KR20220014623A - Laundry Treatment Apparatus - Google Patents

Abstract

The present invention relates to a laundry treatment apparatus in which a process of assembling a duct cover through which air discharged from a drum moves can be reduced and a washing unit for washing an evaporator can be mounted on the duct cover. The laundry treatment apparatus according to the present invention includes a cabinet, a drum, a circulation passage, a fan, a heat exchange unit, a moving unit, and a discharge unit.

Description

Laundry Treatment Apparatus

The present invention relates to a laundry treatment apparatus.

Recently, a clothes treatment device that performs a drying cycle capable of removing moisture from clothes has appeared. Conventional clothes treatment apparatuses supply hot air to a drum accommodating clothes to dry clothes, thereby greatly shortening the drying time of clothes, and sterilizing and sterilizing clothes.

A conventional laundry treatment apparatus may use an electric heater to supply hot air to the drum. By installing a heater in the duct communicating with the drum to heat the air flowing into the drum, it was possible to generate hot air.

Recently, a clothes treatment apparatus for heating the air flowing into the drum with a heat pump system has appeared. Such a clothes treatment apparatus can cool air discharged from clothes through an evaporator to condense moisture, and reheat the air through a condenser to generate high-temperature, dry hot air.

The laundry treatment apparatus having the heat pump system has advantages of higher energy efficiency, simple installation convenience, and easy repair and replacement than the laundry treatment apparatus using an electric heater.

However, in the conventional clothes treatment apparatus, there is a problem in that the air discharged from the clothes directly collides with the evaporator, so that foreign substances such as lint are attached to the evaporator. Foreign substances adhering to the evaporator interfere with heat exchange between the cold refrigerant flowing through the evaporator and the air discharged from the drum, thereby reducing drying efficiency.

In particular, when foreign substances remaining in the evaporator are corrupted by bacteria or the like, there is a problem in that even the clothes accommodated in the drum are contaminated.

Referring to Korean Patent Application Laid-Open No. 10-2012-0110498, a clothes treatment apparatus capable of washing the evaporator with water has appeared.

The clothes treatment apparatus was able to automatically remove foreign substances attached to the evaporator by supplying the water to the evaporator, thereby preventing the user from having to directly wash the evaporator.

1 is a view showing a duct structure of a conventional laundry treatment apparatus

A conventional laundry treatment apparatus has a base 3 on which a heat pump system can be mounted. The base 3 may be provided with a mounting portion 39 for installing a compressor, and one side of the mounting portion 39 includes an inlet duct 33 through which the air discharged from the drum flows, and the inlet duct 33 . ) may be provided with a heating duct 35 that is heated after the air introduced therein is cooled, and a supply duct 31 that supplies the air heated from the heating duct 35 to the drum.

An evaporator and a condenser may be accommodated in the heating duct 35 , and a cover 36 on which a moving part 6 for supplying water to the evaporator is installed may be provided.

The inlet duct 33 may include a guide duct 352 extending from the cover 36 to move air under the cover 36 .

The guide duct 352 may be provided separately from the cover 36 and disposed in front of the cover 36 . The guide duct 352 may collide with the water introduced from the moving unit 6 to guide the evaporator.

The guide duct 352 may include a suction duct 3521 forming a flow path through which the air moves, and a conversion rib 3522 extending downward from the suction duct 3521 to change the direction of movement of water. .

A washing pipe 631 , which guides water from the moving part 6 to the evaporator, is coupled to a washing hole 651 provided through the cover 36 . The water introduced into the washing hole 651 moves in the a direction toward the diverting duct 3522 . Thereafter, the water colliding with the conversion duct 3522 may move in the b direction and be guided to the surface of the evaporator.

As a result, the water moving in the a-direction collides in the diverting duct 3522 and then is temporarily stored in the diverting duct 3522 and spreads uniformly, so that it can be supplied in the b-direction. Accordingly, water may be uniformly supplied to the surface of the evaporator, and foreign substances adhering to the evaporator may be removed.

However, in the conventional clothes treatment apparatus, the guide duct 352 and the cover 36 are manufactured as separate components, and there is a cumbersome assembly of the guide duct 352 and the cover 36 separately.

In particular, there is a problem in that the air of the drum may leak into the portion where the guide duct 352 and the cover 36 are in contact.

An object of the present invention is to provide a laundry treatment apparatus capable of reducing the process of assembling a duct cover through which air discharged from a drum moves.

An object of the present invention is to provide a laundry treatment apparatus capable of mounting a washing unit capable of washing an evaporator on an upper portion of a duct cover through which air discharged from a drum moves.

An object of the present invention is to provide a laundry treatment apparatus capable of simplifying the production and assembly process of a duct.

An object of the present invention is to provide a laundry treatment apparatus having a discharge unit capable of supplying water evenly to the surface of an evaporator.

An object of the present invention is to provide a laundry treatment apparatus in which the discharge unit can be installed by being mounted on the duct cover.

An object of the present invention is to provide a laundry treatment apparatus capable of dispersing and supplying water supplied to the discharge unit over a wider area.

In order to solve the above problems, the present invention includes a cabinet forming an exterior, a drum accommodated in the cabinet for accommodating clothes, and a circulation passage provided to re-supply air discharged from the drum to the drum; A fan provided inside the circulation passage to move air, an evaporator installed inside the circulation passage to cool the air discharged from the drum, and a condenser spaced apart from the evaporator to heat the air A heat exchange unit, a moving unit coupled to the heat exchange unit or the circulation passage to move the water condensed in the evaporator, and a moving unit coupled to the moving unit to receive the water and discharge it to the evaporator to remove foreign substances attached to the evaporator It may include; a discharge unit to remove.

The discharge unit includes an inlet hole coupled to the moving unit to receive the water, and a discharge slit for discharging the water supplied from the inlet hole to the evaporator, wherein the inlet hole and the discharge slit face each other It may be arranged to be spaced apart so as to be blocked.

The discharge unit may further include a flow path body having the inlet hole on one side, the discharge slit on the other side, and providing a space for water to move. The discharge slit may be provided through one surface of the flow path body so that the water moving through the flow path body is discharged in a direction different from the moving direction.

The flow path body may include a moving duct for guiding the water introduced from the inlet hole to the outlet slit, and the moving duct may be provided to increase in width from the inlet hole to the outlet slit.

The flow path body may include a blocking surface for guiding to the discharge slit by collision of water moving along the moving duct.

The flow path body may further include a conversion duct extending from the distal end of the moving duct to the blocking surface.

The conversion duct may include an extended surface extending to the blocking surface at an angle different from an angle at which the moving duct extends from the inlet hole toward the discharge slit.

The conversion duct may include an extended surface provided so that both sides increase in width as it approaches the discharge slit.

The discharge unit may include a flow path control unit provided inside the flow path body to control the movement direction of the water.

The flow path control unit may include an inclined portion provided to be inclined so that the water introduced into the flow path body moves to the discharge slit.

The flow path control unit may include a curved portion provided with an inner surface of the flow path body bent so that the water introduced into the flow path body moves to both ends of the discharge slit.

The flow path control unit may include a plurality of partition ribs partitioning the inside of the flow path body.

The plurality of partition ribs may be provided such that a distance between one end toward the discharge slit is greater than a distance between the other ends.

The discharge unit may further include a step portion provided to protrude in the longitudinal direction of the discharge slit inside the flow path body.

The step portion may be provided to protrude from one surface of the discharge slit.

The discharge unit may include an extension duct extending from the flow path body to communicate with the discharge slit to discharge water supplied from the discharge slit.

The discharge unit further includes a flow path body having the inlet hole on one side and the discharge slit on the other side and providing a space for water to move, wherein the discharge slit is a direction in which water moving through the flow path body moves It may be provided through the free end of the flow path body so as to be discharged to the

The flow duct includes a moving duct for guiding the water introduced from the inlet hole to the discharge slit; A portion of the moving duct is bent and provided to include a bent portion provided to temporarily collect water moving the moving duct.

The flow path body may be provided parallel to an inlet surface through which air of the circulation path of the evaporator flows.

In order to solve the above problems, the present invention includes a cabinet forming an exterior, a drum accommodated in the cabinet for accommodating clothes, and a circulation passage provided to re-supply air discharged from the drum to the drum; A fan provided inside the circulation passage to move air, an evaporator installed inside the circulation passage to cool the air discharged from the drum, and a condenser spaced apart from the evaporator to heat the air A heat exchange unit, a moving unit coupled to the heat exchange unit or the circulation passage to move the water condensed in the evaporator, and a moving unit coupled to the moving unit to receive the water and discharge it to the evaporator to remove foreign substances attached to the evaporator It may include a discharge unit to remove.

The circulation passage may include a connection duct in which the evaporator and the condenser are accommodated and coupled, and a mounting duct coupled to an upper portion of the connection duct to shield the evaporator and the condenser and to which the washing unit is coupled.

The discharge unit may be mounted on the upper portion of the mounting duct.

The mounting duct may include a mounting cover coupled to the connection duct to shield the evaporator and the condenser, and a cover through-hole penetrating the mounting cover to expose at least a portion of the evaporator.

The discharge unit may include a flow path body coupled to the upper portion of the mounting cover to supply water to the cover through hole.

The discharge unit may include a flow path connector extending from the flow path body in parallel with the mounting cover, and the flow path body may be provided to guide the water supplied from the flow path connection pipe to the cover through hole.

The cover through hole may be provided in plurality along the width direction of the evaporator, and the flow path body may be provided in plurality to be coupled to the cover through hole, respectively.

The plurality of flow path bodies may be provided extending from the installation body coupled to the mounting cover.

The present invention has the effect of reducing the process of assembling the duct cover in which the air discharged from the drum moves.

The present invention has an effect that a washing unit capable of washing the evaporator can be mounted on the upper portion of the duct cover through which the air discharged from the drum moves.

The present invention has the effect of simplifying the production and assembly process of the duct.

The present invention has an effect of having a discharge unit that can supply water evenly to the surface of the evaporator.

The present invention has an effect that the discharge unit can be installed by being mounted on the duct cover.

The present invention has the effect of dispersing and supplying the water supplied to the discharge part over a larger area.

1 illustrates a duct structure of a conventional laundry treatment apparatus.
2 shows the structure of the laundry treatment apparatus of the present invention.
3 is a diagram showing the internal structure of the laundry treatment apparatus of the present invention.
4 is a view showing the structure of the base of the laundry treatment apparatus of the present invention.
5 is a view showing the function of the discharge unit of the laundry treatment apparatus of the present invention.
6 is a view showing an embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
7 is a view showing another embodiment of the structure of the discharge unit of the laundry treatment apparatus of the present invention.
8 is a view showing another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
9 shows another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
10 shows another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
11 shows another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
12 shows another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
13 shows another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
14 shows another embodiment of the structure of the discharge part of the laundry treatment apparatus of the present invention.
15 is a view showing the installation structure of the duct and the discharge part of the laundry treatment apparatus of the present invention.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the accompanying drawings. In this specification, even in different embodiments, the same and similar reference numerals are assigned to the same and similar components, and the description is replaced with the first description. As used herein, the singular expression includes the plural expression unless the context clearly dictates otherwise. In addition, in describing the embodiments disclosed in the present specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easy understanding of the embodiments disclosed in the present specification, and should not be construed as limiting the technical spirit disclosed herein by the accompanying drawings.

Hereinafter, a preferred embodiment of a laundry treatment apparatus and a control method thereof will be described in detail with reference to the accompanying drawings. The configuration or control method of the apparatus to be described below is only for explaining an example of the laundry treatment apparatus and the control method thereof, and is not intended to limit the scope of the invention, and the same reference numerals used throughout the specification refer to the same configuration. represents elements.

2 is a view showing the basic structure of the laundry treatment apparatus of the present invention.

As shown in FIG. 2 , the cabinet 1 includes a front panel 11 forming a front surface of the laundry treatment apparatus. The front panel 11 has an inlet provided to communicate with the drum 2 . 111 and a door 112 rotatably coupled to the cabinet to open and close the inlet 111 may be provided.

A control panel 117 is provided on the front panel 11, and the control panel 117 includes an input unit 118 for receiving a control command from a user, and a display unit 119 for outputting information such as a control command selectable by the user. ) may be provided, and a main control unit for controlling a command to perform a drying cycle of the laundry treatment apparatus may be installed.

The input unit 118 may include a power supply request unit for requesting power supply to the laundry treatment apparatus, a course input unit for allowing a user to select a desired course from among a plurality of courses, and an execution request unit for requesting the start of the course selected by the user. can be provided. The display unit 119 may be provided to include at least one of a display panel capable of outputting text and figures, and a speaker capable of outputting a voice signal and sound.

Meanwhile, the laundry treatment apparatus of the present invention may include a water storage unit 7 provided to separately store moisture generated during the drying of the clothes. The water storage part 7 may include a storage body 72 that is provided to be withdrawn from one side of the front panel 11 to the outside. The storage body 72 may be provided to collect the condensed water received from a washing pump to be described later. The user can remove the condensed water by withdrawing the storage body 72 from the cabinet 1 and then re-install it in the cabinet 1 . Accordingly, the laundry treatment apparatus according to the present invention may be freely disposed in a place where a sewer or the like is not installed.

Meanwhile, the laundry treatment apparatus of the present invention may further include a steam unit 200 capable of supplying steam to the clothes or the inside of the cabinet. The steam unit 200 may be provided to generate steam by receiving fresh water instead of condensed water. The steam unit 200 may be provided to generate steam by heating the water, using ultrasonic waves, or vaporizing it.

Since the steam unit 200 is provided to generate steam by receiving a predetermined amount of water, it may occupy a predetermined volume. At this time, the front panel 11 of the cabinet is provided with a door and a control panel 117, and the rear panel 12 of the cabinet is provided with a duct for supplying or discharging air to the drum, a water supply unit, etc., so that the steam unit 200 may be advantageously installed on the side panel 14 of the cabinet.

In addition, the laundry treatment apparatus of the present invention may include a steam control unit 800 provided to separately control the steam unit 200 . The steam control unit 800 may be installed on the control panel 117 , but may be provided as a separate control panel to prevent overload of the control panel 117 and increase the production cost.

The steam control unit 800 may be provided adjacent to the steam unit 200 . The steam control unit 800 is provided on the side panel 14 on which the steam unit 200 is installed to reduce the length of a control line connected to the steam unit 200 .

Since the steam unit 200 supplies steam that can come into contact with the clothes, it is preferable to generate steam with fresh water. Since the water collected in the water storage unit 7 is generated from clothes, it is highly likely that lint or foreign substances are contained therein, and thus may not be suitable for generating the steam.

Accordingly, the laundry treatment apparatus of the present invention supplies water to the steam unit 200 , but may include a water supply unit 300 provided separately from the water storage unit 7 . The water supply unit 300 may be provided to store fresh water or to supply the fresh water to the steam unit 200 by receiving the fresh water from the outside.

For example, the water supply unit 300 stores fresh water separately from the external supply unit 500 that can receive water from an external water supply source and deliver it to the steam unit 200 and supply it to the steam unit 200 . It may include an internal supply unit 400 that can.

The internal supply unit 400 includes a water tank 420 provided separately from the water storage unit 7 to store fresh water, and water provided to supply the water from the water tank 420 to the steam unit 200 . It may further include a pump 430 and a tank housing 410 for seating the water tank 420 and the water pump 430 inside the cabinet.

In the laundry treatment apparatus of the present invention, the water tank 420 and the steam unit 200 have a difference in installation height, so that the water in the water tank 420 is supplied to the steam unit 200 by its own weight. may be

When the difference in installation height between the water tank 420 and the steam unit 200 cannot be ensured, it may be preferable to additionally install the water pump 430 . In addition, when the water pump 430 is additionally disposed, there is an advantage that the space inside the cabinet 1 can be more densely utilized.

The external supply unit 500 may include a direct water valve 520 connected to the external water supply source to receive water.

In addition, the laundry treatment apparatus of the present invention may further include a determining unit 700 that determines whether to supply water to the steam unit 200 by preferentially using either the external supply unit 500 or the internal supply unit 400 . can The determining unit 700 may be structurally provided to determine which one of the external supply unit 500 and the internal supply unit 400 is to be used preferentially.

Meanwhile, the water tank 420 may be provided to store fresh water. The water tank 420 is preferably provided to be exposed to the outside of the cabinet 1 so that fresh water can be frequently charged.

However, since the water tank 420 is also provided to store water and the water reservoir 7 is also provided to store water, users may be confused. To this end, in the laundry treatment apparatus of the present invention, the direction or position in which the water tank 420 and the water reservoir 7 are exposed from the cabinet may be different. For example, the water tank 420 may be provided to be exposed through the upper panel 13 , and the water reservoir 7 may be provided to be exposed through the front panel 11 . Accordingly, even if both the water tank 420 and the water storage unit 7 are provided, it is possible to prevent user confusion.

Since the water tank 420 must store fresh water and the freshness of the stored water must be maintained, the water tank 420 may have a relatively smaller volume than the water storage unit 7 . Accordingly, the user can distinguish the water tank 420 from the water storage unit 7 by the volume difference.

Since the water tank 420 has a smaller volume than the water storage part 7 , it may be easily withdrawn to the upper part. Accordingly, the water tank 420 may be provided to be withdrawn from the upper panel 13 upwardly. As a result, since the withdrawal directions of the water tank 420 and the water storage unit 7 are different from each other, the possibility of user confusion may be further reduced.

The upper panel 13 of the laundry treatment apparatus of the present invention may include a tank withdrawing hole 131 provided so that the water tank 420 is exposed to the outside or the water tank 420 can be withdrawn to the outside of the cabinet. have. The tank take-out hole 131 may correspond to the cross-sectional area of the water tank 420 or may be provided slightly larger than the area of the water tank 420 .

The upper panel 13 may further include a pull-out cover 132 provided to shield the tank take-out hole 131 to prevent the water tank 420 from being arbitrarily drawn out. The pull-out cover 132 may include one or more panel coupling portions 1321 provided to be coupled to the outer peripheral surface of the tank take-out hole 131 . The panel coupling part 1321 may be provided extending from one side of the pull-out cover 132 to rotatably couple the pull-out cover 132 to the upper panel 13 . The panel coupling part 1321 and the upper panel 13 may be coupled to each other by a hinge coupling method.

On the other hand, the pull-out cover 132 may be provided with a panel handle 1323 that can be gripped by a user on the surface, and the panel handle 132 is a groove provided concavely downward from the pull-out cover 132 . can be provided. In addition, the pull-out cover 132 may further include a panel fixing part 1332 that is detachably coupled to the upper panel 13 or the outer peripheral surface of the tank take-out hole 131 . The panel fixing part 1332 may be coupled to the upper panel 13 or the tank withdrawal hole 131 by a push button method.\

The laundry treatment apparatus of the present invention may further include a filter capable of removing foreign substances from the circulated air. The front panel 11 may be provided with a filter mounting hole 113 provided so that the filter is drawn out or inserted.

3 is a view showing the internal configuration of the laundry treatment apparatus of the present invention.

As shown in FIG. 3 , the clothes treatment apparatus 100 includes a cabinet 1 , a drum 2 rotatably provided inside the cabinet to provide a space for storing clothes, and discharge from the drum 2 . A duct (3) forming a flow path for re-supplying the exhausted air to the drum (2), and a heat exchange unit (4) for dehumidifying and heating the air introduced into the duct (3) and then re-supplying it to the drum (2) includes

When the drum 2 is provided with a cylindrical drum body 21 having an open front surface and a rear surface, respectively, in the cabinet 1, a first rotatably supporting front surface of the drum 2 is provided. A support portion 17 and a second support portion 19 for rotatably supporting the rear surface of the drum 2 may be provided.

The first support part 17 is provided to penetrate the first fixed body 171 fixed inside the cabinet 1 and the first fixed body to communicate the inlet 111 and the inside of the drum body 21 . It may be provided to include a drum inlet 173, a first support body 175 that is provided on the first fixed body 171 and is inserted into the front surface (first open surface) of the drum body 21 . .

The first fixed body 171 may be provided in any shape as long as the drum inlet 173 and the first support body 175 can be provided. The first support body 175 may be provided in the shape of a pipe protruding from the first fixed body 171 toward the drum body 21, and the diameter of the first support body 175 is the drum inlet. It may be set larger than the diameter of 173 and smaller than the diameter of the front surface of the drum body 21 . In this case, the drum inlet 173 will be located inside the space formed by the first support body 175 .

The first support unit 17 may be provided to further include a connecting body 177 connecting the inlet 111 and the drum inlet 173 . The connection body 177 may be provided in the shape of a pipe extending from the drum inlet 173 toward the inlet 111 . The connection body 177 may be provided with an air outlet 178 communicating with the duct 3 . As shown in FIG. 3 , the air outlet 178 is a passage that allows the air inside the drum body 21 to move to the duct 3 , and is provided to pass through the connection body 177 . It may be provided alone.

The second support part 19 is provided on the second fixed body 191 fixed inside the cabinet 1 and the second fixed body 191 to the rear surface (second open surface) of the drum body 21 . ) may be provided to include a second support body 195 inserted in. The second support part 19 is provided with an air inlet 198 provided to pass through the second fixed body 191 to communicate the inside of the drum body 21 with the inside of the cabinet 1 . In this case, the duct 3 may be provided to connect the air outlet 178 and the air inlet 198 .

The drum body 21 having an empty cylindrical shape can be rotated through various types of driving units, and FIG. 3 shows a motor 23 in which the driving unit 28 is fixed inside the cabinet 1, and is rotated by the motor. A case in which the pulley 25 is provided to include a belt 27 connecting the circumferential surface of the pulley 25 and the circumferential surface of the drum body 21 is illustrated as an example.

In this case, the first roller 179 for rotatably supporting the circumferential surface of the drum body 21 is provided on the first support part 17 , and the second support part 19 has the peripheral surface of the drum body 21 . A second roller 199 for rotatably supporting the may be provided.

The duct 3 includes an exhaust duct 31 connected to the air outlet 178, a supply duct 33 connected to the air inlet 198, and a connecting duct 35 connecting the exhaust duct and the supply duct. can be provided to do so.

The heat exchange unit 4 may be provided with various devices as long as possible sequentially dehumidifying and heating the air introduced into the duct 3 . For example, the heat exchange unit 4 may be provided as a heat pump system.

The heat exchange unit 4 includes a fan 49 that moves air along the duct 3, a first heat exchanger that removes moisture from the air introduced into the duct 3 (heat absorbing unit 41), and the It may include a second heat exchanger (heating unit, 43) provided inside the duct (3) to heat the air that has passed through the first heat exchanger (41).

The fan 49 may be provided to include an impeller 491 provided inside the duct 3 and an impeller motor 493 for rotating the impeller 491 . (See FIG. 4) The impeller 491 may be provided in any of the exhaust duct 31, the connection duct 35, and the supply duct 33, FIG. 3 shows that the impeller 491 is the supply duct ( 33) is illustrated as an example (when it is located at the rear of the heating unit).

The evaporator 41 is provided with a plurality of metal plates disposed along the width direction (Y-axis direction) of the connection duct 35 or the height direction (Z-axis direction) of the connection duct, and the condenser 43 is the It may be provided with a plurality of metal plates disposed along the width direction of the connection duct or the height direction of the connection duct. The evaporator 41 and the condenser 43 are sequentially disposed along the direction from the exhaust duct 31 to the supply duct 33 inside the connection duct 35, forming a circulation flow path of the refrigerant They are connected to each other through a refrigerant pipe (48). (See Fig. 4)

The refrigerant moves along the refrigerant pipe 48 by the compressor 45 located outside the duct 3 , and the refrigerant pressure of the refrigerant passing through the condenser 43 is adjusted in the refrigerant pipe 48 . A pressure regulator 47 is provided.

The evaporator 41 is a means for cooling the air and evaporating the refrigerant by transferring the heat of the air introduced into the exhaust duct 31 to the refrigerant. The condenser 43 transfers the heat of the refrigerant that has passed through the compressor 45 to the air, thereby heating the air and condensing the refrigerant. In this case, when the moisture contained in the air passes through the evaporator 41 , it will be collected on the bottom surface of the connection duct 35 along the surface of the evaporator 41 .

In order to collect the water removed from the air passing through the evaporator 41 , the laundry treatment apparatus 100 is provided with a water collecting unit.

The water collected in the water collecting unit may be collected in the water storing unit 7 and provided so that it can be discharged at a later time. The water storage part 7 is provided to pass through the storage body 72, which is detachably provided in the cabinet 1 to provide a space for storing water, and the storage body 72, and the water storage part supply pipe 633. It may be provided to include an inlet 722 for introducing water discharged from the storage body 72 into the interior.

The storage body 72 may be provided as a drawer-type tank drawn out from the cabinet 1 . In this case, the storage body 72 is inserted into the storage unit mounting hole in the front panel 11 of the cabinet. This should be provided A panel 71 is fixed to the front surface of the storage body 72 , and the panel 71 may be detachably coupled to the water reservoir mounting hole to form a part of the front panel 11 . .

The panel 71 may further include a groove 711 into which a user's hand is inserted. In this case, the panel 71 will also perform the function of a handle for withdrawing or inserting the storage body 72 from the cabinet.

The inlet 722 may be provided to receive water discharged from the nozzle 722a fixed to the cabinet 1 . The nozzle 722a may be fixed to the upper panel 13 of the cabinet so that it is positioned above the inlet 722 when the storage body 72 is inserted into the cabinet 1 .

The water storage unit 7 having the above-described structure is inverted or tilted toward the direction in which the inlet 722 is located after the user withdraws the storage body 72 from the cabinet 1 . Accordingly, the water inside the storage body 72 can be discarded. A communication hole 721 provided to penetrate the upper surface of the storage body 72 may be further provided so that the water inside the storage body 72 is easily discharged through the inlet 722 .

The steam unit 200 may be disposed to be spaced apart from the water storage unit 7 . As described above, the steam unit 200 may be connected to the internal water supply unit 400 and the external water supply unit 500 to receive water and form steam. The external water supply unit 500 includes a direct water valve 520 adjacent to or fixed to the rear panel 13 , and water transferred from the direct water valve 520 to the steam unit 200 . It may include a direct water pipe 510 for supplying. The direct water valve 520 may be provided to be coupled to an external water supply source. For example, the direct water valve 520 may be coupled to a water supply pipe extending to the rear surface of the cabinet. Accordingly, the steam unit 200 may be provided to receive water directly through the direct water valve 520 . Therefore, even if the internal water supply unit 400 is omitted or water is not stored in the internal water supply unit 400 , the steam unit 200 supplies water through the direct water valve 520 whenever necessary. can receive The direct water valve 520 may be directly controlled by the steam control unit 800 .

Meanwhile, the steam unit 200 may be provided adjacent to the direct water valve 520 . Accordingly, it is possible to prevent unnecessary residual water from remaining in the direct water pipe 510, and water can be supplied immediately when necessary.

The internal water supply unit 400 includes a water tank 420 for storing water, a water pump 430 for supplying water to the steam unit 200 by receiving water from the water tank 420 , and the water A tank 420 and a tank housing 410 providing a space for seating the water pump 430 may be included. The water pump 430 and the water tank 420 may be provided at a height corresponding to the steam unit 200 . The tank take-out hole 131 may be installed in a region corresponding to a portion of the upper panel 13 where the water tank 420 is installed. Accordingly, it is possible to prevent the water pump 430 from being unnecessarily exposed to the tank withdrawal hole 131 as much as possible. The withdrawal cover 132 is rotatably coupled to the outer peripheral surface of the tank withdrawal hole 131 to prevent the water tank 420 from being unnecessarily exposed to the outside.

The steam unit 200 may receive water through the water supply unit 300 , generate steam, and then supply it to the drum 2 or the duct 3 through the steam discharge pipe 213 . The steam discharge pipe 213 may directly communicate with the drum 2 to supply the steam into the drum 2 , and communicate with the duct 3 or the second support unit 19 to communicate with the drum 2 . ) can indirectly supply steam to the inside.

When the steam discharge pipe 213 is connected to the duct 3, it may be provided in communication with the supply duct 33, and when it is connected to the second support part 19, it is communicated with the air inlet 19 can be provided. Accordingly, the steam can be more smoothly introduced into the drum 2 by using the power of the blowing fan 49 .

The steam unit 200 may be controlled to generate steam when a steam supply mode using steam is performed during the drying cycle. The steam supply mode may correspond to a series of drying courses for sterilizing the clothes, increasing the temperature inside the drum during the drying cycle of the clothes, or removing wrinkles from the clothes at the end of the drying cycle of the clothes. . The steam unit 200 may be controlled to supply steam to the inside of the drum 2 by receiving water through the external water supply unit 500 as well as the internal water supply unit 400 as needed.

Meanwhile, the heat exchange unit 4 is provided to condense moisture in the air circulating in the evaporator 41 . Accordingly, even if the air circulates through the drum 2 , moisture is removed from the evaporator 41 , so that the clothes inside the drum 2 can be continuously dried.

The moisture condensed in the evaporator 41 may be primarily collected in the water collecting unit 37 and then may be secondarily collected in the water storing unit 7 . The water collecting part 37 may be located inside the connection duct 35 , and may be separately provided in a space spaced apart from the connection duct 35 .

3 and 4 show an embodiment in which the water collecting unit 37 may be provided inside the connection duct 35, but this is for illustration only. The water collecting unit 37 collects condensed water If possible, it may be provided in any structure.

The water collecting unit 37 may be provided as a water collecting body 371 that is fixed to the bottom surface of the connecting duct 35 and communicates with the inside of the connecting duct. A heat exchanger support 372 may be further provided inside the water collecting body 371 so that the heat absorbing and heat generating portions 41 and 43 do not come into contact with the water (condensate) stored in the water collecting body 371 . The heat exchanger support part 372 is a spacer ( 375), and a support plate through hole 376 provided to pass through the support plate 373 may be provided.

The support plate through-hole 376 may be provided only in a space in which the evaporator 41 is supported among the spaces provided by the support plate 373, and may be provided in a space in which the heat absorbing part is supported and a space in which the heat generating part is supported, respectively. may be If the support plate through hole 376 is also provided in the lower part of the condenser 43, the water that has moved to the condenser 43 along the support plate 373 will be able to be discharged to the water collecting body 371 (the heat generating part is in the water). to prevent deterioration of heat transfer efficiency that occurs when contacting).

In order to minimize the accumulation of foreign substances (lint, etc.) discharged from the drum body 21 on the evaporator 41 and the condenser 43 , the laundry treatment apparatus 100 may further include a filtering unit for filtering air. can

The second filtering unit 8 is provided as a means for filtering the air flowing into the exhaust duct 31 from the drum body 21 , and the first filtering unit 5 is the second filtering unit 8 ) and located between the evaporator 41 and may be provided as a means for filtering the air passing through the second filtering unit. The diameter of the filtration hole provided in the first filtration unit 5 may be set smaller than the diameter of the filtration hole provided in the second filtration unit 8 .

The second filtering unit 8 includes a frame 81 that is detachably inserted into the exhaust duct 31 through the air outlet 178, and a filter (fourth filter, 83) provided in the frame to filter air. ) can be provided.

The first filtering unit 5 may be detachably provided in the connection duct 35 . In this case, the front panel 11 of the cabinet is provided with a filter mounting hole 113 (refer to FIG. 1) from which the first filter unit 5 is drawn out and a mounting hole door 114 for opening and closing the filter mounting hole, and , the duct 3 may be provided with a duct through hole 34 (refer to FIG. 3 ) into which the first filtering unit 5 is inserted. Accordingly, the user can remove the foreign substances remaining in the first filter unit 5 and wash the first filter unit after separating the first filter unit 5 from the laundry treatment apparatus if necessary.

The first filter unit 5 is inserted into the filter mounting hole 113 and the duct through hole 34 and is positioned between the second filter unit 8 and the evaporator 41. The filter body 51, 53, 57, 58), and filters 531, 551, 571 that are provided in the filter body and filter the fluid (air and water) moving to the evaporator 41 and the water collecting body 371. can be

The filter body may be provided in various shapes depending on the shape of the cross-section (YZ plane, and XZ plane) of the connection duct 35, FIG. 1 shows a case in which the filter body is provided in a shape similar to a hexahedron. It is shown as an example.

In this case, the filter body has a front surface 51 provided in a shape capable of closing the duct through hole 34 , a rear surface 53 positioned between the front surface and the evaporator 41 , and the front surface It may be provided to include a bottom surface 55 provided to connect the rear surface and a first side surface 57 and a second side surface 58 forming the left and right surfaces of the filter body.

A lock 513 that is detachably coupled to the lock fastening unit 16 provided in the cabinet may be provided on the front surface 51 . The lock 513 is provided as a bar rotatably coupled to the front surface 51 of the filter body, and the lock fastening part 16 forms a groove in which the free end of the bar is accommodated. can be provided.

Preferably, the locks 513 are respectively provided on opposite sides of the front surface 51 , and the lock fastening parts 16 are respectively provided on opposite sides of the filter mounting hump 113 .

A handle 511 may be further provided on the front surface 51 to facilitate insertion of the filter body into the connection duct 35 or separation from the connection duct 35 .

A first filter 531 and a second filter 551 for filtering the fluid (air and water) introduced into the body of the filter unit may be provided on the rear surface 53 and the bottom surface 55, respectively. . The rear surface 53 is provided with a rear surface through hole for communicating the inside of the filter body with the inner space of the duct 3 , and the first filter 531 is provided in the rear surface through hole. The bottom surface 55 is provided with a bottom surface through-hole for communicating the inside of the filter body with the inner space of the duct 3 , and the second filter 551 is provided in the bottom surface through-hole. Accordingly, the first filter 531 serves as a means for filtering the fluid (air and water) supplied to the evaporator 41 , and the second filter 551 filters the fluid supplied to the water collecting body 371 . It is a means of filtering.

The first side 57 and the second side 58 may be provided to connect the front surface 51 , the rear surface 53 , and the bottom surface 55 .

The first filter unit 5 having the above-described structure may be provided to communicate with the exhaust duct 31 through the upper surface or the second side surface 58 of the filter unit body.

The first filter unit 5 may be connected to the exhaust duct 31 through an upper surface through-hole provided to penetrate the upper surface of the filter body and a side through-hole provided to penetrate the second side surface 58 have.

The first filter 531 may be inclined at 90 degrees to 100 degrees toward the front surface of the evaporator 41 with respect to the bottom surface 55 of the filter body. This is to allow foreign substances remaining in the first filter to easily move to the bottom surface 55 when water is sprayed onto the first filter 531 through a moving part 6 to be described later.

The second filter 551 may be provided inclined downward by 10 to 20 degrees from the front surface 51 toward the first filter 531 (the second filter has a filter mounting hole at the lower end of the first filter). It may be provided inclined upward by 10 to 20 degrees toward the direction in which it is located). When the second filter 551 is provided to be inclined downward toward the first filter 531, the connection point between the first filter 531 and the second filter 551 is the lowest point in the space provided by the first filter unit. Therefore, the foreign substances of the first filter unit 5 may be concentrated at the connection point between the first filter 531 and the second filter 551 . When the foreign material is concentrated at the connection point between the first filter 531 and the second filter 551 , the user will be able to more easily remove the foreign material inside the first filter unit 5 .

However, when foreign substances are concentrated at the connection point between the first filter 531 and the second filter 551 , a long time is required for the water sprayed through the moving part 6 to be discharged to the water collecting body 371 . This can happen. In order to solve this problem, as shown in FIG. 1 , the first side 57 has a bypass hole for communicating the inside of the first filtration unit 5 with the zip body 371 and the bypass A third filter 571 provided in the hole may be further provided. 3 , the bypass hole and the third filter 571 may be provided at a position higher than the uppermost end of the second filter 551 and lower than the uppermost end of the first filter 531 . Accordingly, the laundry treatment apparatus can minimize a phenomenon in which the water sprayed to the first filter unit 5 is not recovered to the water collecting body 371 due to foreign substances remaining in the first filter unit 5 .

On the other hand, the laundry treatment apparatus 100 includes a moving unit 6 using water stored in the water collecting body 371, and coupled to the moving unit 6 to receive the water and receive the water from the evaporator 41 or the second unit. 1 may include a discharge unit 900 for washing the filter unit (5).

The water stored in the water collecting body 371 may be separately collected by the water storage unit 7 or may be selectively moved to the moving unit 6 .

The moving unit 6 injects the water stored in the water collecting body 371 to the first filtration unit 5, so that the first filter 531, the second filter 551, the third filter 571, And it may be provided as a means for moving the water for washing at least one of the evaporator (41).

The moving unit 6 may be provided in the duct 3 to supply water to the discharge unit 900 that supplies water to the first filtering unit 5 or the evaporator 41 . The moving unit 6 may be provided to include a washing pump 61 for moving the water stored in the water collecting body 371 to the discharging unit 900 .

The washing pump 61 may be connected to the water collecting body 371 through a first connection pipe 611 , and may be connected to the discharge unit 900 through a second connection pipe 613 . If the laundry treatment apparatus is provided to move the water in the water collecting body 371 to the discharge unit 900 and the water storage unit 7 using only one washing pump 61 , the laundry treatment apparatus 100 has a flow path. A conversion unit 63 may be further provided. In this case, the flow path switching unit 63 is connected to the washing pump 61 through the second connection pipe 613 , and the discharge unit 900 is connected to the flow path switching unit through the injection unit supply pipe 631 . It is connected to 63 , and the water storage unit 7 may be provided to be connected to the flow path conversion unit 63 through a water storage unit supply pipe 633 .

In this case, the water storage part supply pipe 633 should be provided to connect the nozzle 722a and the flow path switching part 63 .

A valve for controlling the opening and closing of the injection unit supply pipe 631 and the opening and closing of the water storage unit supply pipe 633 is provided in the flow path switching unit 63 . Accordingly, the laundry treatment apparatus 100 may supply the water stored in the water collecting body 371 to the discharge unit 900 by controlling the valve provided in the flow path switching unit 63 , and the water storage unit 7 ) can also be supplied.

The injection part supply pipe 631 may be coupled to the connection duct 35 , and may be coupled to one surface corresponding to the upper surface of the evaporator 41 . Accordingly, the water supplied to the injection unit supply pipe 631 is discharged to the evaporator 41 or the first filter unit 5, and foreign substances attached to the evaporator 41 or the first filter unit 5 are removed. can be

Meanwhile, the moving unit 6 may be provided to receive fresh water directly from the water supply unit 300 as well as the water condensed in the evaporator 41 . In this case, a pipe directly connecting the water supply unit 300 and the moving unit 6 may be provided. For example, a separate pipe connecting the steam unit 200 and the moving unit 6 may be further provided.

On the other hand, the laundry treatment apparatus of the present invention is preferably provided to include a water collecting unit water level detecting unit 91 that measures the water level of the water collecting body 371 and transmits it to the control unit. When the water collection unit water level detection unit 91 is provided, the clothes treatment apparatus can determine when to move the water stored in the water collection body 371 to the storage body 72 , and through this, the water collection body 371 can be determined. ) of water can be prevented from flowing back into the connection duct (35).

The water level sensing unit 91 of the water collecting unit may be provided with any device as long as it can detect the water level inside the water collecting body 371, and FIG. 3 shows a plurality of electrodes having different lengths (electrical according to the water level). A sensor provided with a plurality of electrodes connected to each other is shown as an example.

In order to determine when the operation of the heat exchange unit 4 is stopped by determining the degree of dryness of the clothes, the clothes treatment apparatus 100 may be provided with a dryness detection unit. The dryness detection unit is provided in contact with the clothes and includes an electrode sensor 95 for measuring the amount of moisture contained in the clothes, and a humidity sensor for measuring the humidity of air flowing from the drum 2 into the duct 3 . At least one of them may be provided.

The electrode sensor may be provided to include a first electrode 951 and a second electrode 953 that are fixed to the first fixed body 171 and can contact clothes inside the drum body 21 . As the drying level increases, the amount of moisture contained in the clothes will decrease (electrical resistance of the clothes increases), so by observing the electrical resistance measured when the two electrodes 951 and 953 are connected through the clothes, the clothes treatment apparatus ( 100) can determine the dryness of the clothes. On the other hand, since the amount of moisture contained in the air flowing into the duct 3 will decrease as the drying degree of the clothes increases, the clothes treatment apparatus 100 controls the amount of air introduced into the duct 3 through the humidity sensor. It is also possible to judge the dryness of the clothes by observing the humidity.

In addition, the clothes treatment apparatus 100 may further include a temperature sensing unit 96 for measuring the temperature of the air introduced into the duct 3 . The temperature sensing unit 96 may be fixed to the upper surface of the connection duct 35 and positioned between the first filter 531 and the second filter 551 .

4 shows an embodiment in which the connection duct 35 and the water collecting part 37 are provided on the bottom surface of the laundry treatment apparatus of the present invention.

Referring to FIG. 4A , the laundry treatment apparatus of the present invention may further include a base 39 forming the duct 3 and on which the heat exchange unit 4 can be installed.

A part of the exhaust duct 31 may be installed in the base 39 , and the exhaust duct 31 and the supply duct 33 may be installed at both ends of the connection duct 35 .

The evaporator 41 and the condenser 43 may be installed in the connection duct 35 .

The base 39 may include a device installation part 392 in which a device such as a compressor can be installed on one side of the connection duct 35 .

The device installation unit 392 includes a compression installation unit 393 in which the compressor 45 can be installed, a fan installation unit 391 in which the blowing fan can be mounted, and a driving unit in which the driving unit can be installed. It may include an installation part 392a.

Meanwhile, the device installation unit 392 may further include the water collecting unit 37 . The water collecting part 37 may not be provided under the connection duct 35 , but may be disposed separately from one side of the connection duct 35 by a partition wall 38 .

4(b), the connection duct 35 may include a heat absorption mounting part 372 to which the evaporator 41 can be installed, and a heat generating mounting part 523 to which the heat generating part can be mounted. .

As the drying process proceeds, when the heat supply unit 4 is driven, the air passing through the evaporator 41 is cooled and the moisture contained therein is condensed. When the moisture is condensed, water may accumulate in the vicinity of the heat absorbing part 372 as shown.

The lower surface of the connection duct 35 may be provided to have a lower height toward the water collecting part 37 . The partition wall 38 is provided to block the air flowing through the connection duct 35 from moving to the device mounting part 392, but a communication hole ( 381) may be included.

The water condensed through the communication hole 381 may move to the water collecting unit 37 to be collected in the water collecting unit 37 . The washing pump 61 may be installed in the water collecting part 37 . To this end, the water collecting unit 37 may further include a pump fixing unit 535 on which the washing pump 61 is seated and fixed. The pump fixing part 535 may be provided to separate the bottom surface of the washing pump 61 and the water collecting part 37 by a predetermined distance.

Accordingly, when sufficient water is collected in the water collecting unit 37, the washing pump 61 may be driven to remove it. The flow path switching unit 63 may be controlled to spray the supplied water to the discharge unit 900 or to move it to the water storage unit 7 .

In addition, the water sprayed from the discharge unit 900 to wash the evaporator 41 may also be re-introduced into the water collecting unit 37 and controlled to move back to the water storage unit 7 .

At this time, the moving direction of the air may be set in the opposite direction according to the fan driving. In this case, the positions of the evaporator 41 and the condenser 43 are changed, and the exhaust duct 31 serves as the supply duct 33 and the supply duct 33 serves as the exhaust duct 31 . can do.

5 is a view showing the function of the discharge unit of the laundry treatment apparatus of the present invention.

The evaporator 41 and the condenser 43 may include a plurality of heat exchange fins (P). The plurality of heat-bridged pins (P) are spaced apart from each other by a predetermined distance so that air can move therebetween.

On the other hand, since the evaporator 41 is disposed upstream of the flow path than the condenser 43 , the foreign substances discharged from the drum may be intensively attached to the heat exchange fins P of the evaporator 41 , and in particular, the heat exchange It can be most attached to the inlet surface of the pin (P).

Accordingly, the laundry treatment apparatus of the present invention may further include a discharge unit 900 coupled to the moving unit 6 to move water to the evaporator 41 to remove foreign substances.

Of course, when the first filter unit 5 is provided, the discharge unit 900 can supply water only to the first filter unit 5, and the first filter unit 5 and the evaporator 41 ) can be provided to supply water to all. Supplying water to the evaporator 41 by the discharge unit 900 may include supplying water to the first filtering unit 5 .

Hereinafter, it will be mainly described that the discharge unit 900 supplies water to the evaporator 41 , but supplying water to the first filter unit 5 may also be applied in the same principle.

The discharge part 900 may be provided by being fixed to the connection duct 35 , and may be fixedly coupled to an end of the discharge part 900 .

The discharge unit 900 may be provided to intensively supply water to one surface of the evaporator 41 that can first come into contact with the air discharged from the drum. That is, since most foreign substances are attached to the inlet surface of the evaporator 41, intensively supplying water to the inlet surface may have the highest cleaning efficiency. For example, when the air is introduced into the front surface of the evaporator 41 , the discharge unit 900 may be provided to supply water to the upper front surface of the evaporator 41 . Accordingly, a large amount of foreign substances attached to the inlet surface of the evaporator 41 can be washed away.

The discharge part 900 may be provided in the shape of a nozzle or may be provided in the shape of a diffuser.

The outlet 900 has an outlet area wider than the inlet area to induce water to spread widely, so that water can be evenly sprayed onto the inlet face of the evaporator 41 . As a result, water can be uniformly supplied to the entire cooling fins P attached to the evaporator 41 in multiple layers.

However, even if the width of the outlet t1 of the outlet 900 is greater than the width t2 of the inlet, the water discharged from the outlet 900 automatically expands to the outlet width t1. doesn't happen Therefore, the water in the discharge part 900 does not spread evenly over the surface of the evaporator 41, and there is a large possibility that the water is discharged as it is with the introduced width t2.

Also, the discharge unit 900 may be disposed on the upper surface of the evaporator 41 . That is, the water discharged from the discharge unit 900 may be induced to be supplied to the evaporator 41 by its own weight.

However, as the liquid moves, the faster the flow rate, the narrower the diameter becomes. Therefore, the width t2 of the water passing through the discharge unit 900 may become narrower as it goes away from the discharge unit 900, and the water w may not be evenly supplied to the surface of the evaporator 41. have. As a result, all foreign substances adhering to the surface of the evaporator 41 may not be completely removed.

Accordingly, in the laundry treatment apparatus of the present invention, the water supplied from the discharge unit 900 may be uniformly sprayed on the surface of the evaporator 41 to remove all foreign substances.

6 is a view showing the structure of the discharge part of the laundry treatment apparatus of the present invention.

The discharge unit 900 may be set so that the direction in which water flows in and the direction in which water flows out are different.

The discharge unit 900 is provided so that the introduced water is sprayed with a direction changed, so that the introduced water may be guided to move along the inner surface of the discharge unit 900 .

As a result, it is possible to prevent the introduced water from falling freely or being discharged without contact with the surface of the discharge unit 900 , and is in contact with the inner surface of the discharge unit 900 to follow the surface of the discharge unit. It can lead to dispersion.

Accordingly, when the outlet of the discharge unit 900 has a larger area than the inlet of the discharge unit 900 , the water introduced into the discharge unit 900 may be discharged over a larger area than the introduced area. .

Referring to FIG. 6( a ), the discharge part 900 is coupled to a flow path connector 930 coupled with the moving part 6 to receive water, and is coupled to the flow path connector 930 to move water. It may include a euro body 920 that

The flow path connection pipe 930 may be coupled to the upper surface with respect to the longitudinal direction of the flow path body 920 . Accordingly, the water flowing into the flow path body 920 may be induced to directly collide with the inner surface of the flow path body 920 .

The flow path connection pipe 930 may further include a fixing rib 932 that can be fixed to the flow path body 920 or fixed to the connection duct 35 . The fixing rib 932 is coupled to a fixed rigid body such as the connection duct 35 to fix the position of the flow path connection pipe 930 even when water flows into the flow path connection pipe 930 . Accordingly, the flow path connection pipe 930 can be prevented from being separated from the flow path body 920 .

The fixing rib 932 may be provided in a plate shape, and a fixing hole 9321 through which a fastening member capable of fixing the fixing rib 932 may pass may be further provided.

The flow path body 920 may extend from a portion coupled to the flow path connector 930 to a distal end so that an area thereof becomes wider. Accordingly, the water introduced into the flow path connection pipe 930 may fill the flow path body 920 or spread over a wider area while moving along the flow path body 920 .

Referring to FIG. 6(b), the flow path body 920 is provided with an inlet hole 9211 through which the flow path connector 930 is coupled or supplied with water, and is spaced apart from the inlet hole 9211. It may further include a discharge slit 923 through which the introduced water is discharged.

The inlet hole 9211 and the outlet slit 923 may be disposed to be spaced apart from each other so as to block them from facing each other. The inlet hole 9211 and the outlet slit 923 may be disposed to prevent them from facing each other on a straight line.

Accordingly, it is possible to prevent the water flowing into the inlet hole 9211 from being directly discharged to the discharge slit 923 without contacting the flow path body 920 . As a result, the water introduced from the inlet hole 9211 may move to the discharge slit 923 after spreading inside the flow path body 920 .

The inlet hole 9211 may be provided on one side of the flow path body 920 , and the discharge slit 923 may be provided on the other side of the flow path body 920 . When the inlet hole 9211 is provided through the upper portion of one side of the passage body 920 , the inlet hole 9211 may be provided through the other lower portion of the passage body 920 .

The inlet hole 9211 and the discharge slit 923 may be spaced apart as far as possible to induce water to move along the flow path body 920 . The inlet hole 9211 may be provided in a circular shape.

The euro body 920 may be provided in a duct shape having an empty interior and allowing water to flow.

The flow path body 920 may include a coupling body 921 to which the flow path connection pipe 930 is coupled, and a moving duct 922 extending from the coupling body 921 to a wider cross-sectional area. The coupling body 921 may be provided through the inlet hole 9211, and the moving duct 922 may be provided to increase in width from the coupling body 921 to the discharge slit 923. have.

The coupling body 921 may form one end of the flow path body 920 , and the flow path connection pipe 930 may be coupled to and supported thereon. The moving duct 922 may extend from an end of the coupling body 921 in a diffuser shape to extend an area. The discharge slit 923 may be provided through the distal end of the moving duct 922 . The discharge slit 923 may be provided in a slit shape having a width longer than a width, and may be manufactured to have a width corresponding to the width of the distal end of the moving duct 922 .

The discharge slit 923 may be provided in a direction different from the direction in which the moving duct 922 extends from the coupling body 921 . That is, the moving duct 922 may be provided through one surface of the moving duct 922 so that water is discharged in a direction different from the moving direction of the water.

Meanwhile, a blocking surface 924 for moving water moving along the moving duct 922 to the discharge slit 923 may be provided at an end of the moving duct 922 . The blocking surface 924 may serve to shield the inside of the flow path body 920 , and may be provided at the distal end of the flow path body 920 .

The blocking surface 924 may serve to temporarily store the water introduced into the inlet hole 9211 in the flow path body 920 . The blocking surface 924 may induce water moving along the moving duct 922 to collide and move to the discharge slit 923 .

In addition, the inlet hole 9211 may be provided at the free end of the coupling body 921, but at the free end of the coupling body 921 so that the introduced water can stay in the flow path body 920 more. They may be spaced apart.

The inlet hole 9211 may be provided through the coupling body 921, but to pass through the coupling body 921 and further penetrate a part of the moving duct 922 in order to secure a larger flow rate. can

The water introduced into the inlet hole 9211 may move along the moving duct 922 . In this case, even if the flow rate of the water introduced into the inlet hole 9211 is high and the speed is high, the flow rate may be dispersed and the speed may be slow while moving along the moving duct 922 . The slowed water may be more smoothly dispersed along the surface of the moving duct 922 .

Since the moving duct 922 continues to widen toward the discharge slit 923 , the speed of the introduced water is further reduced, and the water may be further dispersed along the width direction of the moving duct 922 .

Accordingly, the water introduced into the inlet hole 9211 may be discharged through the discharge slit 923 , and may be dispersed and discharged along the width direction of the discharge slit 923 .

Furthermore, when the inlet hole 9211 is spaced apart from one end of the coupling body 921 , a portion of the water introduced into the inlet hole 9211 flows back to one end of the coupling body 921 . In this case, the backwashed water may interfere with the movement of the inflow water to further reduce the speed of the inflow water, and the water may lose more kinetic energy and spread more evenly in the moving duct 922 .

Furthermore, since the area of the discharge slit 923 is relatively small, the water colliding with the blocking surface 924 may not be discharged directly to the discharge slit 923 and may be collected from the blocking surface 924 . Accordingly, the water introduced into the flow path body 920 is not discharged directly to the discharge slit 923, but stays in the flow path body 920 for a certain period of time and is evenly discharged while filling the entire width of the discharge slit 923. can

In addition, the blocking surface 924 further reduces the kinetic energy of water moving through the moving duct 922 while colliding with water moving along the moving duct 922, The direction of movement may also be switched to the discharge slit 923 .

Accordingly, water may be further dispersed and discharged through the entire discharge slit 923 .

As a result, even if the flow rate of the water introduced into the flow path body 920 is high and the diameter of the inlet hole 9211 is smaller than the width of the discharge slit 923, the water is evenly distributed through the discharge slit 923. can be emitted. In addition, more water is not supplied to a specific portion of the discharge slit 923 , and water may be evenly dispersed and discharged to the entire area of the discharge slit 923 .

Therefore, if the discharge slit 923 is set parallel to the inlet surface of the evaporator 41, water can be evenly sprayed on the surface of the evaporator 41, and the blind spot can be further reduced.

The movable body 922 may be disposed parallel to the upper surface of the evaporator 41 , and the discharge slit 923 may face a part of the upper surface or the inflow surface of the evaporator 41 or the inflow of the evaporator 41 . It may be disposed toward the front side. In addition, the inlet hole 9211 may be provided at an upper portion of the flow path body 920 .

Accordingly, the water introduced into the upper portion of the discharge unit 900 may be discharged toward the evaporator 41 after moving for a predetermined distance along the upper surface of the evaporator 41 .

Referring to FIG. 6( c ), the flow path connection pipe 930 is coupled to the discharge unit 900 to receive water supplied to the washing inlet pipe 931 , and a fixed rib for fixing the washing inlet pipe 931 . It may include a 932 and an inlet pipe 934 extending from the washing inlet pipe 931 to be introduced into the flow path body 920 . The washing inlet pipe 931 and the inlet pipe 934 may be provided integrally.

Since the input pipe 934 is disposed inside the flow path body 920 , it is possible to prevent water from leaking out of the flow path body 920 .

In all other embodiments described below, in the case of a configuration common to the above-described embodiment, overlapping descriptions are omitted, and differences will be intensively described.

7 shows another embodiment of the discharge unit.

Referring to FIG. 7A , the discharge part 900 may include a flow path connector 930 and the flow path body 920 at the same time.

The discharge unit 900 may further include a conversion duct 925 extending from the distal end of the moving duct 920 to the blocking surface 924 .

The conversion duct 925 may be provided to convert an angle or a width extending from the moving duct 920 . Accordingly, the conversion duct 925 may change the direction or distribution of water flowing through the moving duct 920 .

Referring to FIG. 7( b ), the conversion duct 925 extends from the end of the moving duct 920 , and the moving duct 920 extends from the coupling surface 921 toward the blocking surface 924 . It may include an extension surface 9251 that is provided to extend to the blocking surface 924 at an angle different from the angle.

In other words, based on the longitudinal direction of the flow path body 920, the moving duct 920 extends from the inlet hole 9211 toward the discharge slit 923 at an angle different from the extended surface. (9251) may be included.

The extension surface 9251 may be provided to reduce the rate at which the moving duct 920 is expanded. For example, the extension surface 9251 may be provided in the shape of a rectangular parallelepiped duct.

Accordingly, the moving water can change the direction toward the discharge slit 923 while moving along the extension surface 9251 along the angle at which the moving duct 920 is expanded.

In other words, as water moves along the extension surface 9251 , the direction of movement of water may become more uniform.

Accordingly, it can be prevented that water is concentrated to a specific point of the discharge slit 923 or that water that has passed through the discharge slit 923 is dispersed in various directions. Accordingly, water may be uniformly discharged over the entire width of the discharge slit 923 , and the discharged water may move toward the evaporator 41 in a more uniform direction.

8 shows another embodiment of the discharge unit.

Referring to FIG. 8A , the discharge unit 900 may further include a conversion duct 925 extending from the distal end of the moving duct 922 to the blocking surface. The conversion duct 925 may further include an extension surface 9252 having an area wider from the inlet hole 9211 toward the discharge slit 923 .

Referring to FIG. 8(b) , the extension surface 9252 may extend to the blocking surface 924 at an angle different from the angle at which the moving duct 922 extends, like the extension surface 9251 .

In addition, the width of the expanded surface 9252 may increase as the cross-section approaches in a direction farther from the discharge slit 923 . The extension surface 9252 may be provided such that the area gradually expands in the vertical direction.

If the movable body 922 and the extended surface 9251 control the flow of water flowing in the longitudinal direction of the flow path body 920 , the extended surface 9252 is the flow of water flowing in the height direction of the flow path body 920 . flow can be controlled.

Accordingly, as the water flowing inside the flow path body 920 moves toward the discharge slit 923 , the speed may be reduced in vertical and front-rear directions, and may be evenly distributed in the width direction of the discharge slit 923 .

As a result, more uniform water is discharged through the discharge slit 923 at a uniform speed, so that foreign substances adhering to the evaporator 41 can be washed evenly.

9 shows another embodiment of the discharge unit 900 .

Referring to FIG. 9A , the discharge unit 900 may further include a flow path control unit 926 provided inside the flow path body 920 to control the movement direction of the water.

When the flow path body 920 is disposed parallel to the upper surface of the evaporator 41 or disposed above the connection duct 35, the power through which water flows may be lost due to the movable body 922, etc. There are concerns.

In addition, when the lower surface of the flow path body 920 is disposed parallel to the ground, water may remain inside the flow path body 920 to cause corruption.

Accordingly, the discharge unit 900 of the present invention may induce the water introduced into the flow path body 920 through the flow path control unit 926 to be discharged through the discharge slit 923 and block the generation of residual water.

The flow path control unit 926 may include an inclined portion 9261 that allows the water introduced into the flow path body 920 to more smoothly move to the discharge slit 923 .

The inclined portion 9261 may be provided extending from the coupling body 921 to the discharge slit 923 .

The inclined portion 9261 may be provided separately from the flow path body 920 to be coupled to the flow path body 920 . In addition, the inclined portion 9261 may be provided integrally with the flow path body 920 to be formed on one surface of the flow path body 920 with different thicknesses.

The inclined portion 9261 may have the highest inner surface of the coupling body 921 and the lowest inner surface adjacent to the discharge slit 923 .

Accordingly, the water introduced into the washing inlet pipe 933 may move to the discharge slit 923 by gravity along the inclined portion 9261 and be completely discharged.

Also, the inclined portion 9261 may have a straight cross-section.

Referring to FIG. 9( b ), the flow path control unit 926 may include a curved portion 9262 provided so that the water introduced into the flow path body 920 moves to both ends of the discharge slit 923 . have. The bent portion 9262 may be provided on the inclined portion 9261 . In addition, only the bent portion 9262 may be provided inside the flow path body 920 .

The bent portion 9262 may be provided with both ends of the discharge slit 923 bent so that the height is lower than the height of the center of the discharge slit 923 .

Accordingly, it is possible to induce the water introduced into the inlet hole 9211 to be dispersed toward both ends of the discharge slit 923 by gravity. As a result, even when the moving duct 922 or the conversion duct 925 is relatively short, water may be dispersed toward both ends of the discharge slit 923 by the bent portion 9262 .

Meanwhile, the washing inlet pipe 933 may be bent downward from the washing inlet pipe 931 to further add kinetic energy to the sprayed water.

FIG. 10 shows another embodiment of the discharge unit 920 .

Referring to FIG. 10A , the flow path control unit 926 may include a plurality of partition ribs 9263 that partition the inside of the flow path body 920 . The plurality of partitioning ribs 9263 may be disposed to be spaced apart such that a distance between one end toward the discharge slit 923 is greater than a distance between the other ends.

The partition rib 9263 may be provided extending from the coupling body 921 to the discharge slit 923 .

However, the partition rib 9263 may be provided to extend from the moving duct 922 to the discharge slit 923, and extend from the middle part of the moving duct 922 to the discharge slit 923. can be

Accordingly, the water introduced into the inlet hole 9211 is transferred to both ends of the discharge slit 923 before moving the moving duct 922 or in the process of moving the moving duct 922 and the water and the discharge. Water moving to the center of the slit 923 may be determined. Accordingly, the water introduced into the inlet hole 9211 may be concentrated in a specific area of the discharge slit 923 and prevented from being discharged.

The partition rib 9263 may be applied to all of the above-described embodiments. For example, it may be applied to the flow path body 920 provided with the conversion duct 925 and the inclined portion 9261 .

Referring to FIG. 10B , the partition rib 9263 may also be provided on the bent portion 9262 . Accordingly, water may be further dispersed and discharged to both ends of the discharge slit 923 .

The plurality of partition ribs 9263 may have one end spaced apart from each other at uniform intervals, but if it is difficult to disperse water in a specific area due to the structure of the flow path body 920, more water may be supplied to the area. They may be arranged at different intervals.

11 shows another embodiment of the discharge unit 900 .

The discharge unit 900 may further include a step portion 927 provided to protrude in the longitudinal direction of the discharge slit 923 inside the flow path body 920 .

The step portion 927 may be disposed on the other surface of the passage body 920 facing the one surface to which the inlet hole 9211 or the passage connection pipe 930 is coupled.

The step portion 927 may serve to temporarily collect water moving in the flow path body 920 . The water introduced through the flow path connection pipe 930 may be stored in the flow path body 920 until the water level exceeds the height of the step 927 even when it reaches the step 927 . . Thereafter, when more water is introduced into the flow path body 920 and water capable of exceeding the height of the step portion 927 is stored, the water moves to the discharge slit 923 over the step portion 927 . can

Since the stepped portion 927 is provided in parallel with the discharge slit 923, the water moving along the upper surface of the stepped portion 927 may be evenly distributed over the entire area of the discharge slit 923 and discharged. . As a result, even if water first reaches a specific area of the stepped portion 927 , the water may be uniformly discharged through the discharge slit 923 along the entire area of the stepped portion 927 .

In addition, the water exceeding the step portion 927 may be discharged through the discharge slit 923 in a uniform direction.

The step portion 927 includes a limiting surface 9271 protruding from the flow path body 920 to temporarily block the movement of water, and a moving surface 9272 extending from the upper portion of the limiting surface to the discharge slit to induce the movement of water. ) may be included.

The limiting surface 9271 may have a downward convex curve. Thereby, a larger amount of water can be temporarily stored.

In addition, the moving surface 9272 may be provided on a flat surface, such as a cliff, and may extend in parallel with one surface of the discharge slit 923 . This may prevent the moving surface 9272 from providing unnecessary resistance to water.

Meanwhile, the stepped portion 927 may further include a slit or a hole provided through the lower surface of the stepped portion 927 to prevent water from accumulating therein.

The step portion 927 may be applied to all of the above-described embodiments.

12 shows another embodiment of the discharge unit.

The discharge unit 900 may further include an extension duct 928 extending from the flow path body 920 to guide water to the evaporator 41 .

The extension duct 928 may be provided to extend from the outer peripheral surface of the distal end of the discharge slit 923 . The extension duct 928 may be provided integrally with the flow path body 920 to extend from the flow path body 920 .

The extension duct 928 may be provided to extend from the lower surface of the flow path body 920 , and the extension duct 928 may be provided to extend toward the evaporator 41 .

The water collected in the inlet body 920 may be discharged toward the evaporator 41 while passing through the extension duct 928 , regardless of movement in any direction. Accordingly, foreign substances adhering to the evaporator 41 can be effectively removed.

The shape of the extension duct 928 may be provided to correspond to the inner circumferential surface of the discharge slit 923 .

The width of the extension duct 928 may correspond to the width of the discharge slit 923 , and the width of the extension duct 928 may correspond to the width of the discharge slit 923 . The extension duct 928 may be provided in a shape in which the discharge slit 923 extends to the outside.

Of course, the width of the extension duct 928 may be smaller than the width of the discharge slit 923 so that the hydraulic pressure is set strongly.

The extension duct 928 may be applied to all the above-described embodiments.

In all the above-described embodiments, the discharge unit 900 is disposed in a direction inclined or perpendicular to the inlet surface direction of the evaporator 41 (front and rear direction of the duct), and a discharge slit is located at the lower portion of the discharge unit 900 . (923).

On the other hand, in all the above-described embodiments, the inlet hole 9211 is disposed above the flow path body 920 and the discharge slit 923 is disposed below the flow path body 920 . .

However, if the inlet hole 9211 and the outlet slit 923 do not face each other, the inlet hole 9211 may communicate with one end of the flow path body 920 .

That is, the inlet hole 9211 may be provided to face one end of the coupling body 921 or the blocking surface 924 . Accordingly, it is possible to prevent the water flowing into the inlet hole 9211 from flowing backward or from generating a vortex inside the coupling body 921 .

13 shows another embodiment of the discharge unit 900 .

The discharge part 900 may be disposed in the same direction as the inflow surface of the evaporator 41 .

Referring to FIG. 13( a ), the discharge part 900 may include a flow path connector 930 and a flow path body 920 as in the above-described embodiment, and the flow path body 920 is a coupling body. It may include a 921 and a moving duct 922 . In addition, the discharge unit 900 may further include the conversion duct 925 .

However, the flow path body 920 may be disposed in a direction parallel to the inflow surface of the evaporator 41 . That is, the flow path body 920 may be disposed in the height direction of the cabinet.

In this case, the discharge slit 923 may include an opening 929 provided with one surface of the flow path body 920 open to discharge the water introduced into the flow path body 920 to the evaporator 41 . have.

That is, the discharge slit 923 may include an opening 929 provided through the free end of the flow path body 920 so that the water moving in the flow path body 920 is discharged in a moving direction. . The opening 929 may be provided to completely open the surface on which the blocking surface 924 is formed on the flow path body 920 .

Accordingly, the water introduced into the flow path body 920 may be further accelerated by gravity and discharged to the evaporator 41 , and foreign substances attached to the evaporator 41 may collide with water more strongly and be separated. .

Referring to FIG. 13(b) , the opening 929 may also be disposed so that it is blocked from facing the inlet hole 9211 . That is, the inlet hole 9211 may be provided on the front or rear surface of the flow path body 920 , and the opening 929 may be provided at the lower end of the flow path body 920 .

Accordingly, the water introduced into the inlet hole 9211 may be dispersed into the flow path body 920 while colliding with the inner surface of the flow path body 920 , and then discharged through the opening 929 . Accordingly, it is possible to prevent the water flowing into the inlet hole 9211 from being discharged into the opening 929 without contacting the flow path body 920 .

The discharge part 900 may further include a bent part 9291 provided in the flow path body 920 to temporarily collect the water moving to the opening part 929 .

The bent part 9291 may be provided so that a part of the flow path body 920 can be recessed into the flow path body 920 to reduce the flow path area of the flow path body 920 . Accordingly, the water introduced through the inlet hole 9211 may be temporarily accumulated in the bent part 9291 , and after being dispersed along the width direction of the bent part 9291 , it is discharged to the open part 929 . can be

The bent portion 9291 may be provided closer to the opening 929 than the inlet hole 9211 .

FIG. 14 shows an expanded embodiment of the discharge unit 900 of FIG. 13 .

The discharge part 900 may further include a dispersion rib 9292 that partitions the area of the open part 929 .

The dispersion rib 9292 may be provided along the width direction of the opening 929 . In addition, the dispersion ribs 9292 only extend from both side surfaces of the flow path body 920 , and may be disposed to be spaced apart from the inner surface of the flow path body 920 .

The dispersion rib 9292 may be provided to face the flow path formed by the bent portion 9291 . As a result, the water passing through the bent portion 9291 collides with the dispersion rib 9292 once again to limit the flow, so that the water can be dispersed along the width direction of the flow path body 920 .

As a result, water may be induced to be discharged to the entire area of the opening 929 .

15 is a view showing the duct structure of the laundry treatment apparatus of the present invention.

Referring to FIG. 15 , the laundry treatment apparatus of the present invention may include a duct 3 that circulates the air discharged from the drum 2 and forms a circulation path for re-supplying the air back to the drum 2 . The duct 3 includes an exhaust duct 31 through which the air supplied from the drum 2 is discharged, a connection duct 35 to which the evaporator 41 and the condenser 43 are mounted, and the connection duct 35 ) and may include a supply duct 33 for supplying air to the drum (2).

In this case, the duct 3 may further include a mounting duct 36 that is detachably provided on the upper portion of the connection duct 35 . Accordingly, after the evaporator 41 and the condenser 43 are installed in the connection duct 35 , the mounting duct 36 is coupled to the connection duct 35 and the air flowing through the connection duct 35 . can be prevented from leaking.

The mounting duct 36 may serve as a cover for the connection duct 35 , and at least one of the moving part 6 and the discharge part 900 may be seated and supported thereon.

The mounting duct 36 may further extend from the extension duct 35 toward the exhaust duct 31 so as to form an upper portion of the exhaust duct 31 and may be composed of one piece. can Thereby, the problem of assembling or installing two components can be solved because the cover forming the upper part of the connection duct 35 is composed of only one mounting duct 36 .

Furthermore, since the mounting duct 36 is formed of an integral part, the outflow of air circulating in the duct 3 to the mounting duct 36 can be blocked.

The mounting duct 36 may include a mounting cover 361 mounted on an upper portion of the connection duct 35 , and a mounting rib 362 provided on an outer surface of the mounting cover 361 . The mounting rib 362 protrudes in the thickness direction on at least one of both sides, front, and back of the mounting cover 361 to improve durability of the mounting cover 361 as well as to improve the durability of the mounting cover 361. It is possible to provide a space in which a separate component can be seated on the upper part.

The mounting rib 362 may be provided to be mounted to at least one of the connection duct 35, the supply duct 33, and the exhaust duct 31 by an interference fit, etc., of the mounting rib 362 A plurality of mounting hooks 363 that can be detachably coupled to at least one of the connection duct 35 , the supply duct 33 , and the exhaust duct 31 may be provided on the surface.

The mounting cover 361 includes an installation cover 3611 forming an upper surface of the connection duct 35 and a cleaning cover extending from the installation cover 3611 to form a space in which the discharge unit 900 is mounted ( 3612 ) and an inlet cover 3613 extending from the washing cover 3612 to form an upper surface of the supply duct 33 or to be connected to the supply duct 33 .

In the installation cover 3611, a part of the moving part 6 may be seated. For example, the flow path switching unit 63 and the supply pipe 631 may be supported by the installation cover 3611 .

Meanwhile, the cleaning cover 3612 may be provided to extend to the installation cover 3611 , and the evaporator 41 may be disposed at a lower portion thereof.

The cleaning cover 3612 may be provided on which the discharge part 900 is seated. To this end, the cleaning cover 3612 may be provided by being recessed from the mounting cover 361 , and may be provided inclined downwardly from the installation cover 3611 . In addition, the cleaning cover 3612 may be provided with a flow path installation part 364 to which the discharge part 900 can be mounted. The flow path installation unit 364 may include a cover through hole 3644 through which the water supplied from the discharge unit 900 may be guided to the evaporator 41 through the washing cover 3612 . The cover through-holes 3644 may be provided in a slit shape, and may be provided with a plurality of spaced apart from each other along the width direction of the mounting cover 361 .

The inlet cover 3613 may be provided to extend from the cleaning cover 3612 to the supply duct 33, and may form a flow path through which air flows. The inlet cover 3613 and the washing cover 3612 may be provided integrally.

Meanwhile, the mounting cover 361 may further include a blocking rib 3614 provided to partition the inlet cover 3613 and the washing cover 3612 . The blocking ribs 3614 may be disposed along the plurality of cover through holes 3644 , and may be disposed on the front surface of the cover through holes 3644 .

On the other hand, the discharge unit 900 may be provided mounted on the upper portion of the cleaning cover (3612). In other words, the discharge unit 900 capable of supplying the water to the evaporator 41 may be seated and coupled to the upper portion of the mounting duct 36 , and may not be involved at all in forming the circulation passage.

Accordingly, after the assembly of the duct 3 is completed, the discharge part 900 may be installed in the duct 3 . As a result, the assembly and installation of the duct 3 can be simplified.

On the other hand, the discharge unit 900 may be provided with all of the above-described embodiments mounted on the cleaning cover 3612 .

That is, any embodiment may be applied to the discharge unit 900 as long as the discharge slit 923 communicates with the cover through hole 3644 .

The flow path installation part 364 may include installation ribs 3641 and 3642 that provide a space in which the flow path body 920 of the above-described embodiment can be mounted. Specifically, the installation ribs 3641 and 3642 may be provided to correspond to the shape of the flow path body 920 to fix the flow path body 920 . Accordingly, it is possible to prevent the discharge slit 923 and the cover through hole 3644 from being misaligned.

The installation ribs 3641 and 3642 may be provided in a groove shape, and a first installation rib 3641 supporting one side of the flow path body 920 and a second installation rib 3641 supporting the other side of the flow path body 920 are provided. Ribs 3642 may be included. One end of the first installation rib 3641 and one end of the second installation rib 3642 may be spaced apart from each other, but may be connected to each other. The other end of the first installation rib 3641 and the other end of the second installation rib 3642 may extend to the blocking rib 3614 .

In addition, the first installation rib 3641 and the second installation rib 3642 may be disposed to extend to the blocking rib 3614 so as to be separated from each other.

Accordingly, the water flowing out from the flow path body 920 may collide with the blocking ribs 3614 and then be guided to the installation ribs and discharged through the cover through-holes 3644 .

In addition, the flow path connection pipe 930 may be supported between one end of the first installation rib 3641 and one end of the second installation rib 3642 .

On the other hand, the discharge unit 900 may be provided in an embodiment completely different from the above-described embodiment. For example, the discharge part 900 is provided to supply water to the first installation rib 3641 and the second installation rib 3642 , and the first installation rib 3641 and the second installation rib 3642 . Water supplied to the inside (3642) may collide with the blocking rib (3614) and be provided to be discharged through the cover through hole (3644). That is, the discharge unit 900 may be provided with a completely open lower surface.

In this case, the discharge unit 900 may be provided as a cover provided to simply shield a part of the washing cover 3612 to form an upper portion of a flow path through which the water supplied from the supply pipe 631 moves. have.

Specifically, the discharge unit 900 is coupled to the supply pipe 631 to receive water supplied to the flow path connection pipe 930 and the water supplied to the flow path connection pipe 930 is moved to the cover through hole 3644 . It may include a euro body 920 .

In this case, a plate-shaped installation body 910 may be provided, and the flow path body 920 may be provided in a rib shape extending toward the cover duct 362 . In other words, the flow path body 920 may be provided with an entire lower surface open, unlike the above-described embodiment, and the water supplied to the flow path connection pipe 930 is guided into the installation ribs 3641 and 3642. It may be provided with ribs.

When the cover through hole 3644 is provided in plurality, the flow path connection pipe 930 and the flow path body 920 corresponding to each cover through hole 3644 are provided on the installation body 910, respectively. can be

Accordingly, the structure of the discharge unit 900 can be simplified, and by mounting the installation body 910 to the flow path installation unit 364, the installation of the discharge unit 900 can be completed simply. have.

In addition, the water flowing into the flow path connection pipe 930 flows into the washing cover 3612 by the flow path body 920 , and the water flowing into the washing cover 3612 is the first installation rib 3641 . ) and the second installation rib 3642 and may extend to the surface of the cleaning cover 3612 . Thereafter, it collides with the blocking rib 3614 and is evenly distributed along the width of the cover through hole 3644 to move to the evaporator 41 .

The present invention may be modified and implemented in various forms, but the scope of the rights is not limited to the above-described embodiments. Therefore, if the modified embodiment includes the elements of the claims of the present invention, it should be regarded as belonging to the scope of the present invention.

100 clothes handling equipment
1 cabinet 2 drums
3 Duct 5 Filtration
6 Moving part 900 Discharging part

Claims (22)

cabinets that form the facade;
a drum accommodated in the cabinet to accommodate clothes;
a circulation passage provided to re-supply the air discharged from the drum to the drum;
a fan provided inside the circulation passage to move air;
a heat exchange unit including an evaporator installed inside the circulation passage to cool the air discharged from the drum, and a condenser spaced apart from the evaporator to heat the air;
a moving unit coupled to the heat exchange unit or the circulation passage to move the water condensed in the evaporator;
and a discharge unit coupled to the moving unit to receive the water and discharge it to the evaporator to remove foreign substances attached to the evaporator;
the discharge part
an inlet hole coupled to the moving part to receive the water, and a discharge slit for discharging the water supplied from the inlet hole to the evaporator,
and the inlet hole and the outlet slit are spaced apart from each other to block them from facing each other. According to claim 1,
the discharge part
Further comprising a flow path body having the inlet hole on one side, the discharge slit on the other side, and providing a space for water to move,
and the discharge slit is provided through one surface of the flow path body so that the water moving through the flow path body is discharged in a direction different from the moving direction. 3. The method of claim 2,
The flow path body includes a moving duct for guiding the water introduced from the inlet hole to the discharge slit,
and the width of the moving duct increases from the inlet hole to the outlet slit. 4. The method of claim 3,
The Eurobody is
and a blocking surface for guiding water moving along the moving duct to the discharge slit by collision. 5. The method of claim 4,
The Eurobody is
Further comprising a conversion duct extending from the end of the moving duct to the blocking surface,
and the conversion duct includes an extended surface extending to the blocking surface at an angle different from an angle at which the moving duct extends from the inlet hole toward the discharge slit. 5. The method of claim 4,
The Eurobody is
Further comprising a conversion duct extending from the end of the moving duct to the blocking surface,
and the conversion duct includes an expanded surface provided with both sides of the conversion duct to increase in width as it approaches the discharge slit. 3. The method of claim 2,
the discharge part
and a flow path control unit provided inside the flow path body to control the moving direction of the water. 8. The method of claim 7,
The flow control unit
and an inclined part inclined so that the water introduced into the flow path body moves to the discharge slit. 8. The method of claim 7,
The flow control unit
and a bent part provided with an inner surface of the flow path body bent so that the water introduced into the flow path body moves to both ends of the discharge slit. 8. The method of claim 7,
The flow control unit
and a plurality of partition ribs partitioning the inside of the euro body. 11. The method of claim 10,
The plurality of partition ribs
and a distance between one end toward the discharge slit is greater than a distance between the other ends. 3. The method of claim 2,
the discharge part
and a step portion protruding from the inside of the flow path body in a longitudinal direction of the discharge slit. 13. The method of claim 12,
and the step portion is provided to protrude from one surface of the discharge slit. 3. The method of claim 2,
the discharge part
and an extension duct extending from the flow path body to communicate with the discharge slit to discharge water supplied from the discharge slit. According to claim 1,
the discharge part
Further comprising a flow path body having the inlet hole on one side, the discharge slit on the other side, and providing a space for water to move,
and the discharge slit is provided through a free end of the flow path body so that the water moving through the flow path body is discharged in a moving direction. 16. The method of claim 15,
The flow duct includes a moving duct for guiding the water introduced from the inlet hole to the discharge slit;
and a bent part provided to temporarily collect water moving through the moving duct by bending a portion of the moving duct. 16. The method of claim 15,
and the flow path body is provided parallel to an inlet surface through which air of the circulation flow path of the evaporator flows. cabinets that form the facade;
a drum accommodated in the cabinet to accommodate clothes;
a circulation passage provided to re-supply the air discharged from the drum to the drum;
a fan provided inside the circulation passage to move air;
a heat exchange unit including an evaporator installed inside the circulation passage to cool the air discharged from the drum, and a condenser spaced apart from the evaporator to heat the air;
a moving unit coupled to the heat exchange unit or the circulation passage to move the water condensed in the evaporator;
and a discharge unit coupled to the moving unit to receive the water and discharge it to the evaporator to remove foreign substances attached to the evaporator;
The circulation path
a connection duct in which the evaporator and the condenser are accommodated and coupled;
A mounting duct coupled to the upper part of the connection duct to shield the evaporator and the condenser and to which the moving part is coupled,
The clothes treatment apparatus according to claim 1, wherein the discharge unit is mounted on an upper portion of the mounting duct. 19. The method of claim 18,
The mounting duct includes a mounting cover coupled to the connection duct to shield the evaporator and the condenser, and a cover through-hole penetrating the mounting cover to expose at least a portion of the evaporator,
and the discharge unit includes a flow path body coupled to an upper portion of the mounting cover to supply water to the cover through hole. 20. The method of claim 19,
The discharge part includes a flow path connecting pipe extending parallel to the mounting cover from the flow path body,
and the flow path body is provided to guide the water supplied from the flow path connection pipe to the cover through hole. 20. The method of claim 19,
The cover through hole is provided in plurality along the width direction of the evaporator,
The clothes treatment apparatus according to claim 1, wherein the flow path body is provided in plurality so as to be respectively coupled to the cover through-holes. 20. The method of claim 19,
The plurality of flow path bodies are provided to extend from an installation body coupled to the mounting cover.

Images