KR20190128529A - Laundry treatment apparatus - Google Patents

Abstract

Disclosed is a clothing treating apparatus comprising: a cabinet; a drum rotatably installed in the cabinet and having a form opened to the front and the rear; a circulation passage forming a path for allowing air discharged from a front opening of the drum to enter a rear opening of the drum via an evaporator and a condenser; a circulation fan disposed after the condenser on the basis of the flow of air in the circulation passage, and sucking and blowing air passing through the condenser; and a vent hole formed in the circulation passage between the circulation fan and the rear opening of the drum such that a part of the air blown by the circulation fan flows out of the circulation passage.

Description

Clothing processing unit {LAUNDRY TREATMENT APPARATUS}

The present invention relates to a clothes treating apparatus having a function of drying clothes or bedding.

The apparatus for treating clothes refers to all devices that manage or process clothes, such as washing, drying, or removing wrinkles in clothes or bedding, such as at home or at a laundry. The clothes handling apparatus includes a washing machine, a dryer, a washing machine and a dryer.

A washing machine is a device for washing clothes or bedding, etc., and a dryer is a device for drying the clothes or bedding by removing moisture. The washing machine and dryer are devices that combine washing and drying functions.

In particular, the dryer supplies hot air to the object to be treated (dry matter) such as clothes or bedding, which is put into a drum (or tub), to evaporate moisture contained in the object. The moisture of the object to be evaporated from the drum and the air exiting the drum contain the moisture of the object to be treated at a high temperature and high humidity. At this time, the type of dryer is classified into a condensation type and an exhaust type according to a method of treating the high temperature and high humidity air.

The condenser dryer condenses the moisture contained in the hot humid air through heat exchange while circulating without discharging the hot humid air to the outside. In contrast, the exhaust dryer directly discharges hot and humid air to the outside. The condensation dryers have a structure for treating condensed water, and the exhaust dryers have a structural difference from each other in that they have a structure for exhausting air.

The condensation dryer has a circulation passage for removing moisture from the air discharged from the drum and then heating it to enter the drum. In the structure in which the circulation fan is disposed after the condenser based on the flow of air, the pressure inside the drum and the circulation passage is highest at the outlet side of the circulation fan and gradually decreases through the drum, the evaporator, and the condenser.

The flow resistance inside the drum is increased by the treatment object contained inside the drum, or the lint filter for removing lint from the air discharged from the front opening of the drum is blocked, thereby increasing the flow resistance, or between the front opening of the drum and the circulation fan. When the outside air flows into the gap connected to the outside on the circulation flow path of the inside, the pressure difference between the inside and outside of the drum occurs. As such, when the pressure inside the drum is greater than the outside pressure, a phenomenon may occur in which the humid air inside the drum leaks to the outside of the drum through a gap between the drum and the structure for rotatably supporting the drum.

Wet air leaking to the outside of the drum may cause problems such as short circuits, corrosion, and leakage of the electric parts and circuit boards. In addition, the lint may leak to the outside of the drum through the gap. In this case, the lint may cause a short circuit of the electric parts or the circuit board, and may cause a bad smell when exposed to moisture for a long time.

The present invention, in the structure in which the circulation fan is arranged after the condenser based on the flow of air in the circulation passage, a structure that can reduce the leakage of the wet air to the outside of the drum due to the pressure difference between the inside and outside of the drum. The purpose is to provide.

In order to achieve the object of the present invention, the laundry treatment apparatus of the present invention, the cabinet; A drum rotatably installed in the cabinet, the drum having a form opened forward and backward; A circulation passage forming a path for allowing air discharged from the front opening of the drum to enter the rear opening of the drum via an evaporator and a condenser; A circulation fan disposed after the condenser on the basis of the flow of air in the circulation passage, for sucking and blowing air passing through the condenser; Disclosed is a clothes processing apparatus including a vent hole formed in the circulation passage between the circulation fan and the rear opening of the drum such that a part of the air blown by the circulation fan flows out of the circulation passage.

An object of the present invention, the drum has a form that is opened back and forth, and accommodates the garment; A front supporter rotatably supporting the drum at a front side of the drum, the front supporter having a communication hole communicating with the front opening of the drum; A rear supporter rotatably supporting the drum at a rear side of the drum, the rear supporter having a vent communicating with the rear opening of the drum; A circulation passage connecting the communication hole and the vent to form a path for allowing air discharged from the front opening of the drum to enter the rear opening of the drum through an evaporator and a condenser; A circulation fan disposed after the condenser on the basis of the flow of air in the circulation passage, for sucking and blowing air passing through the condenser; And a vent hole formed in the circulation passage between the circulation fan and the vent so that a part of the air blown by the circulation fan flows out of the circulation passage.

The vent hole area can be a 5cm ² or more than 30cm ^2.

The clothes treating apparatus may further include a cover rotatably connected to the circulation passage and configured to selectively open or close at least a portion of the vent hole.

The cover is disposed to cover the vent hole by gravity, and may be rotated to open the vent hole when the pressure difference between the inside and the outside of the drum is greater than gravity.

The rotation angle of the cover increases as the pressure difference between the inside and the outside of the drum increases.

The clothes treating apparatus includes: a sensing unit configured to sense a pressure difference between an inside and an outside of the drum; And a controller configured to control the rotation of the cover based on the pressure difference sensed by the sensing unit.

The cover may be disposed to completely cover the vent hole in a closed state.

The cover may include a protrusion that is supported around the vent hole in a closed state to form a gap between the circulation passage and the cover.

The circulation passage may have a protrusion protruding from the periphery of the vent hole to support the cover in a closed state to form a gap between the circulation passage and the cover.

The clothes treating apparatus includes a cabinet accommodating the drum and the circulation passage and forming an appearance of the clothes treating apparatus; A blowing fan provided in an internal space between the cabinet and the drum to circulate air in the internal space; And an exhaust fan installed in the cabinet and discharging air in the internal space to the outside of the cabinet.

In order to achieve the object of the present invention, the laundry treatment apparatus of the present invention, the cabinet; A drum rotatably installed in the cabinet, the drum having a form opened forward and backward; A circulation passage forming a path for allowing air discharged from the front opening of the drum to enter the rear opening of the drum via an evaporator and a condenser; A circulation fan disposed after the condenser on the basis of the flow of air in the circulation passage, for sucking and blowing air passing through the condenser; A vent hole formed in the circulation passage between the circulation fan and the rear opening of the drum; And a cover rotatably connected to the circulation passage and configured to selectively open and close at least a portion of the vent hole.

The cover is rotated to open the vent hole when the pressure difference between the inside and the outside of the drum is greater than gravity, and is disposed to cover the vent hole when the pressure difference between the inside and the outside of the drum is less than gravity. Can be.

The clothes treating apparatus includes: a sensing unit configured to sense a pressure difference between an inside and an outside of the drum; And a controller configured to control the rotation of the cover based on the pressure difference sensed by the sensing unit.

The cover may include a protrusion that is supported around the vent hole in a closed state to form a gap between the circulation passage and the cover.

The clothes treating apparatus includes: a blowing fan provided in an inner space between the cabinet and the drum to circulate air in the inner space; And an exhaust fan installed in the cabinet and discharging air in the internal space to the outside of the cabinet.

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

First, since a vent hole is formed in the circulation passage between the circulation fan and the rear opening of the drum, a part of the air blown by the circulation fan flows out of the circulation passage to reduce the pressure difference between the inside and the outside of the drum. . Thus, leakage of wet air to the outside of the drum can be reduced.

Second, the cover is rotatably connected to the circulation passage to selectively open and close at least a part of the vent hole, thereby improving drying performance compared to the structure in which the vent hole is always open.

Third, the cover is configured not to completely cover the vent hole, it is possible to breathe even if the infant or pet is trapped inside the drum can be prevented from choking.

1 is a perspective view showing a clothes processing apparatus according to an embodiment of the present invention.
2 is a conceptual diagram illustrating the circulation of air through the drum and the circulation passage shown in FIG.
3 is a conceptual view illustrating a structure in which the drum illustrated in FIG. 1 is rotatably supported by the front supporter and the rear supporter.
4 is a conceptual view showing the structure of the drum front shown in FIG.
FIG. 5 is a perspective view illustrating the base cabinet and main components mounted to the base cabinet shown in FIG. 1; FIG.
6 is a conceptual view showing the structure of the rear of the drum shown in FIG.
7 is a conceptual view showing the main parts of the rear of the drum shown in FIG.
8 is a conceptual view illustrating a state in which the rear duct connector shown in FIG. 6 is mounted on a circulation fan accommodating part.
9 is a conceptual view showing a state in which the rear duct connector shown in FIG. 6 is coupled to the rear supporter.
10 is a view showing the inside of the base member shown in FIG.
FIG. 11 is a conceptual diagram for explaining an effect by an internal partition shown in FIG. 10. FIG.
12 and 13 are conceptual views for explaining the pressure in the main portion of the drum and the circulation passage in a structure in which the circulation fan is disposed before the heat exchange unit based on the flow of air.
14 and 15 are conceptual views for explaining the pressure in the main part of the drum and the circulation passage in a structure in which the circulation fan is arranged after the heat exchange unit based on the flow of air.
16 is a conceptual diagram briefly showing the flow of air in the drum and the circulation passage shown in FIG.
17 and 18 are conceptual views of a clothes treating apparatus according to another embodiment of the present invention, and FIG. 17 shows when the clothes treating apparatus is stopped or when the pressure difference between the inside and the outside of the drum is small, and FIG. 18 shows a drum. This indicates when the pressure difference between the inside and outside is large.
19 is a conceptual diagram of a clothes treating apparatus according to another embodiment of the present invention.
20 is a conceptual diagram of a clothes treating apparatus according to another embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, the clothing processing apparatus which concerns on this invention is demonstrated in detail with reference to drawings.

In the present specification, the same or similar reference numerals are used to designate the same or similar components in different embodiments, and redundant description thereof will be omitted.

In addition, even if different embodiments do not contradict structurally and functionally, the structure applied to one embodiment may be equally applied to another embodiment.

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

In the following description of the embodiments disclosed herein, if it is determined that the detailed description of the related known technology may obscure the gist of the embodiments disclosed herein, the detailed description thereof will be omitted.

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

1 is a perspective view showing a clothes processing apparatus 1000 according to an embodiment of the present invention.

The cabinet 1010 forms an appearance of the clothes treating apparatus 1000. The cabinet 1010 includes a plurality of sub cabinets constituting at least one of front, rear, left and right sides, top and bottom surfaces of the clothes processing apparatus 1000. The sub cabinet may be made of a metal plate, or may be made of a synthetic resin material.

The sub cabinet forming the base of the garment processing apparatus 1000 may be referred to as a base cabinet 1310. The base cabinet 1310 is formed of a synthetic resin material to provide a space for mounting various components. The base cabinet 1310 may itself form a bottom surface of the clothing processing apparatus 1000, and a base plate formed of a metal material may be mounted on the bottom surface of the base cabinet 1310.

The clothes inlet 1011 is formed at the front portion of the cabinet 1010. The clothing inlet 1011 communicates with the front side opening of the drum 1030 and is configured to inject a treatment object such as clothes or bedding into the drum 1030.

The door 1020 is formed to open and close the clothes input opening 1011. The door 1020 may be rotatably connected to the cabinet 1010 by a hinge 1021. The door 1020 may include a light transmitting unit. Therefore, even when the door 1020 is closed, the inside of the drum 1030 may be visually exposed through the light transmitting portion.

The drum 1030 is rotatably installed in the cabinet 1010. The drum 1030 is formed in a hollow cylindrical shape that is open to the front and rear, the front opening 1030 ′ of the drum 1030 is in communication with the clothes inlet 1011, the object to be processed in the drum 1030 It is configured to be accommodated.

A circulation passage is connected to the front opening 1030 ′ and the rear opening 1030 ″ of the drum 1030 so that air is circulated in the closed loop formed by the interior of the drum 1030 and the circulation passage. The humid air discharged through the front opening 1030 ′ of the drum 1030 is passed through the evaporator 1110 on the circulation passage to remove moisture and is heated through the condenser 1130. This hot and dry air is supplied to the drum 1030. ) Is introduced into the drum 1030 through the rear opening 1030 ″, thereby drying the object to be treated.

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

Rollers 1060 may be installed at the front supporter 1040 and the rear supporter 1050, respectively. The roller 1060 is disposed directly below the drum 1030 and contacts the outer circumferential surface of the drum 1030. The roller 1060 is rotatably formed to assist rotation of the drum 1030 while rotating in a direction opposite to the rotation direction of the drum 1030. The outer circumferential surface of the roller 1060 in contact with the outer circumferential surface of the drum 1030 may be formed of an elastic material (for example, rubber).

Underneath the drum 1030 are heat pump cycle devices 1100. The lower side of the drum 1030 here means the space between the lower part of the drum 1030 and the base cabinet 1310. Heat pump cycle devices 1100 refer to devices that configure the cycle to sequentially evaporate-compress-condense-expand the refrigerant. When the heat pump cycle apparatuses 1100 are operated, the air is hot dried while sequentially exchanging heat with the evaporator 1110 and the condenser 1130.

An evaporator 1110 and a condenser 1130 are disposed on the circulation passage for heat exchange with air flowing along the circulation passage. In the base cabinet 1310, a base flow path part 1310 ′ forming a part of the circulation flow path is formed.

The base flow path part 1310 ′ includes a heat exchange part 1312 in which an evaporator 1110 and a condenser 1130 are arranged for heat exchange. A guide part 1311 is provided at the front of the heat exchange part 1312 to guide the inflow of air into the heat exchange part 1312, and the air passing through the heat exchange part 1312 is blown in the rear of the heat exchange part 1312. Is provided with a circulation fan receiving unit 1313, the circulation fan 1710 is received. That is, the base flow path part 1310 ′ includes a guide part 1311, a heat exchange part 1312, and a circulation fan accommodating part 1313, which are provided in order from the front to the rear.

After the evaporator 1110 and the condenser 1130 are installed in the base flow path part 1310 ′, the base cover 1320 is disposed to cover a portion opened upward of the base flow path part 1310 ′. In addition, after the circulation fan is installed in the circulation fan accommodating part, the cover member 1330 is disposed to cover a portion opened to the rear of the circulation fan accommodating part. This completes the flow passage leading from the opening 1311 ′ of the guide portion 1311 to the exhaust port 1313 ″ of the circulation fan accommodating portion 1313. The flow passage forms an outlet duct 1210 and an inlet duct 1220. In connection, it may be referred to as a connection duct 1230 (see FIG. 2).

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

The air to be treated and dried in the drum 1030 is introduced into the heat exchange part 1312 through the guide part 1311 of the front duct connector 1220 and the base flow path part 1310 ′. Water is removed from the heat exchange unit 1312 and heated air is introduced into the drum 1030 through the rear duct connector 1220 by the circulation fan 1710.

Meanwhile, a flow path defined by the front duct connector 1210 and the guide part 1311 around the heat exchange part 1312 may be referred to as a first flow path, and the circulation fan accommodating part 1313 and the rear duct connector ( The flow path defined by 1220 may be referred to as a third flow path. Here, the flow path defined by the heat exchange unit 1312 may be referred to as a second flow path. That is, the air inside the drum 1030 is discharged through the first channel, the water is removed from the second channel and then reheated, and then flows back into the drum 1030 through the third channel.

The first flow path forms a path through which air discharged from the front opening 1030 ′ of the drum flows, and extends downward toward one side of the base cabinet 1310. The second flow path extends in a straight line toward the rear of one side of the base cabinet 1310. The third passage extends upward from one side of the base cabinet 1310 to connect the second passage and the vent 1050 ′ formed in the rear supporter 1050.

That is, the second passage and the third passage are disposed on one side of the base cabinet 1310. Thus, a simplified circulation passage can be realized compared to the existing circulation passage in which the direction change from one side of the base cabinet 1310 to the other side has been performed.

The third passage includes a circulation fan 1710 which is disposed to face the second passage and sucks air that has passed through the second passage and blows the air to the vent of the rear supporter 1050. The third passage includes a forward inlet 1313 ′ facing the second passage and an exhaust port 1313 ″ opened upwardly perpendicular to the inlet 1313 ′, and includes a circulation fan 1710. The circulation fan accommodating part 1313 for accommodating) is formed.

As such, a circulation fan 1710 is disposed at the rear of the second flow path extending in a straight line and blows the air in front of the second flow path upward, thereby forming a uniform flow in the second flow path and the third flow path. have. Therefore, a decrease in heat exchange efficiency in the second channel can be prevented, and a flow path resistance in the third channel can be reduced.

The base cabinet 1310 is formed with a base flow path portion that forms part of the first flow path, the second flow path, and the third flow path. This will be described later.

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

The water pump 1440 (refer to FIG. 5) is provided in the clothes processing apparatus 1000. The water pump 1440 may be installed in the base cabinet 1310. The water pump 1440 moves the condensate to the bucket 1410, and the water bucket 1410 collects the condensate.

The bucket 1410 is disposed on the upper left or upper right of the drum 1030. In other words, the bucket 1410 is disposed in the empty space at the upper left side or the empty space at the upper right side between the top of the drum 1030 and the cabinet 1010. In FIG. 1, a bucket 1410 is shown disposed above the left side of the drum 1030.

The bucket cover 1420 is disposed on the upper left or upper right of the front of the clothes processing apparatus 1000 to correspond to the position of the bucket 1410. The bucket cover 1420 is formed to be gripped by hand and is exposed to the front surface of the clothes treating apparatus 1000. When the bucket cover 1420 is pulled to empty the condensed water collected in the bucket 1410, the bucket 1410 is withdrawn from the bucket supporting frame 1430 together with the bucket cover 1420.

The bucket supporting frame 1430 is formed to support the bucket 1410 in the cabinet 1010. The bucket supporting frame 1430 extends along the inserting / drawing direction of the bucket 1410 to guide the insertion and withdrawal of the bucket 1410.

The input / output panel 1500 is provided on the front or upper surface of the clothes processing apparatus 1000. In FIG. 1, the input / output panel 1500 is illustrated as being disposed beside the bucket cover 1420. The input / output panel 1500 may include an input unit 1510 for receiving a selection of a clothing processing course from a user, and an output unit 1520 for visually displaying an operating state of the clothing processing apparatus 1000.

The input unit 1510 may be formed of a jog dial, but is not limited thereto. The output unit 1520 may be configured to visually display an operating state of the clothes treating apparatus 1000. The clothing processing apparatus 1000 may include a separate configuration for an acoustic display in addition to the visual display.

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

The circuit board constituting the control unit 1600 and the elements mounted on the circuit board may be disposed on the upper left or upper right of the drum 1030. In FIG. 1, a circuit board is installed on a side wall of a cabinet 1010 corresponding to an upper right side of a drum 1030 opposite to the bucket 1410. Considering that the condensate is collected in the water container 1410, the air containing moisture flows in the circulation flow path, and that electrical products such as circuit boards and devices are vulnerable to water, ) Or as far away from the circulation channel as possible.

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

In order to dry the processing object put into the drum 1030, the high temperature dry air is supplied to the inside of the drum 1030, the air to dry the clothes is recovered again to remove moisture and heated, the drum 1030 The process of resupply should be repeated. In order to repeat this process in a condensation dryer, air must be continuously circulated through the drum 1030. The air is circulated through the drum 1030 and the circulation passage.

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

The drum 1030, the outlet duct 1210, the connection duct 1230, and the inlet duct 1220 are sequentially connected based on the flow of air, and the inlet duct 1220 is again connected to the drum 1030 to provide waste oil flow. to form a closed flow path.

In the front supporter 1040, an opening 1040 ′ corresponding to the front opening 1030 ′ of the drum for inputting a treatment object is formed, and a communication hole 1040 communicating with the outlet duct 1210 at the lower circumferential portion thereof. ") Is formed.

The outlet duct 1210 extends downwardly from the front supporter 1040 into the connecting duct 1230. Air dried in the drum 1030 is recovered to the connecting duct 1230 through the outlet duct 1210.

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

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

The inlet duct 1220 extends upwardly from the connecting duct 1230 to cover the rear surface of the rear supporter 1050 and communicates with the vent 1050 ′ formed in the rear supporter 1050. The rear surface of the rear supporter 1050 refers to the surface facing the rear of the clothes processing apparatus 1000. Hot dry air is supplied into the drum 1030 through the vent 1050 '.

Since the drum 1030 and the connecting duct 1230 are arranged to be spaced apart from each other along the vertical direction, the inlet duct 1220 is toward the rear of the drum 1030 from the connecting duct 1230 disposed below the drum 1030. Extend upwards. The inlet duct 1220 may also extend in the vertical direction like the outlet duct 1210, but the length of the vertical extension of the inlet duct 1220 in the connection structure is longer than that of the outlet duct 1210.

3 is a conceptual view illustrating a structure in which the drum illustrated in FIG. 1 is rotatably supported by the front supporter and the rear supporter, and FIG. 4 is a conceptual diagram illustrating the structure of the drum 1030 shown in FIG. 1 in front.

3 and 4, a drum support ring 1041 corresponding to the front opening 1030 ′ of the drum 1030 protrudes from the rear surface of the front supporter 1040 facing the drum 1030. The drum support ring 1041 is inserted into the front opening 1030 ′ of the drum 1030 to rotatably support the drum 1030.

At least two rollers 1060 are rotatably mounted to the front supporter 1040. The roller 1060 rotatably supports the drum 1030 at the bottom of the drum 1030.

The sealing pad 1080 is connected to the drum 1030 and the front supporter 1040 to prevent air from leaking into the gap between the front opening 1030 ′ of the drum 1030 and the drum support ring 1041. It may be arranged to cover the portion. The sealing pad 1080 is formed to surround the front opening 1030 ′ of the drum 1030 and the drum support ring 1041. The sealing pad 1080 may be formed of a felt material.

An opening 1040 'corresponding to the front opening 1030' of the drum 1030 is formed in the front supporter 1040, and a communication hole 1040 " is formed in the lower circumferential portion of the drum 1030. Air discharged through the front opening 1030 ′ flows into the communication hole 1040 ″.

The front supporter 1040 is equipped with a front duct connector 1210 for guiding air flowing into the communication hole 1040 "to the lower part of the drum 1030. The front duct connector 1210 is equipped with a communication hole 1040". The opening 1311 'formed in the base cabinet 1310, the opening defined by the base flow path part 1310', and the front cover 1321 are connected.

The front duct connector 1210 extends downwardly from the communication hole 1040 ". In this figure, the front duct connector 1210 is shown including the filter guide 1211 and the duct connector 1212. This figure is shown. Alternatively, the front duct connector 1210 may be formed of a single member.

The filter guide 1211 is mounted on the front supporter 1040 and inserted into the communication hole 1040 ". The filter guide 1211 may be mounted on the circumference of the front supporter 1040. The filter guide 1211 The filter unit 1240 is detachably coupled therein and configured to filter lint in the air discharged through the front opening 1030 ′ of the drum 1030.

The filter unit 1240 may include a plurality of filters. In this figure, the inner filter 1242 is inserted into the outer filter 1241, and the outer filter 1241 is inserted into the filter guide 1211 to be arranged to penetrate the communication hole 1040 ″. The number of holes of the mesh net per unit area of the outer filter 1241 and the inner filter 1242 may be configured differently. For example, the mesh of the inner filter 1242 may be formed more densely than the mesh of the outer filter 1241. Can be.

The duct connector 1212 is mounted to the front supporter 1040 and connected to the filter guide 1211. The duct connector 1212 may be mounted on the front surface of the front supporter 1040. The lower end of the filter guide 1211 may be received in the duct connector 1212.

The duct connector 1212 extends downward and is connected to an opening 1311 'formed in the base cabinet 1310, an opening defined by the base flow path portion 1310' and the front cover 1321. One side of the duct connector 1212 may extend downwardly inclined toward the opening 1311 ′ formed at one side of the base cabinet 1310.

FIG. 5 is a perspective view illustrating main parts of the base cabinet 1310 and the base cabinet 1310 illustrated in FIG. 1.

Referring to FIG. 5, a base cabinet 1310 is disposed below the drum 1030 to provide a space in which various components are mounted, including the heat pump cycle devices 1100. The bottom surface of the base cabinet 1310 may form the bottom surface of the clothing processing apparatus 1000.

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

The drum motor mounting unit 1314 is equipped with a drum motor 1800 for generating a driving force for rotating the drum 1030. A drum (not shown) for transmitting the driving force of the drum motor 1800 to the drum 1030 may be connected to the drum motor 1800. The belt is disposed to surround the outer circumference of the drum 1030.

Pulleys 1810 and springs (not shown) may be used to adjust the tension on the belt.

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

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

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

When two shafts are provided in one driving motor 1730, the driving force 1730 has many advantages in terms of improving power consumption of the clothes treating apparatus 1000. Basically, compared to the case where the driving motor 1730 for rotating the drum 1030 and the driving motor 1730 for rotating the blower fan 1820 are respectively provided, power consumption is reduced by half.

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

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

The blowing fan 1820 is rotated according to the driving of the drum motor 1800 to blow air in the internal space between the cabinet 1010 and the drum 1030. Therefore, air leaking finely into the gap between the drum 1030 and the front supporter 1040 and the gap between the drum 1030 and the rear supporter 1050 causes the internal fan to flow through the internal space. do. Therefore, the occurrence of condensation caused by the stagnation of air can be reduced.

Meanwhile, the heat dissipation fan may be mounted on the circuit board constituting the controller. The heat dissipation fan dissipates the elements mounted on the circuit board, and forms a circulating flow that circulates air in the internal space between the cabinet 1010 and the drum 1030 together with the blower fan 1820. The heat dissipation fan may be positioned above the base flow path part 1310 ′ and may be configured to blow air downward, that is, toward the base flow path part 1310 ′.

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

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

The compressor mounting unit 1315 is equipped with a compressor 1120 for generating compressed air for heat exchange. The compressor 1120 is an element constituting the heat pump cycle devices 1100, but does not need to be installed in the base flow path part 1310 ′ because it does not directly exchange heat with air. Rather, since the compressor 1120 may interfere with the flow of air if the compressor 1120 is installed in the base flow path part 1310 ', the compressor 1120 is preferably installed outside the base flow path part 1310'.

The refrigerant is evaporated (liquid-> gas) while absorbing heat from the evaporator 1110, and the refrigerant is brought into the compressor 1120 at a low temperature and low pressure gas state. The gas-liquid separator 1140 is installed upstream of the compressor 1120 based on the flow of the refrigerant. The gas-liquid separator 1140 separates the refrigerant flowing into the compressor 1120 into the gaseous phase and the liquid phase, so that only the refrigerant in the gas phase flows into the compressor 1120. According to this, the problem that the liquid refrigerant flows into the compressor 1120 and causes a failure or a decrease in efficiency can be prevented.

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

The compressor mounting unit 1315 may be provided with support ribs 1315 ″ for supporting the compressor 1120. The support ribs 1315 ″ are centers of virtual polygons formed by connecting a plurality of fixed ribs 1315 '. It may consist of a combination of portions extending radially from and portions concentric to said center.

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

The base flow path portion 1310 'forms part of the circulation flow path. Based on the air flow, the base flow path part 1310 ′ is divided into a guide part 1311, a heat exchange part 1312, and a circulation fan accommodating part 1313. An evaporator 1110 and a condenser 1130 are disposed in the heat exchange part 1312, and a circulation fan 1710 is disposed in the circulation fan accommodating part 1313 to face the condenser 1130.

The guide part 1311 corresponds to a portion into which air discharged from the front opening 1030 ′ of the drum 1030 flows. An opening opened upward is formed in the guide part 1311, and the opening communicates with the front duct connector 1210. The air flowing downward through the front duct connector 1210 is redirected from the guide portion 1311 to the rear of the base cabinet 1310 and flows into the heat exchange portion 1312.

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

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

The circulation fan accommodating part 1313 corresponds to a portion in which the circulation fan 1710 for sucking and blowing air passing through the heat exchange part 1312 is accommodated. The circulation fan 1710 is disposed so that the rotating shaft faces the condenser 1130 and the evaporator 1110, and is composed of a sirocco fan that blows the air in front of the air, that is, the condenser 1130, to the side.

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

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

A condensate recovery part 1316 is provided between the base flow path part 1310 ′ and the compressor mounting part 1315. The condensate recovery unit 1316 communicates with the base flow path unit 1310 ′, thereby forming a space in which the condensate generated in the evaporator 1110 is recovered. In this embodiment, the condensate recovery unit 1316 is configured to communicate with the heat exchange unit 1312.

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

The condensate recovery unit 1316 may protrude in a partition form on one surface of the base cabinet 1310, or may be formed in a recessed shape on one surface of the base cabinet 1310 as in the present embodiment.

The communication hole 1316 ′ communicating the heat exchange unit 1312 and the condensate recovery unit 1316 may be formed at one rear end of the condenser 1130. The condensed water generated in the evaporator 1110 falls to the bottom surface of the heat exchanger 1312 and flows into the condensed water recovery unit 1316 through the communication hole 1316 ′. The heat exchanger 1312 may be inclined toward the communication hole 1316 ′ so that the condensed water may move to the communication hole 1313a ″ by gravity.

FIG. 6 is a conceptual view illustrating a structure behind the drum 1030 illustrated in FIG. 1, and FIG. 7 is a conceptual view illustrating main parts of the rear portion of the drum 1030 illustrated in FIG. 6 by separating them, and FIG. 8 is illustrated in FIG. 6. Is a conceptual view showing the rear duct connector 1220 mounted to the circulation fan accommodating part 1313, and FIG. 9 is a view showing the rear duct connector 1220 shown in FIG. 6 coupled to the rear supporter 1050. Conceptual diagram.

6 to 9, a drum support ring 1051 corresponding to the rear opening 1030 ″ of the drum 1030 protrudes from the front of the rear supporter 1050 facing the drum 1030. The drum support ring 1051 is inserted into the rear opening 1030 ″ of the drum 1030 to rotatably support the drum 1030.

At least two rollers 1060 are rotatably mounted to the rear supporter 1050. The roller 1060 rotatably supports the drum 1030 at the bottom of the drum 1030.

In order to prevent leakage of air into the gap between the rear opening 1030 "of the drum 1030 and the drum support ring 1051, the sealing pad 1090 may be arrange | positioned so that a connection part may be covered. 1090 is formed to cover and surround the rear opening 1030 ″ and drum support ring 1051 of the drum 1030. The sealing pad 1090 may be formed of a felt material.

The rear supporter 1050 is provided with a vent 1050 'corresponding to the rear opening 1030 "of the drum 1030. The vent 1050' refers to a vertical reference line passing through the center of the rear supporter 1050. The vent hole 1050 ′ may be formed above a horizontal reference line passing through the center of the rear supporter 1050.

The rear supporter 1050 is equipped with a rear duct connector 1220 that connects the vent 1050 'spaced up and down and the exhaust port 1313 "of the circulation fan accommodating portion 1313. The rear duct connector 1220 is equipped with a rear duct connector 1220. It is formed to extend upward, and is configured to guide the air blown by the circulation fan 1710 to the vent 1050 ′ of the rear supporter 1050.

The rear duct connector 1220 may be screwed or hooked to the rear surface of the rear supporter 1050 and the circulation fan receiver 1313. In the present exemplary embodiment, the rear duct connector 1220 is hooked to the circulation fan accommodating part 1313 and is screwed to the rear surface of the rear supporter 1050.

The rear support protrusion 1050 may be formed at a portion of the rear supporter 1050 in which the rear duct connector 1220 is not disposed. Thus, the front surface of the rear supporter 1050 is recessed toward the rear relatively. The inner space of the drum 1030 may be further secured.

The rear duct connector 1220 has a first opening 1220 'which communicates with the exhaust opening 1313 "of the circulation fan accommodating portion 1313 and a second opening 1220 which communicates with the vent opening 1050' of the rear supporter 1050. ") Is formed. The first opening 1220 ′ is disposed downwardly at the lower end of the rear duct connector 1220 to face the exhaust opening 1313 ″. The second opening 1220 ″ is positioned above the first opening 1220 ′. It is positioned to face the vent 1050 'of the rear supporter 1050 by opening forward.

The interior of the rear duct connector 1220 is provided with an internal partition 1221a for reducing the eddy current and resistance of air flowing in the rear duct. In addition, a vent hole 1200 ′ is formed in the rear duct connector 1220 to allow a portion of the hot dry air flowing therein to flow out of the circulation passage 1200. These will be described later.

The rear duct connector 1220 may include a base member 1221 forming a rear portion and a cover member 1330 forming a front portion. The cover member may be screwed or hooked to the base member 1221.

The first opening 1220 ′ may be defined by the coupling of the base member 1221 and the cover member 1330. In the present embodiment, when the cover member 1330 is coupled to the base member 1221, the inner surface of the cover member 1330 defines one side of the first opening 1220 ′.

The second opening 1220 "may be formed on the front surface of the cover member 1330. The base member 1221 may be provided with an inner partition 1221a, and a part of the inner partition 1221a may be a second opening ( 1220 "through the front. In addition, a vent hole 1200 ′ may be formed in the base member 1221.

The rear cover 1070 is disposed to cover the rear duct connector 1220. The inner surface of the rear cover 1070 has a recess 1070 'recessed toward the outer surface. A recess 1050 "of the rear supporter 1050 and a rear duct connector 1220 are accommodated in the recess 1070 '. The rear supporter 1050 is mounted to the rear cover 1070.

FIG. 10 is a view illustrating an interior of the base member 1221 illustrated in FIG. 7, and FIG. 11 is a conceptual diagram for describing an effect of the inner partition 1221a illustrated in FIG. 10.

10 and 11, the base member 1221 may include a first portion extending upwardly from the first opening 1220 ′ and a second portion located above the first portion and corresponding to the second opening 1220 ″. Since the second part is formed to be wider than the first part, vortices may occur when air flows from the narrow first part to the wider second part, thereby causing a flow resistance. Will occur.

To solve this, the base member 1221 is formed with an inner partition 1221a for guiding the flow of air so that air can flow more naturally from the first portion to the second portion. A portion of the inner partition 1221a is exposed forward through the second opening 1220 ". When the cover member 1222 is coupled to the base member 1221, the inner partition 1221a contacts the inner surface of the cover member. Or adjacent the inner surface of the cover member.

The inner partition 1221a extends upwardly from one inner wall of the base member 1221. Specifically, since the width of the second portion is wider than the first portion, one inner wall of the base member 1221 extends outward at a point corresponding to the upper end of the first portion. That is, the inner partition 1221a extends upwardly at or near the one inner wall of the base member 1221 where the shape change occurs.

The inner partition 1221a is formed to be inclined in the same direction as one inner wall to guide the air to flow naturally from the first portion to the second portion. The inner partition 1221a may be disposed to be inclined upward from one inner wall of the base member 1221 toward the other inner wall.

Meanwhile, condensed water may flow into the rear duct connector 1220 due to blowing of the circulation fan 1710. However, unlike air, condensate will fall without gravity.

In order to smoothly drain the condensate, a drainage hole 1221a ′ may be formed between the inner side wall of the base member 1221 and the inner partition 1221a to prevent water drip. In the present embodiment, it is shown that the lower end of the inner partition 1221a is spaced apart from one inner wall of the base member 1221 to form the drainage hole 1221a '.

However, the present invention is not limited thereto. The inner partition 1221a extends in a branched form from one inner wall of the base member 1221, and a drainage hole 1221a ′ is formed at a lower end of the inner partition 1221a to condense the condensate.

On the other hand, a rounded portion 1221a "may be formed at an upper end of the inner partition 1221a toward the one side. In this embodiment, the rounded portion 1221a" is opposite to the extending direction of the inner partition 1221a. It is shown to be formed round in the direction. According to this, the air naturally flows in the opposite direction at the top of the inner partition 1221a so that the vortex and the flow resistance can be reduced.

Ribs 1222a are disposed on the inner surface of the cover member 1222 defining the second opening 1220 ″ to be spaced apart at regular intervals to reinforce the strength around the second opening 1220 ″. The rib 1222a may extend toward the second opening 1220 ". In this embodiment, the rib 1222a shows that the rib 1222a is vertically disposed with respect to one side defining the second opening 1220". have.

A hook hook 1221b is formed in the base member 1221, and a hook hole 1222b is formed in the cover member 1222 so that the hook hook 1221b can be latched. The locking hook 1221b may be spaced apart from each other along a circumference of the base member 1221. The cover member 1222 may be coupled to the base member 1221 by hooking the hook hook 1221b and the hook hole 1222b.

Meanwhile, the vent hole 1200 ′ may be formed at a portion where the air flowing through the inner partition 1221a flows. The vent hole 1200 ′ may be formed at one side of the base member 1221 facing the round part 1221a ″.

12 and 13 illustrate pressures in the main part of the drum 1030 and the circulation passage 1200 in the structure in which the circulation fan 1710 is disposed before the heat exchange unit 1312 based on the flow of air. Are conceptual diagrams.

As illustrated in FIG. 12, the circulation fan 1710 may be disposed in front of the heat exchanger 1312 based on the flow of air. That is, the circulation fan 1710 may be disposed in the circulation passage 1200 between the front opening 1030 ′ of the drum 1030 and the heat exchange unit 1312. The circulation fan 1710 is configured to suck air discharged from the front opening 1030 ′ of the drum 1030 and blow it into the heat exchange unit 1312.

Therefore, a negative pressure is formed in front of the circulation fan 1710 and a positive pressure is formed in the rear of the circulation fan 1710. When measuring the pressure in the main portion of the drum 1030 and the circulation passage 1200, as shown in Figure 13, it can be seen that the negative pressure is formed to the rear opening 1310 "of the drum 1030. .

That is, based on the flow of air, the sound pressure is formed to the rear opening 1310 ″ of the drum 1030, the front opening 1030 ′ of the drum 1030, and the front of the circulation fan 1710, and the circulation fan. Positive pressure is formed to the rear of the 1710 and the rear of the heat exchanger 1312.

As such, since a negative pressure is formed in both the front opening 1030 ′ and the rear opening 1310 ″ of the drum 1030, air outside the drum 1030 can rotate the drum 1030 and the drum 1030. Although it may be introduced into the drum 1030 through a gap between the front supporter 1040 and the rear supporter 1050 supporting the same, wet air in the drum 1030 may be introduced into the drum 1030 through the gap. There was little room for leakage to the outside.

However, the situation is different when the circulation fan 1710 is disposed behind the heat exchange unit 1312 based on the flow of air.

14 and 15 illustrate pressures of main parts of the drum 1030 and the circulation passage 1200 in a structure in which the circulation fan 1710 is disposed after the heat exchange unit 1312 based on the flow of air. Are conceptual diagrams.

As shown in FIG. 14, the circulation fan 1710 may be disposed in the circulation passage 1200 between the heat exchange unit 1312 and the rear opening 1310 ″ of the drum 1030. The circulation fan 1710. The air is configured to suck air passing through the heat exchange unit 1312 and to blow the air to the heat exchange unit 1312.

Therefore, a negative pressure is formed in front of the circulation fan 1710 and a positive pressure is formed in the rear of the circulation fan 1710. When measuring the pressure in the main portion of the drum 1030 and the circulation passage 1200, as shown in Figure 15, it can be seen that the negative pressure is formed to the front opening 1030 'of the drum 1030. .

That is, based on the flow of air, a negative pressure is formed to the front opening 1030 ′ of the drum 1030, the rear of the heat exchange unit 1312, and the front of the circulation fan 1710, and the rear of the circulation fan 1710. Positive pressure is formed to the rear opening 1310 ″ of the drum 1030.

As such, a negative pressure is formed in the front opening 1030 ′ of the drum 1030, but a positive pressure is formed in the rear opening 1310 ″ of the drum 1030, so that the humid air inside the drum 1030 is not exposed to the drum 1030. ) And a gap between the structure for rotatably supporting the drum 1030 (specifically, a gap between the rear opening 1310 "of the drum 1030 and the support ring 1051 of the rear supporter 1050). Leaking to the outside of the drum 1030 may occur.

Wet air leaking to the outside of the drum 1030 may cause problems such as short circuits, corrosion, and leakage of electric parts and circuit boards. In addition, the lint may leak to the outside of the drum 1030 through the gap. In this case, the lint may cause a short circuit of the electric parts or the circuit board, and may cause a bad smell when exposed to moisture for a long time.

The present invention discloses the following structure to solve this problem.

FIG. 16 is a conceptual diagram briefly showing a flow of air in the drum 1030 and the circulation passage 1200 shown in FIG. 1.

Referring to FIG. 16, a drum 1030 is rotatably installed in a cabinet 1010 forming an outer appearance of the clothes treating apparatus 1000. The drum 1030 has a shape that is opened forward and backward, and the front opening 1030 ′ and the rear opening 1310 ″ of the drum 1030 are connected by the circulation passage 1200. That is, the drum 1030 The interior and the circulation passage 1200 forms a waste passage through which air is circulated.

Air discharged from the front opening 1030 ′ of the drum 1030 is removed from the water while the circulation passage 1200 flows and is heated, and then the drum 1030 through the rear opening 1310 ″ of the drum 1030. In the circulation passage 1200, an evaporator 1110 for removing water and a condenser 1130 for heating are sequentially disposed in the air flow direction.

The air passing through the condenser 1130 has a high temperature dry property because water is removed from the evaporator 1110 and heated in the condenser 1130. On the other hand, the air before flowing into the evaporator 1110 has a relatively low temperature and high humidity because it passes through the interior of the drum 1030 in which the drying object is accommodated.

The circulation fan 1710 is disposed after the condenser 1130 based on the flow of air in the circulation passage 1200. The circulation fan 1710 is configured to suck air passing through the condenser 1130 and blow the air toward the rear side of the circulation passage 1200. As described above with reference to FIGS. 9 and 10, a positive pressure is formed from the rear of the circulation fan 1710 to the rear opening 1310 ″ of the drum 1030.

Thus, the circulation between the circulation fan 1710 and the rear opening 1310 ″ of the drum 1030 to reduce the positive pressure formed from the rear of the circulation fan 1710 to the rear opening 1310 ″ of the drum 1030. The vent hole 1200 ′ is formed in the flow path 1200. Thus, a portion of the air blown by the circulation fan 1710 flows out of the circulation passage 1200, and as a result, is formed from the rear of the circulation fan 1710 to the rear opening 1310 ″ of the drum 1030. Positive pressure is gradually reduced.

Here, the air flowing out to the outside is the air blown by the circulation fan 1710 past the condenser 1130, and has a characteristic of having a high temperature dry characteristic. That is, by depressing the hot dry air instead of the humid air inside the drum 1030 through the vent hole 1200 ′, pressure reduction may be realized.

Therefore, the humidity of the internal space between the drum 1030 and the cabinet 1010 is lowered in contrast to the leakage of the humid air inside the drum 1030. That is, the problem that the condensate falls on the inner wall or main components of the cabinet 1010 due to the leakage of wet air is reduced. As such, the amount of condensation outside the waste flow path defined by the drum 1030 and the circulation flow passage 1200 is inversely proportional to the size of the vent hole 1200 ′, that is, the area.

Therefore, short circuits of electrical parts or circuit boards by wet air leaking to the outside of the drum 1030, corrosion, leakage, short circuits of electrical parts or circuit boards due to lint leaking to the outside of the drum 1030, and odors may be reduced. have.

The size of the vent hole 1200 ′, that is, the area, and the drying performance of the clothes treating apparatus 1000 are inversely proportional. When the hot dry air escapes through the vent hole 1200 ', heat loss occurs, the drying time increases, and the energy consumption of the main components (drum 1030, driving motor, etc.) increases. to be.

The size of the vent hole 1200 ′, that is, the area and the condensation efficiency of the evaporator 1110 are proportional to each other. This is because the amount of wet air leaked through the gap between the drum 1030 and the structure for rotatably supporting the drum 1030 is reduced by the amount of air flowing out through the vent hole 1200 ′.

In view of the above, the vent hole 1200 ′ should have an appropriate size, that is, an area. The experimental results, a vent hole (1200 ') has been found to be desirable to have a surface area of 30cm ² or less than 5cm ^2.

However, when the vent hole 1200 ′ is formed in a predetermined area or more, the rigidity may be weakened. Referring to FIG. 10, the reinforcing rib 1200 ′ a may be formed to cross the vent hole 1200 ′ to reinforce rigidity. That is, the vent hole 1200 ′ may be divided into a plurality of regions by the reinforcing rib 1200 ′ a.

In addition, as described above, the present invention forms a vent hole 1200 ′ in the rear duct connector 1220 to reduce leakage of humid air and lint in the drum 1030, thereby forming the interior of the rear duct connector 1220. It is configured to discharge a portion of the hot dry air flowing through the rear duct connector 1220.

When the vent hole 1200 ′ is formed in the high pressure region inside the rear duct connector 1220, noise may occur due to a high flow rate. Accordingly, the positive pressure is always maintained inside the rear duct connector 1220, but the pressure is relatively low compared to other portions, and the vent hole 1200 'is formed at a portion where the pressure difference is almost constant regardless of whether the filter unit 1240 is blocked. It is preferable that this be formed.

In consideration of this, the vent hole 1200 ′ may be formed at an upper end portion of the rear duct connector 1220, and in particular, a portion through which the air flowing through the inner partition wall 1221a flows (see FIGS. 7 to 11). In addition, the vent hole 1200 ′ may be formed at one side of the base member 1221 facing the round part 1221 a ″. That is, the vent hole 1200 ′ is formed to face the round part 1221 a ″. Can be.

17 and 18 are conceptual views of a clothes treating apparatus according to another embodiment of the present invention. 18 shows when the pressure difference between the inside and the outside of the drum 2030 is large.

As described above, a vent hole 1200 'is formed in the circulation passage 1200 between the circulation fan 1710 and the rear opening 1310 " However, since the opening of the vent hole 1200 'at all times adversely affects the drying performance of the clothes treating apparatus 1000, a structure in which the vent hole 1200' is opened only when necessary may be considered. have.

Thus, the structure further includes a cover 2201 configured to selectively open and close at least a part of the vent hole 2200 'in addition to the above-described structure. The cover 2201 may be rotatably connected to the circulation passage 2200 by the hinge 2201a. The amount of air flowing out through the vent hole 2200 'by opening and closing the cover 2201 is variable. Opening and closing of the cover 2201 may be performed based on a pressure difference between the inside and the outside of the drum 2030.

The cover 2201 is rotatably connected to the circulation passage 2200 to selectively open and close at least a part of the vent hole 2200 ', so that drying performance may be improved compared to a structure in which the vent hole 2200' is always opened. Can be.

The opening and closing of the cover 2201 may be naturally performed by the gravity and the pressure difference between the inside and the outside of the drum 2030 without a separate device. Specifically, the cover 2201 is disposed to cover the vent hole 2200 'by gravity, and is configured to open the vent hole 2200' when the pressure difference between the inside and the outside of the drum 2030 is greater than gravity. That is, when the pressure difference between the inside and the outside of the drum 2030 is greater than gravity, the cover 2201 is rotated to open the vent hole 2200 ', and the pressure difference between the inside and the outside of the drum 2030 is less than the gravity. The cover 2201 is disposed to cover the vent hole 2200 ′. In this figure, the cover 2201 is disposed so as to completely cover the vent hole 2200 'in a closed state.

As the pressure difference between the inside and the outside of the drum 2030 increases, the rotation angle of the cover 2201 increases. That is, as the pressure difference between the inside and the outside of the drum 2030 increases, the amount of air flowing out through the vent hole 2200 'increases.

Meanwhile, a blower fan 2820 for circulating air in the inner space may be provided in the inner space between the cabinet 2010 and the drum 2030. As a result, air in the internal space circulates to prevent condensation in a specific portion.

In addition, the cabinet 2010 may include an exhaust fan 2730 for discharging air in the internal space to the outside of the cabinet 2010. Therefore, the air discharged into the inner space between the cabinet 2010 and the drum 2030 through the vent hole 2200 ′ may be finally discharged to the outside of the clothes treating apparatus 2000.

In the following, modifications of the above-described structure will be described.

19 is a conceptual diagram of a clothes treating apparatus 3000 according to another embodiment of the present invention.

Referring to FIG. 19, opening and closing of the cover 3201 may be implemented by the sensing unit 3450 and the controller.

Specifically, the sensing unit 3450 is configured to sense a pressure difference between the inside and the outside of the drum 3310. The sensing unit 3450 includes a first sensor 3451 installed in the drum 3310 and a second sensor 3452 installed outside the drum 3310.

The first sensor 3451 is disposed to cover the rear opening 3310 ″ of the drum 3310 and may be installed in the rear supporter 3050 having a fixed configuration. The first sensor 3501 is provided with a vent 3050 '. May be disposed adjacent to).

The second sensor 3452 may be disposed adjacent to the rear supporter 3050. The second sensor 3452 may be installed on an inner surface of the cabinet 3010.

The controller controls the rotation of the cover 3201 based on the pressure difference between the inside and the outside of the drum 3310 sensed by the sensing unit 3450. In detail, the controller compares the values sensed by the first sensor 3401 and the second sensor 3452, and when the difference is greater than or equal to a preset pressure, the cover 3201 may open the vent hole 3200 ′. The cover 3201 is rotated to open. In addition, the controller compares the values sensed by the first sensor 3401 and the second sensor 3452, and the cover 3201 covers the vent hole 3200 ′ when the difference between the values is less than the preset pressure. The cover 3201 is rotated.

20 is a conceptual diagram of a clothes treating apparatus according to another embodiment of the present invention.

Referring to FIG. 20, a protrusion 4201b supported around the vent hole 4200 ′ is formed to protrude from the cover 4201 in a state where the cover 4201 is closed. As the projection 4201b is supported around the vent hole 4200 ', the cover 4201 forms a gap 4200 "between the circulation flow path 4200. The projection 4201b has a stick shape at least at one point. It may be formed to protrude, or may be formed to extend in the form of a rib.

The protrusion 4201b may protrude from the circulation passage 4200 instead of the cover 4201. That is, the protrusion 4201b may protrude from the periphery of the vent hole 4200 ′ to support the cover 4201 when the cover 4201 is closed.

According to the above structure, since the cover 4201 is not disposed to completely cover the vent hole 4200 ′, the waste flow path defined by the drum 4310 and the circulation flow passage 4200 is always in the cabinet 4010 and the drum 4310. It communicates with the internal space between them. On the other hand, the inner space is configured to communicate with the outside of the cabinet 4010.

That is, the waste flow passage is always in communication with the outside of the cabinet 4010. Therefore, even if an infant or a pet is trapped inside the drum 4310, breathing may be performed, and asphyxiation may be prevented.

The clothes treating apparatus described above is not limited to the configuration and method of the above-described embodiments, and the above embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

Claims (15)

A drum having a shape of opening and closing in front and rear and accommodating clothes;
A front supporter rotatably supporting the drum at a front side of the drum, the front supporter having a communication hole communicating with the front opening of the drum;
A rear supporter rotatably supporting the drum at a rear side of the drum, the rear supporter having a vent communicating with the rear opening of the drum;
A circulation passage connecting the communication hole and the vent to form a path for allowing air discharged from the front opening of the drum to enter the rear opening of the drum through an evaporator and a condenser;
A circulation fan disposed after the condenser on the basis of the flow of air in the circulation passage, for sucking and blowing air passing through the condenser; And
And a vent hole formed in the circulation passage between the circulation fan and the vent so that a part of the air blown by the circulation fan flows out of the circulation passage. The method of claim 1,
Garment processing apparatus, characterized in that the area of the vent hole is 5cm ² or more and 30cm ² or less. The method of claim 1,
And a cover rotatably connected to the circulation passage and configured to selectively open and close at least a portion of the vent hole. The method of claim 3,
The cover is disposed so as to cover the vent hole by gravity, when the pressure difference between the inside and outside of the drum is greater than gravity is rotated to open the vent hole. The method of claim 4, wherein
And the rotation angle of the cover increases as the pressure difference between the inside and the outside of the drum increases. The method of claim 3,
A sensing unit for sensing a pressure difference between the inside and the outside of the drum; And
And a control unit which controls the rotation of the cover based on the pressure difference sensed by the sensing unit. The method of claim 3,
And the cover is disposed to completely cover the vent hole in a closed state. The method of claim 3,
The cover has a clothing processing apparatus, characterized in that the projection is formed around the vent hole in the closed state to form a gap between the circulation passage and the cover. The method of claim 3,
The circulation passage is formed in the clothing processing apparatus, characterized in that the protrusion protruding from the periphery of the vent hole to support the cover in a state in which the cover is closed to form a gap between the circulation passage and the cover. The method of claim 1,
A cabinet accommodating the drum and the circulation passage and forming an appearance of the clothes treating apparatus;
A blowing fan provided in an internal space between the cabinet and the drum to circulate air in the internal space; And
And an exhaust fan installed in the cabinet and discharging air in the internal space to the outside of the cabinet. cabinet;
A drum rotatably installed in the cabinet, the drum having a form opened forward and backward;
A circulation passage forming a path for allowing air discharged from the front opening of the drum to enter the rear opening of the drum via an evaporator and a condenser;
A circulation fan disposed after the condenser on the basis of the flow of air in the circulation passage, for sucking and blowing air passing through the condenser;
A vent hole formed in the circulation passage between the circulation fan and the rear opening of the drum; And
And a cover rotatably connected to the circulation passage and configured to selectively open and close at least a portion of the vent hole. The method of claim 11,
The cover,
If the pressure difference between the inside and outside of the drum is greater than gravity, it is rotated to open the vent hole,
And a pressure difference between the inside and the outside of the drum is less than gravity, so as to cover the vent hole. The method of claim 11,
A sensing unit for sensing a pressure difference between the inside and the outside of the drum; And
And a control unit which controls the rotation of the cover based on the pressure difference sensed by the sensing unit. The method of claim 11,
The cover has a clothing processing apparatus, characterized in that the projection is formed around the vent hole in the closed state to form a gap between the circulation passage and the cover. The method of claim 11,
A blowing fan provided in an internal space between the cabinet and the drum to circulate air in the internal space; And
And an exhaust fan installed in the cabinet and discharging air in the internal space to the outside of the cabinet.

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