longitudinal direction. That is, the drainage holes 1952 may be staggered along the length direction.

The upper surface of the evaporator seating portion 1901 and the upper surface of the condenser seating portion 1905 may be positioned parallel to each other, and the evaporator seating portion 1901 and the condenser seating portion 1905 are connected by a connection portion 1902.

The connection portion 1902 may be formed in plural between the evaporator seating portion 1901 and the condenser seating portion 1905, and may be formed to connect the shortest distance between the evaporator seating portion 1901 and the condenser seating portion 1905. have.

Based on a direction intersecting with a direction in which air is moved in the base passage part 1310 ′, the connection part 1903 may be formed in a plate shape having both sides facing each other. Both surfaces facing each other may be formed to be parallel to a direction in which the air is moved.

That is, the connection portion 1902 may be formed in a plate shape having both sides parallel to the longitudinal direction of the evaporator seating portion 1901 and the condenser seating portion 1905.

That is, the normal lines of both sides of the connection portion 1902 may be parallel to the width direction of the evaporator seating portion 1901 and the condenser seating portion 1905.

Since the direction in which the air is moved and both sides of the connection part 1902 are formed in parallel, condensate water generated from the air passing through the evaporator is minimized in contact with the connection part 1902, and even if contacted, it moves downward along the both sides.

A blocking rib 1917 is formed on the lower surface of the evaporator seating part 1901. The blocking rib 1917 is a condensed water on the bottom surface of the base flow path part 1310 ′ by the suction force of the circulation fan 1710 and flows back to the lower opening 1910 ″ of the evaporator seating part 1901, or the condenser Prevents scattering toward (1130).

The blocking rib 1917 protrudes downward from the lower surface of the evaporator seat 1901 along the width direction of the evaporator seat 1901.

The blocking rib 1917 may be formed in plural. In one embodiment of the present invention, the blocking ribs 1917 are respectively located at both ends of the evaporator seating portion 1901 with respect to the longitudinal direction of the evaporator seating portion 1901, and may be additionally provided therebetween.

The plurality of blocking ribs 1917 may have different lengths based on the vertical direction. This will be described in detail later.

7 is a plan view of the water cover shown in FIG. 6.

In FIG. 7, a direction in which air moves in the base flow path 1310 ′ indicates a first direction DR1, and a direction crossing the direction in which the air moves indicates a second direction DR1.

The first direction DR1 is parallel to the longitudinal direction of the water cover 1900, and the second direction DR2 is parallel to the width direction of the water cover 1900.

In the water cover 1900, an evaporator seating portion 1901, a connection portion 1903, and a condenser seating portion 1905 are sequentially positioned along a first direction, and the evaporator seating portion 1901 and the condenser seating portion 1905 are connected. Connected by (1903).

The evaporator seating part 1901 may be sequentially divided into a first area D1, a second area D2, and a third area D3 along the second direction DR2.

A plurality of openings 1910a, 1910b, and 1910c are formed in the second region D2, and first, second, third and fourth inclined portions are formed around each of the plurality of openings 1910a, 1910b, and 1910c. 1911a, 1911b, 1911c, 1911d) are located.

Each of the openings 1910 is formed to penetrate in the vertical direction, has an upper opening 1910' through which condensate discharged from the air flows through heat exchange with the evaporator 1110, and flows into the upper opening 1910'. It has a lower opening 1910'' through which condensed water is discharged.

The first, second, third and fourth inclined portions 1911a, 1911b, 1911c, and 1911d connect the circumference of the upper opening 1910 ′ and the lower opening 1910 ″.

The first inclined portion 1911a and the second inclined portion 1911b are sequentially arranged in the first direction DR1 and are inclined downward in the first direction DR1.

The first inclined portion 1911a may be inclined more gently than the second inclined portion 1911b, and the second inclined portion 1911b may be formed vertically downward.

When pointing the first area D1 side to the rear and the third area D3 side to the front based on the second direction DR2, the third inclined portion 1911c is inclined downward toward the front, and the fourth The inclined portion 1911d is inclined downward toward the rear.

The plurality of openings 1910 may be repeatedly disposed along the first direction DR1 and the second direction DR2. Also, two openings 1910 adjacent to each other along the first direction DR1 and the second direction DR2 may be positioned to contact each other.

Of the two openings 1910 in contact with each other along the first direction DR1, the second inclined portion 1911b of the opening 1910 located on the front side and the first inclined portion 1911a of the opening 1910 located on the rear side The upper sides of) are in contact with each other.

Of the two openings 1910 in contact with each other along the first direction DR1, the circumference of the upper opening 1910 ′ of the opening 1910 located on the front side and the upper opening 1910 ′ of the opening 1910 located on the rear side The perimeters of) overlap each other.

In addition, the fourth inclined portion 1911d and the third area D3 of the opening 1910 located on the side facing the first area D1 of the two openings 1910 in contact with each other along the second direction DR2 are formed. The upper sides of the second inclined portions 1911c of the openings 1910 located on the facing side are in contact with each other.

In addition, the circumference of the upper opening 1910 ′ of the opening 1910 and the third region D3 of the two openings 1910 in contact with each other along the second direction DR2 facing the first region D1 The circumferences of the upper openings 1910' of the openings 1910 located on the side facing toward are overlapped with each other.

That is, a plurality of openings 1910 are formed, and the plurality of openings 1910 are repeatedly arranged along a first direction DR1 and a second direction DR2, and the first direction DR1 and the second direction The peripheries of the upper openings 1910 ′ of the two openings 1910 adjacent to each other by DR2 are formed to partially overlap.

Through the above structure, when the evaporator 1110 is supported by the upper surface of the evaporator seat 1901, the bottom surface of the evaporator 1110 is the upper opening of the plurality of openings 1910 formed in the second region D2 ( 1910'). That is, the bottom surface of the evaporator 1110 is in line contact with the top surface of the evaporator seating portion 1901.

Condensed water discharged from the air by exchanging heat with the evaporator 1110 flows into the upper opening 1910' and is discharged to the lower opening 1910', and the condensed water falls from the evaporator 1110 to the perimeter of the upper opening 1910'. It flows directly into the inside or flows down along the inclined portion 1910 along the circumference of the upper opening 1910' and discharged into the lower opening 1910'.

In this case, when the condensed water is located around the upper opening 1910' crossing the first direction DR1, the lower side along the inclined portion of either the first inclined portion 1911a or the second inclined portion 1911b Can be moved to.

In addition, when the condensed water is located around the upper opening 1910 ′ crossing the second direction DR2, the third inclined portion 1911c or the fourth inclined portion 1911d moves downward along the inclined portion of any one of the Can be moved.

That is, the condensed water flowing into the second region D2 may be discharged downward without accumulating on the upper surface of the second region D2. A plurality of openings 1910 are provided in the second region D2, an inclined surface is formed around the plurality of openings 1910, and the evaporator is in line contact with the upper opening 1910' to smooth condensate water. It is drained and water can be prevented from accumulating on the upper surface of the evaporator seating part 1901.

When water accumulates on the upper surface of the evaporator seating part 1901, the water accumulated on the upper surface after the clothing treatment apparatus 1000 stops operating may evaporate to accumulate lint.

By adopting a structure that prevents water from accumulating on the upper surface of the evaporator seating portion 1901, it is possible to prevent lint from accumulating on the upper surface of the evaporator seating portion 1901.

When pointing the first area D1 side to the rear and the second area D2 side to the front based on the second direction DR2, the first area D1 is the rear boundary of the second area D2. A peripheral inclined portion 1912a inclined downward from the rear is formed, and a peripheral inclined portion 1912b inclined downward from the front boundary of the second area D2 is formed in the third area D3. Is formed.

The peripheral inclined portion 1912a is in contact with the third inclined portion 1910c of the opening 1910 located on the rear side of the plurality of openings 1910, and the peripheral inclined portion 1912b is in front of the plurality of openings 1910. It contacts the fourth inclined portion 1910d of the located opening 1910.

That is, the peripheral inclined portions 1912a and 1912b are in contact with the peripheries of the upper openings 1910' of the plurality of openings 1910.

When pointing the first area D1 side to the rear side and the second area D2 side to the front side based on the second direction DR2, the condensed water moved to the rear side boundary of the second area D2 is the first area. It is moved downward along the peripheral inclined portion 1912a of (D1) or the third inclined portion 1911c located on the rear side of the second region D2.

In addition, the condensed water moved to the front boundary of the second area D2 is the peripheral inclined portion 1912b of the third area D1 or the fourth inclined portion 1911d located at the front side of the second area D2. It moves downwards along the line.

Through the above structure, the condensed water discharged from the air by exchanging heat with the evaporator is mostly moved downward along the inclined portion 1910 or the peripheral inclined portion 1912, and falls to the bottom surface of the heat exchanger receiving portion 1312, and the bottom It is moved toward the water collecting part 1312' along the surface.

When the evaporator seating portion 1110 is injection-molded, a gate surface 1914 may be formed in a portion adjacent to the gate. In an embodiment of the present invention, the gate surface 1914 may be located at the center of the second region D2.

When the gate surface 1914 is formed in the center of the second region D2, the opening 1910 may be formed in plural to surround the gate surface 1914. The sizes of the upper opening 1910 ′ and the lower opening 1910 ′ of the opening 1910 may be formed differently.

The water cover 1900 of the present invention does not necessarily include the gate surface 1914. For example, in the second region D2, a plurality of openings 1910 may be repeatedly arranged along the first direction DR1 and the second direction DR2.

Also, the two openings 1910 adjacent to each other with respect to the first direction DR1 may be disposed so as to partially overlap along the first direction DR1. That is, the plurality of openings 1910 may be alternately disposed along the first direction DR1.

A portion of the upper circumference 1910 ′ of the opening 1910 located at the rear side based on the first direction DR1 may form a rear boundary of the second region D2. The upper side of the second inclined portion 1911b of the opening 1910 forms a part of the rear boundary of the second region D2.

In addition, a curved surface curved toward the rear side may be formed on the upper side of the second inclined portion 1911b of the opening 1910 located at the rear side based on the first direction DR1.

The second inclined portion 1911b of the opening 1910 located at the rear side forms a part of the rear boundary of the second region D2. The connection part 1902 extends from the side facing the rear side of the second inclined part 1911b toward the condenser seating part 1905. When the upper side of the second inclined portion 1911b is formed perpendicular to the surface from which the connecting portion 1903 extends, the condensed water located at the vertical corner is the connecting portion 1903 by air sucked by the circulation fan 1710 It moves downwards in the direction, but condensate particles at the vertical corners can be resisted by the surface tension to reduce the surface area.

The surface energy of a liquid is higher than that of a solid, and in the case of a liquid with high surface energy, it has the property of reducing the surface area or making contact with other surfaces. When the upper side of the second inclined portion 1911b of the opening 1910 located on the rear side is formed perpendicular to the surface from which the connection portion 1903 protrudes, water particles in the condensate at the vertical corners have no additional contact surface. Bar, it is moved in the direction to reduce the surface area, it is possible to reduce the efficiency of the condensed water is moved downwards beyond the vertical edge.

On the other hand, when a curved surface curved toward the rear side is formed on the upper side of the second inclined portion 1911b of the opening 1910 located on the rear side based on the first direction DR1, the second inclined portion 1911b ), the water particles of the condensed water are moved along the curved surface toward the lower surface energy, so that the efficiency of the condensed water moving downward along the vertical surface facing the connection part 1902 can be improved.

The third inclined portion 1911c or the fourth inclined portion 1911d of the opening 1910 where the peripheral inclined portions 1912a and 1912b and the peripheral inclined portions 1912a and 1912b are in contact with each other has an upward direction along the second direction DR2. Support ribs 1915a and 1915b that protrude to are formed.

The support ribs 1915a and 1915b protrude up to the same height as the circumference of the upper opening 1910', and support the evaporator 1110 together with the upper circumference 1910'.

A condenser seating portion 1903 is positioned behind the seating portion 1901 based on the first direction DR1.

The condenser seating part 1903 supports the condenser, and the temperature decreases through the evaporator 1110 and the dried air is heated in the condenser 1130 and flows into the rear opening of the drum.

An upwardly extending rib 1951 is formed on the front side of the condenser seating part 1905.

The upwardly extending rib 1951 protrudes upward from the upper surface of the condenser seat 1905 along the second direction DR2.

The upwardly extending rib 1951 heat-exchanges with the evaporator 1110 to limit the flow of condensed water generated from the air into the condenser seat 1905. In addition, condensed water accumulated on the bottom surface of the heat exchanger accommodating part 1312 is restricted from being scattered by the suction force of the circulation fan 1710 and flowing into the upper side of the condenser seating part 1905.

A drain hole 1952 is positioned at the rear side of the upwardly extending rib 1951 based on the first direction DR1. The drain hole 1952 is formed to penetrate the condenser seat 1905 in the vertical direction, and is formed to be adjacent to the upwardly extending rib 1951.

Condensed water flowing into the condenser seating portion 1905 over the upwardly extending rib 1951 flows into the drainage hole 1952 adjacent to the upwardly extending rib 1951 and is discharged downward.

When the first direction DR1 is the length direction of the condenser seating portion 1905 and the second direction DR2 is the width direction of the condenser seating portion 1905, the drain hole 1952 is formed of the condenser seating portion 1905. It can be arranged repeatedly at intervals of recognition along the length and width directions. The two drainage holes 1952 adjacent in the longitudinal direction may be arranged so as to completely overlap in the longitudinal direction.

In addition, the two drainage holes 1952 adjacent in the longitudinal direction may be formed to partially overlap in the longitudinal direction. That is, the drainage holes 1952 may be staggered along the length direction.

The upper surface of the evaporator seating portion 1901 and the upper surface of the condenser seating portion 1905 may be positioned parallel to each other, and the evaporator seating portion 1901 and the condenser seating portion 1905 are connected by a connection portion 1902.

The connection portion 1902 may be formed in plural between the evaporator seating portion 1901 and the condenser seating portion 1905, and may be formed to connect the shortest distance between the evaporator seating portion 1901 and the condenser seating portion 1905. have.

Based on the second direction DR2, the connection part 1903 may be formed in a plate shape having both surfaces facing each other. Both surfaces facing each other may be formed to be parallel to the second direction DR2.

That is, the connection portion 1902 may be formed in a plate shape having both sides parallel to the longitudinal direction of the evaporator seating portion 1901 and the condenser seating portion 1905.

That is, the normal lines of both sides of the connection portion 1902 may be parallel to the width direction of the evaporator seating portion 1901 and the condenser seating portion 1905.

By forming the second direction DR2 and both sides of the connecting portion 1902 in parallel, condensed water generated from the air passing through the evaporator is minimized in contact with the connecting portion 1903, and even if contacted, it moves downward along the both sides. .

FIG. 8 is a right side view of the water cover shown in FIG. 6, and FIG. 9 is a front view of the water cover shown in FIG. 6.

In FIG. 8, based on the direction in which air is moved in the base flow path part 1310', the upstream side points to the front and the downstream side points to the rear.

In FIG. 9, one side points to the left side and the other side opposite to the one side points to the right side based on a direction crossing the direction in which the air moves in the base flow path part 1310 ′.

With reference to FIGS. 8 and 9, the support 1907 and the blocking ribs 1917 and 1957 protruding downward from the bottom surface of the water cover 1900 will be described in detail.

The support part 1907 may be formed in plural.

The plurality of support portions 1907 may be sequentially disposed in a downstream side based on a direction in which air is moved within the base passage part 1310 ′, and may be formed longer in a downward direction toward a downstream side.

That is, the plurality of support portions 1907 may be formed longer in a downward direction from the front to the rear.

In addition, the plurality of support portions 1907 are sequentially arranged from one side to the other side opposite to the direction in which the air moves in the base flow path portion 1310 ′, and are sequentially arranged on either side. It may be formed longer in the downward direction as it goes toward the other side opposite to this.

That is, the plurality of support portions 1907 may be formed to be longer in a downward direction from one of the left and the right to the other.

That is, when the direction in which air moves in the base flow path part 1310' indicates the longitudinal direction of the water cover 1900, and the direction in which the air moves in the cross direction indicates the width direction of the water cover 1900 , The support part 1907 may be repeatedly arranged along the length and width directions of the water cover 1900, and may be formed to be longer in a downward direction as it goes from one side in the length direction and the width direction toward the other side opposite to it.

That is, the support portion 1907 may be repeatedly arranged from front to rear and from left to right, and may be formed longer in a downward direction as it goes from front to rear and from left to right.

Through the above structure, the upper surface of the water cover 1900 may be spaced apart from the bottom surface of the heat exchanger accommodating part 1312 by a predetermined distance, and may be positioned parallel to the bottom surface of the laundry treatment apparatus.

A water collecting part 1312 ′ is formed on one side of the bottom surface of the heat exchanger accommodating part 1312 provided in the base cabinet 1310 at a position lower than the surrounding slope. In one embodiment of the present invention, the bottom surface of the heat exchanger accommodating portion 1312 is formed to be inclined downward toward the water collecting portion 1312' from any one point on the downstream side. The one point and the water collecting part 1312 ′ for collecting condensed water are formed to face each other in the longitudinal direction and the width direction.

The vertical distance between the bottom surface of the heat exchanger accommodating part 1312 and the bottom surface of the water cover 1900 increases toward the downstream side along the longitudinal direction of the water cover 1900. In addition, the vertical distance between the bottom surface of the heat exchanger accommodating part 1312 and the bottom surface of the water cover 1900 is, along the width direction of the water cover 1900, the side where the water collecting part 1312' is formed and the other The closer it gets to the side.

In other words, the vertical length of the support part 1907 increases toward the downstream side along the longitudinal direction of the water cover 1900, and the water collecting part 1312 ′ is opposite from one side along the width direction of the water cover 1900. It gets shorter as you go to the other side. Through this structure, the support unit 1907 supports the evaporator seating unit 1901 and the condenser seating unit 1905 by a predetermined distance from the bottom surface of the heat exchanger receiving unit 1312, and the evaporator seating unit 1901 and the condenser The upper surface of the seating part 1905 may be positioned parallel to the floor surface on which the laundry treatment apparatus 1000 is installed.

The water cover 1900 includes blocking ribs 1917 and 1957 protruding downward from the lower surface.

The blocking ribs 1917 and 1957 are formed to protrude downward along the width direction of the water cover 1900.

The blocking ribs 1917 and 1957 extend from one side of the heat exchanger accommodating portion 1312 to the other side along the width direction of the water cover 1900.

The blocking ribs 1917 and 1957 extend from one side of the heat exchanger accommodating portion 1312 to the other side across the base flow path portion 1310'.

In addition, a plurality of blocking ribs 1917 and 1957 may be formed from an upstream side to a downstream side based on a direction in which air is moved in the base flow path part 1310 ′.

Since the bottom surface of the heat exchanger accommodating part 1312 through which condensed water flows is formed to incline downward from the upstream side to the downstream side, the blocking ribs 1917 and 1957 can be formed to be longer in the downward direction from the upstream side to the downstream side. have.

That is, the blocking rib 1957 may be formed longer in the downward direction from the front to the rear.

In addition, the blocking ribs 1917 and 1957 protrude downward along the width direction of the water cover 1900, and the downward end of the blocking ribs 1917 and 1957 is lower as it goes from one of the left and the right to the other. Can be formed gradually longer. Through this, between the lower ends of the blocking ribs 1917 and 1957 and the bottom surface of the heat exchanger accommodating part 1312 may be spaced apart at substantially regular intervals.

In the process of driving the clothes treatment apparatus 1000 according to the present invention, the condensed water accumulating on the bottom surface of the heat exchanger accommodating part 1312 forms a full water level of a predetermined height from the water collecting part 1312 ′.

The height of the shortest side at the lower end of the blocking ribs 1917 and 1957 is formed lower in the vertical direction than the full water level. Through this, before the condensed water reaches full water level, the blocking ribs 1917 and 1957 are immersed in the condensed water accumulated on the bottom surface of the heat exchanger accommodating part 1312, and from the front opening of the drum by the suction force of the circulation fan 1710. It is possible to prevent the discharged air from moving to the lower side of the water cover 1900.

A lower flow path through which air is moved to the lower side of the water cover 1900 is sealed, so that most of the air discharged from the front opening of the drum and introduced into the heat exchange unit 1312 can participate in heat exchange with the evaporator 1110. Accordingly, the condensation efficiency of air passing through the evaporator 1110 may be improved.

10 is a cross-sectional view taken along line A-A of FIG. 5.

Referring to FIG. 10, a cross section in the width direction of a state in which the water cover 1900 is mounted on the heat exchanger accommodating part 1312 is shown.

In FIG. 10, one side points to the left and the other side opposite to the one side points to the right side based on the direction crossing the direction in which the air moves in the base flow path part 1310'.

When the clothing treatment apparatus 1000 is driven, condensed water is generated from air through heat exchange with the evaporator 1110.

The generated condensate flows along a plurality of inclined portions 1911a, 1911b, 1911c, 1911d and peripheral inclined portions 1912a, 1912b formed on the upper surface of the evaporator seating portion 1901, and the bottom surface of the heat exchanger receiving portion 1312 Is discharged.

The condensed water flows into the water collecting part 1312 ′ along the bottom surface of the heat exchanger receiving part 1312 by gravity, and the condensed water gradually accumulates on the bottom surface of the heat exchanger receiving part 1312. When a predetermined time elapses after the clothes treatment apparatus 1000 starts to be driven, the condensed water may form a full water level H1 having a predetermined height from the bottom surface of the clothes treatment apparatus 1000.

The height H2 of the lower opening 1910 ″ of the evaporator seating portion 1901 is set to be greater than H1 with respect to the bottom surface of the laundry treatment apparatus 1000. If H2 is less than or equal to H1, condensate can flow back at full water.

In an embodiment of the present invention, the height difference H2-H1 between the lower opening 1910 ″ and the full water level may be set to 4.9 mm. Also, a height difference H3-H1 between the height H3 of the upper opening 1910' and the full water level may be set to 12.4mm.

The inclined portions (1911a, 1911b, 1911c, 1911d) formed on the upper surface of the evaporator seating portion 1901 and the peripheral inclined portions 1912a, 1912b are formed to be inclined downward from the circumference of the upper opening 1910'. It is preferable to determine the inclination in consideration of the height H3 of the opening 1910'.

The condensed water is moved by gravity along the third inclined portion 1911c and the fourth inclined portion 1911d toward the lower opening 1910 ″, and from the lower opening 1910 ″, the heat exchanger receiving portion 1312 is It falls toward the floor.

The bottom surface of the heat exchanger accommodating part 1312 is formed to be inclined downwards from the right to the left, and the condensed water dropped on the bottom of the heat exchanger accommodating part 1312 is the bottom surface of the heat exchanger accommodating part 1312 by gravity It moves downward along the line.

11 is a cross-sectional view taken along line B-B of FIG. 5.

Referring to FIG. 11, a longitudinal cross section of a water cover 1900 in a state in which the water cover 1900 is mounted on the heat exchanger accommodating portion 1312 is shown.

In Fig. 11, based on the direction in which the air is moved in the base flow path part 1310', the upstream side points to the front side, and the downstream side and the rear side are indicated.

When the clothing treatment apparatus 1000 is driven, condensed water is generated from air through heat exchange with the evaporator 1110.

The generated condensate flows along a plurality of inclined portions 1911a, 1911b, 1911c, 1911d and peripheral inclined portions 1912a, 1912b formed on the upper surface of the evaporator seating portion 1901, and the bottom surface of the heat exchanger receiving portion 1312 Is discharged.

The above-described height H1, the height H2 of the lower opening, and the height H3 of the upper opening described in FIG. 10 are formed in the same manner in the structure shown in FIG. 11, and the related description is given in FIG. Substitutes the described description.

The condensed water is moved by gravity along the first inclined portion 1911a and the second inclined portion 1911b toward the lower opening 1910 ″, and from the lower opening 1910 ″, the heat exchanger receiving portion 1312 is It falls toward the floor.

The bottom surface of the heat exchanger accommodating part 1312 is formed to be inclined downward from the front to the rear, and the condensed water dropped on the bottom of the heat exchanger accommodating part 1312 is the bottom surface of the heat exchanger accommodating part 1312 by gravity It moves downward along the line.

A blocking rib 1917 is formed on the lower surface of the evaporator seating part 1901. The blocking rib 1917 is formed to protrude downward from the lower surface of the evaporator seating portion 1901 and is formed along the width direction of the evaporator seating portion 1901.

The blocking ribs 1917 may be formed in plural along the longitudinal direction of the evaporator seating part 1901. The first, second and third blocking ribs 1917a, 1917b, and 1917c are sequentially arranged from the upstream side to the downstream side based on the direction in which the air moves in the base flow path part 1310'.

The lower ends of the first, second, and third blocking ribs 1917a, 1917b, and 1917c are located spaced apart from the bottom surface of the heat exchanger accommodating part 1312 by a predetermined distance. The bottom surface of the heat exchanger accommodating part 1312 is formed so as to be inclined downward from the upstream side to the downstream side. It is formed so as to gradually increase downward as it faces the side.

When condensed water begins to accumulate on the bottom surface of the heat exchanger accommodating part 1312, and the lower ends of the first, second and third blocking ribs 1917a, 1917b, 1917c are submerged in the condensed water, the lower side of the evaporator seating part 1901 The flow path through which air is moved is sealed.

Through this, the air discharged from the front opening of the drum is mostly heat-exchanged with the evaporator to discharge condensed water, and condensation efficiency of air can be improved.

Although the above has been described with reference to preferred embodiments of the present invention, those of ordinary skill in the art will variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can.

1900: water cover
1901: evaporator seat
1903: connection
1905: condenser seat
1907: support
1910: opening
1910': upper opening
1910'': lower opening
1911: slope
1911a: first slope
1911b: second slope
1911c: third slope
1911d: fourth slope
D1: first area
D2: second area
D3: third area
1912: peripheral slope
1912a, 1912b: peripheral slope
1917, 1957: blocking rib
1913: curved surface
1914: gate side
1915: Gigi Rib
1916: fixed rib
1916, 1956: fixed rib
1951: upward extension rib
1952: drainage hole
1310': base flow section
1710: circulation fan
DR1: first direction
DR2: second direction

Claims (15)

A drum for receiving clothing;
An evaporator located outside the drum;
A water cover located below the evaporator and supporting the evaporator; And
And a circulation passage forming a path through which the air discharged from the drum moves from one side of the evaporator toward the other side opposite to the one side,
The water cover,
An opening formed through the water cover in a vertical direction; And
It is formed around the opening and includes an inclined portion inclined downward toward the downstream side of the circulation passage,
Apparel handling device. The method of claim 1,
The opening is,
An upper opening through which condensed water formed from the air is introduced; And
It has a lower opening through which the introduced condensate is discharged,
The center of the lower opening is eccentric by a predetermined distance from the center of the upper opening to a downstream side of the circulation flow path,
Apparel handling device. The method of claim 1,
The inclined portion includes a first inclined portion and a second inclined portion sequentially positioned toward a downstream side of the circulation passage,
The first inclined portion is inclined more gently than the second inclined portion,
Apparel handling device. The method of claim 2,
The water cover includes a first area, a second area, and a third area sequentially positioned along a direction crossing a direction in which the air is moved,
The openings are formed in plural, and the plurality of openings are located in the second region,
In the first region and the third region, a peripheral inclined portion inclined upward toward the second region is formed,
Apparel handling device. The method of claim 4,
The evaporator is supported in line contact with the circumference of the plurality of upper openings,
Apparel handling device. The method of claim 4,
The plurality of openings are sequentially positioned toward a downstream side based on a direction in which air is moved in the circulation passage,
A first inclined portion and a second inclined portion sequentially positioned toward the downstream side are formed around the openings located on the downstream side of the plurality of openings,
A curved surface curved toward the downstream side is formed at the upper end of the second inclined part,
Apparel handling device. The method of claim 4,
In a portion where the first region and the third region are in contact with the second region,
Support ribs protrude to a predetermined length along a direction crossing the direction in which the air is moved,
The support rib supports the evaporator together with the circumference of the upper opening,
Apparel handling device. The method of claim 7,
The water cover,
An evaporator seat supporting the evaporator;
A condenser seating portion spaced a predetermined distance from the evaporator seating portion to a downstream side based on a direction in which air is moved in the circulation passage; And
And a connection part connecting the evaporator mounting part and the condenser mounting part,
The connection portion is formed in a plate shape having both sides parallel to the direction in which the air is moved,
Apparel handling device. The method of claim 8,
An upwardly extending rib protrudes along a direction crossing a direction in which the air is moved on a downstream side of the circulation passage of the condenser seating portion,
Apparel handling device. The method of claim 9,
A drain hole is formed in the condenser seating part,
The drainage hole is positioned to be spaced a predetermined distance from the upwardly extending rib toward the downstream side of the circulation passage,
Apparel handling device. The method of claim 10,
The laundry treatment apparatus further includes a base cabinet disposed under the drum and providing a heat exchanger accommodating part in which components constituting the flow path and the water cover are mounted,
A collecting part is formed on the bottom surface of the heat exchanger accommodating part at a position lower than the surrounding area so that the condensed water collects,
The inner circumferential surface of the heat exchanger accommodating part is formed to be inclined downward toward the collecting part,
Apparel handling device. The method of claim 11,
The water cover includes a plurality of support portions extending from the condenser seating portion and the evaporator seating portion toward the inner peripheral surface of the heat exchanger receiving portion,
Apparel handling device. The method of claim 12,
The evaporator seating portion and the condenser seating portion are formed with blocking ribs protruding downward along a direction crossing a direction in which the air is moved,
The lower end of the blocking rib is formed to be spaced apart a predetermined distance from the inner peripheral surface of the heat exchanger receiving portion,
Apparel handling device. A drum for receiving clothing;
An evaporator located outside the drum;
A circulation passage defining a path through which the air discharged from the front opening of the drum passes through the evaporator and moves to the rear opening of the drum;
A water cover located below the evaporator and supporting the evaporator; And
It includes a base cabinet that provides a space for accommodating the parts and the water cover constituting the circulation passage,
The water cover,
An upper opening through which condensed water generated from the air is introduced;
A lower opening through which the introduced condensed water is discharged; And
And an inclined portion connecting the circumference of the upper opening and the circumference of the lower opening,
The inclined portion,
With first and second inclined portions that are sequentially positioned and inclined downward based on a direction in which air is moved in the circulation passage,
Apparel handling device. The method of claim 14,
The first inclined portion is formed more gently than the second inclined portion,
Apparel handling device.

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