KR20220085404A - Dishwasher - Google Patents

Abstract

The present invention relates to a dishwasher, and according to an embodiment of the present invention, a dishwasher includes a washing tank in which a washing object is accommodated and washing water is sprayed; a sump disposed below the washing tank and storing the washing water; and a softening device disposed between an external water source for supplying the washing water to the sump and the sump, wherein the softening device includes: a filter having an ion exchange resin stored therein and connected to the external water source; and a regenerator that stores a regenerator for removing foreign substances adsorbed on the ion exchange resin and is connected to the sump, wherein the regenerator is a valve device for selectively flowing the washing water to the ion exchange resin or the regenerant. It is detachably connected to the filter through the , and by disposing the filter and the regenerator separately, there is an advantage in that the space occupied by the water softener is reduced.

Description

Dishwasher {Dishwasher}

The present invention relates to a dishwasher, and more particularly, to a water softener.

A dishwasher is a device that sprays washing water and steam to a washing target accommodated inside a cabinet to remove foreign substances and bacteria on the washing target.

In order to prevent cations contained in the washing water from forming stains on the object to be washed, a water softener for softening the supplied washing water is disposed in the dishwasher.

However, in the conventional water softener, the ion exchange resin and the rejuvenating agent are disposed in the same space, causing interference with other parts disposed in the space, and there is a limitation in reducing the size of the product by reducing the volume of the space. there was.

Korean Patent No. 10-2125724 discloses a water softener disposed in a dishwasher, but by providing a water supply storage tank separately from the ion exchange tank, there is a problem in that the volume of the water softener becomes excessively large.

Korean Publication No. 10-2018-0044254 discloses a water softening device for separately storing the ion exchange resin and the regenerant, but a separate pump is provided for circulating the washing water between the storage space of the ion exchange resin and the storage space of the regenerant. However, there was a problem in that the equipment cost was excessive.

Korea Registered Patent 10-2125724 Korean Publication 10-2018-0044254

An object of the present invention is to provide a dishwasher in which a space occupied by a water softener is reduced.

Another object of the present invention is to provide a dishwasher having a water softener having an optimized flow path design.

Another object of the present invention is to provide a dishwasher having a water softener in which a regenerating agent input flow path is simplified.

Another object of the present invention is to provide a spatially compact dishwasher.

Another object of the present invention is to provide a dishwasher having a water softener with improved softening efficiency.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, a dish washing machine according to an embodiment of the present invention includes: a washing tank in which a washing object is accommodated and washing water is sprayed; a sump disposed below the washing tank and storing the washing water; and a water softening device disposed between an external water source for supplying the washing water to the sump and the sump.

The water softener includes: a filter having an ion exchange resin stored therein and connected to the external water source; and a regenerator that stores a regenerating agent for removing foreign substances adsorbed on the ion exchange resin and is connected to the sump.

The regenerator is detachably connected to the filter through a valve device that selectively controls the flow of the washing water to the ion exchange resin or the regenerant, so that the filter and the regenerator are separated and the washing water flows through the valve device at the same time direction can be adjusted.

The filter may be disposed to face a side wall of the washing tub, and the regenerator may be disposed to face a lower wall of the washing tub, so that the water softener may be compactly coupled to the washing tub.

The valve device may be disposed to face an edge formed by connecting a side wall and a lower wall of the washing tank.

The valve device may include a main valve for controlling a flow direction of the washing water; and a sub-valve for blocking the reverse flow of the washing water between the filter and the regenerator, so that the flow direction of the washing water can be adjusted through the valve device.

The sub-valve may include: a first sub-valve blocking the flow of the washing water from the filter to the regenerator; and a second sub-valve blocking the flow of the washing water from the filter to the main valve, thereby reducing wasted washing water.

The valve device may include: a hub on which the main valve is movably disposed; a first passage communicating with the hub through a first hub hole formed in the hub and extending toward the ion exchange resin; a second flow passage communicating with the hub through a second hub hole formed in the hub and extending toward the rejuvenating agent; and a third flow path in which the sub-valve is movably disposed and extends from the regenerator toward the ion exchange resin, so as to adjust the direction of the washing water flowing through the main valve to the first, second, and third flow paths. can

The softening device may be operated in a general training mode in which the rejuvenating agent is not added to the washing water or in a regenerative training mode in which the rejuvenating agent is added to the washing water, and the main valve may cause the water softening device to operate in the normal training mode. When done, the second hub hole may be closed.

The main valve may close the first hub hole when the water softener is operated in the regeneration training mode.

The filter may include: an inflow passage connected to the external water source; and a container disposed separately from the acquisition flow path and storing the ion exchange resin.

The washing water introduced into the filter may be introduced into the valve device through the acquisition passage, and may flow from the valve device toward the container.

The filter may include an outlet water passage formed to surround at least a portion of the container.

The container may increase in width toward the upper side.

The container may include a first guide extending in the vertical direction and forming a space inside which the ion exchange resin is stored.

The container may include a second guide protruding from the space in which the ion exchange resin is stored.

The filter may include a block disposed to cover the acquisition flow path and the container.

The block may be in contact with the guide protruding from the container, thereby protecting the ion exchange resin.

The filter may include a flow meter disposed in the acquisition flow path.

The filter may include a barrier extending in a direction crossing the vertical direction and forming a space in which the ion exchange resin is stored therein, thereby preventing the ion exchange resin from flowing down.

The regenerator may include a supply passage connected to the sump and through which the washing water passing through the ion exchange resin flows, so that the washing water passing through the filter may be guided to the sump through the regenerator.

The regenerator may include: a first regeneration passage through which the washing water that has passed through the valve device is introduced; and a second regeneration passage through which the washing water introduced through the first regeneration passage flows toward the filter.

The regenerator may include a rejuvenating agent box that forms a space in which the rejuvenating agent is stored, and whose width increases from the first regenerating flow path toward the second regenerating flow path.

The details of other embodiments are included in the detailed description and drawings.

According to the dishwasher of the present invention, there are one or more of the following effects.

First, by arranging the filter and the regenerator separately, there is an advantage in that the space occupied by the water softener is reduced.

Second, there is also the advantage of optimizing the flow path design by controlling the washing water flowing in the filter and the regenerator through the valve device.

Third, there is an advantage in that the input flow path of the regenerant can be simplified by changing the flow path through the main valve.

Fourth, by attaching the filter and the regenerator to the wall of the washing tub, there is an advantage that the dishwasher can be compacted by utilizing the outer space of the washing tub.

Fifth, by utilizing the space in the filter as a storage space for the ion exchange resin, there is an advantage in that the softening efficiency is improved through a large amount of ion exchange resin.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view of a dishwasher according to an embodiment of the present invention.
2 is a longitudinal cross-sectional perspective view of a dishwasher according to an embodiment of the present invention.
3 is a cross-sectional perspective view of a dishwasher according to an embodiment of the present invention.
4 shows a washing tank and a water softener according to an embodiment of the present invention.
5 is a top perspective view of a washing tank and a water softener according to an embodiment of the present invention.
6 is a perspective view of a water softener according to an embodiment of the present invention.
7 is a perspective view of a filter according to an embodiment of the present invention.
8 is an exploded perspective view of a filter according to an embodiment of the present invention.
9 is a front view of a filter according to an embodiment of the present invention.
10 is a perspective view of a regenerator according to an embodiment of the present invention;
11 is an exploded perspective view of a regenerator according to an embodiment of the present invention.
12 is a view for explaining the connection relationship between the water softener and the sump according to an embodiment of the present invention.
13 is a diagram showing the internal structure of a regenerator according to an embodiment of the present invention.
14 is a view for explaining the flow of washing water in the general training mode according to an embodiment of the present invention.
Figure 15 (a) is a view for explaining the opening and closing state of the valve device in the general training mode according to an embodiment of the present invention.
Figure 15 (b) is a view for explaining the opening and closing state of the valve device in the general training mode according to another embodiment of the present invention.
16 is a view for explaining the flow of washing water in the regeneration training mode according to an embodiment of the present invention.
Figure 17 (a) is a view for explaining the opening and closing state of the valve device in the regeneration training mode according to an embodiment of the present invention.
Figure 17 (b) is a view for explaining the opening and closing state of the valve device in the regeneration training mode according to another embodiment of the present invention.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform those who have the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

Hereinafter, the present invention will be described with reference to the drawings for explaining the dishwasher according to embodiments of the present invention.

Referring to FIG. 1 , the overall appearance of the dishwasher 1 will be described first. 1 shows the overall appearance of the dishwasher 1 .

The dishwasher 1 includes a cabinet 10 having a washing tub 100 (refer to FIG. 2 ) for accommodating a washing object therein; and a door 20 disposed in front of the cabinet 10 .

The cabinet 10 may form the external shape of the dishwasher 1 and may have a square column shape. The front of the cabinet 10 may be opened, and the object to be washed may be introduced into the washing tub 100 through the opened portion of the cabinet 10 .

The door 20 may open or close the opened portion of the cabinet 10 . The door 20 may close the opened portion to seal the washing tub 100 , and may open the opened portion to allow the washing tub 100 to communicate with the outside of the cabinet 10 .

The door 20 may be connected to the cabinet 10 to be vertically movable. The door 20 includes a door body 21 forming an outer shape of the door 20; It may include a lower door 22 connected to the door body 21 so as to be movable up and down.

The door body 21 may be disposed to be movable up and down with respect to the cabinet 10 , and a guide member (not shown) for vertical motion of the door body 21 may be disposed therein.

The lower end 20b of the lower door 22 may be the lowermost end of the door 20, and the lower door 22 is moved vertically from the door body 21 to protrude downward from the lower surface of the cabinet 10. can

The dishwasher 1 may include a control panel 30 connected to the door 20 to be vertically movable. The control panel 30 may be a display that displays driving information of the dishwasher 1 and can select an administrative course of the dishwasher 1 . The control panel 30 may be connected to the door 20 so as to be vertically movable, and constitute the front surface of the door 20 . The upper end 20a of the control panel 30 may be the uppermost end of the door 20 , and the control panel 30 moves vertically from the door body 21 to protrude upward from the upper surface of the cabinet 10 . can

Hereinafter, an internal structure of the washing tank 100 will be described with reference to FIG. 2 . FIG. 2 is a view showing the form in which the dishwasher 1 shown in FIG. 1 is cut in the vertical direction and viewed from the side.

In the washing tank 100, the washing object is accommodated, and washing water is sprayed. The washing tank 100 is disposed inside the cabinet 10 and forms a washing space 100S in which a washing object is accommodated.

A driving unit 200 for circulating the washing water is disposed under the washing tank 100 . The driving unit 200 may be disposed inside the cabinet 10 . The driving unit 200 forms a driving space 200S in which structures for circulation of washing water, which will be described later, are disposed.

In the washing tub 100, the upper rack 110 on which the object to be washed is seated, and the lower rack 120 on which the object to be washed is seated, which is disposed below the upper rack 110, may be arranged.

A plurality of spray tubes 150 , 160 , 170 for spraying washing water toward the washing target seated on the upper rack 110 and the lower rack 120 may be disposed inside the washing tank 100 . The spray tubes 150 , 160 , 170 may have a rod shape extending in the width direction of the racks 110 and 120 , and may have a rotation shaft extending in the width direction of the racks 110 , 120 . The injection tube (150, 160, 170), the rack (110, 120) and two types of frames arranged in parallel may be cross-shaped formed by crossing, may have a rotation shaft extending in the vertical direction.

The injection tubes 150 , 160 , 170 may have the shape of a tube and be disposed on the lower side of the upper rack 110 or the lower side of the lower rack 120 .

In the washing tank 100 , a driving assembly 162 for rotating the spray tube 160 may be disposed. The driving assembly 162 may be connected to the racks 110 and 120 and the injection tube 160, respectively.

A plurality of injection tubes (150, 160, 170), and the lower injection tube 150 disposed on the lower side of the lower rack (120); an upper injection tube 160 disposed between the upper rack 110 and the lower rack 120; It may include a top spray tube 170 disposed on the upper side of the upper rack (110).

Each of the plurality of injection tubes 150 , 160 , 170 may receive washing water from a washing pump 220 (see FIG. 3 ), which will be described later. The injection pipe 130 extending from the driving unit 200 may be disposed inside the washing tank 100 .

The injection pipe 130 may extend from the washing pump 220 , and branch and extend toward the upper injection tube 160 and the top injection tube 170 , respectively.

The upper injection tube 160 may be connected to the injection pipe 130 to receive washing water through the injection pipe 130 . The top injection tube 170 may be connected to the injection pipe 130 to receive washing water through the injection pipe 130 .

The lower spray tube 150 may be connected to a distribution chamber 240 (see FIG. 3 ) to be described later, and receive washing water through the distribution chamber 240 .

Spray nozzles 151 , 161 , and 171 for supplying washing water into the washing tank 100 may be formed in each of the plurality of injection tubes 150 , 160 , and 170 .

A lower injection nozzle 151 protruding toward the lower rack 120 may be formed in the lower injection tube 150 , and the lower injection nozzle 151 is a plurality of spaced apart in the longitudinal direction of the lower injection tube 150 . can be formed. The lower spray tube 150 may be rotatably disposed in the washing tub 100 , and may be rotated using an upper and lower shaft as a rotation axis to spray the washing water toward the lower portion of the lower rack 120 .

An upper injection nozzle 161 protruding toward the upper rack 110 may be formed in the upper injection tube 160 , and a plurality of the upper injection nozzles 161 are spaced apart from each other in the extending direction of the upper injection tube 160 . can be formed. The upper spray tube 160 may be rotatably connected to the washing tub 100 , and rotated in the front-rear direction as a rotation axis to spray the washing water into the lower part of the upper rack 110 .

A top spray nozzle 171 protruding toward the inside of the washing tank 100 may be formed in the top spray tube 170 . The top spray tube 170 may be rotatably disposed on the upper side of the washing tub 100 , and may evenly spray the washing water toward the inside of the washing tub 100 .

A steam spray nozzle 180 for supplying steam to the inside of the washing tub 100 may be disposed inside the washing tub 100 . The steam spray nozzle 180 may be disposed in front of the washing tank 100 adjacent to the door 20 . The steam injection nozzle 180 may be disposed to face the lower rack 120 .

The steam spray nozzle 180 may be connected to a heater 230 of a driving unit 200 to be described later, and receive steam generated from the heater 230 .

The washing space 100S may be defined as a space in which a washing object, a plurality of spray tubes 150 , 160 , 170 , and a steam nozzle 180 are disposed, and the driving space 200S is the washing space 100S. It may be defined as a space for circulation of the washing water formed on the lower side.

The washing space 100S may mean an internal space of the washing tub 100 and may occupy a space equal to the first height H1.

The driving space 200S may mean an internal space of the driving unit 200 and may occupy a space equal to the second height H2.

The height of the cabinet 10 may be the sum of the first height H1 and the second height H2 , and may be the sum of the heights occupied by the washing space 100S and the driving space 200S.

The height H1 of the washing space 100S may be greater than the height H2 of the driving space 200S.

In order to reduce the height of the cabinet 10 while maintaining the height H1 of the washing space 100S, the height H2 of the driving space 200S may be lowered.

Hereinafter, an internal structure of the driving unit 200 will be described with reference to FIG. 3 . 3 is a view illustrating the internal structure of the driving space 200S as viewed from the upper side to the lower side.

The driving unit 200 is disposed below the washing tub 100 and includes a sump 210 accommodating washing water, connected to the sump 210 , and extruding washing water contained in the sump 210 toward the washing tub 100 . It may include a pump 220, a heater 230 connected to the washing pump 220 and the injection nozzles 151, 161, and 171, respectively, and having a space in which the washing water is heated.

The driving unit 200 is connected to the injection nozzles 151 , 161 , 171 and the heater 230 , respectively, the distribution chamber 240 is spaced apart from the washing pump 220 , and the sump 210 is spaced apart from each other. A drain pump 250 may be further included.

The driving unit 200 includes a water softener 300 connected to the sump 210 .

The sump 210 may provide a space in which the washing water sprayed to the washing object through the jet nozzles 151 , 161 , and 171 is accommodated. In the sump 210 , a sump hole 210s communicating with the washing tub 100 may be formed, and the sump hole 210s may be opened in the vertical direction.

The sump 210 may include a filter 211 for filtering out foreign substances contained in the washing water. The filter 211 may be disposed to surround the sump hole 210s. Washing water flowing into the sump 210 from the washing tank 100 may flow toward the washing pump 220 with foreign substances removed through the filter 211 .

The drain pump 250 may be connected to the sump 210 to discharge the washing water contained in the sump 210 to the outside of the cabinet 10 . The sump 210 may be connected to the drain pump 250 through the drain pipe 253 , and washing water and foreign substances accommodated in the sump 210 may be moved toward the drain pump 250 through the drain pipe 253 .

The drain pump 250 may be connected to the washing water discharge pipe 254 . The washing water discharge pipe 254 may communicate with the outside of the cabinet 10 . The drain pump 250 may suck in the washing water and foreign substances in the sump 210 through the drain pipe 253 , and may extrude it out of the cabinet 10 through the washing water discharge pipe 254 .

The water softener 300 is connected to the external water source 50 and the sump 210 , respectively, and supplies the washing water supplied from the external water source 50 to the sump 210 . The water softener 300 may remove ions contained in the washing water supplied from the external water source 50 and supply it to the sump 210 .

The sump 210 may be connected to the water softener 300 through the sump inlet pipe 213 . The sump 210 may receive the softened washing water from which ions are removed through the sump inlet pipe 213 .

The washing pump 220 may be connected to the sump 210 through the pump inlet pipe 223 . The washing pump 220 may be connected to the heater 230 through the heater inlet pipe 233 .

The washing pump 220 may suck the washing water contained in the sump 210 through the pump inlet pipe 223 and extrude it to the heater 230 through the heater inlet pipe 233 .

The heater 230 may be connected to the washing pump 220 through the heater inlet pipe 233 , and may be connected to the distribution chamber 240 through the heater discharge pipe 234 .

The heater 230 may heat the washing water flowing in from the washing pump 220 to make it a hot water state. The washing water in the hot water state may be introduced into the distribution chamber 240 through the heater discharge pipe 234 .

The heater 230 may heat the washing water flowing in from the washing pump 220 to a steam state. The washing water in the steam state may be introduced into the steam nozzle 180 through the steam nozzle inlet pipe 183 . The washing water in the steam state introduced into the steam nozzle 180 may be sprayed toward the washing object accommodated in the washing tub 100 .

The distribution chamber 240 may be connected to the heater 230 through the heater discharge pipe 234 . The distribution chamber 240 may receive liquid washing water heated by the heater 230 .

The distribution chamber 240 may have a plurality of distribution holes 241 opened vertically. The distribution chamber 240 may supply the washing water to the spray tubes 150 , 160 , 170 through the plurality of distribution holes 241 . Any one of the plurality of distribution holes 241 may be in communication with the lower injection tube 150 . The other one of the plurality of distribution holes 241 may communicate with the upper injection tube 160 or the top injection tube 170 through the injection pipe 130 . The washing water introduced into the distribution chamber 240 may flow to the lower injection tube 150 through one of the distribution holes 241, and through the other distribution hole 241, the upper injection tube 160 or It may flow to the top spray tube 170 .

The lower injection tube 150 may be directly inserted into the distribution hole 241 to be connected to the distribution chamber 240 , or may be connected to the distribution chamber 240 through a separate tube inserted into the distribution hole 241 .

The upper injection tube 160 and the top injection tube 170 may be connected to the distribution chamber 240 through the injection tube 130 inserted into the distribution hole 241 .

The distribution chamber 240 may selectively supply the introduced washing water to the lower injection tube 150 , the upper injection tube 160 , and the top injection tube 170 . The distribution chamber 240 may supply washing water only through any one of the plurality of distribution holes 241 , or may supply the washing water through a plurality of the plurality of distribution holes 241 .

The sump 210 , the washing pump 220 , the heater 230 , the distribution chamber 240 , the drain pump 250 , and the water softener 300 may be disposed to be horizontally spaced apart from each other. . The sump 210 , the washing pump 220 , the heater 230 , the distribution chamber 240 , the drain pump 250 , and the water softener 300 may be arranged such that at least some of them are located at the same height. can

A direction for describing the positional relationship of each structure within the driving unit 200 is defined. The direction in which the door 20 is disposed is the front, the direction opposite to the door 20 is the rear, the left when the door 20 is viewed from the front is the left, and the right when the door 20 is viewed from the front defined as right The front and rear or left and right sides defined herein may be equally applied to the content to be described later.

The water softener 300 may be disposed on the left side of the driving unit 200 . The sump inlet pipe 213 may extend in the left and right directions to connect the water softener 300 and the sump 210 . The sump 210 may be disposed on the right side of the water softener 300 .

The drain pump 250 may be disposed on the left side of the sump 210 . The drain pump 250 may be disposed behind the sump 210 . The drain pipe 253 may extend left and rearward from the sump 210 , and may connect the sump 210 and the drain pump 250 .

The washing water discharge pipe 254 may extend to the rear left from the drain pump 250 and may be connected to the cabinet 10 .

The pump inlet pipe 223 may extend in the left and right directions to connect the sump 210 and the washing pump 220 . The pump inlet pipe 223 may extend in a direction crossing the drain pipe 213 . The pump inlet pipe 223 may extend in a direction parallel to the sump inlet pipe 213 .

The heater inlet pipe 233 may extend in the front-rear direction to connect the washing pump 220 and the heater 230 . The heater inlet pipe 233 may extend in a direction crossing the pump inlet pipe 223 .

The heater discharge pipe 234 may extend in the left and right directions to connect the heater 230 and the distribution chamber 240 . The heater discharge pipe 234 may extend in a direction crossing the heater inlet pipe 233 . The heater discharge pipe 234 may extend in a direction parallel to the pump inlet pipe 223 . The heater discharge pipe 234 and the pump inlet pipe 223 may be disposed to face each other in the front and rear directions.

The sump 210 may be disposed to face the washing pump 220 in the left and right directions. The sump 210 may be disposed to face the distribution chamber 240 in the front-rear direction. The washing pump 220 may be disposed on the right side of the sump 210 . The distribution chamber 240 may be disposed behind the sump 210 .

The washing pump 220 may be disposed to face the heater 230 in the front-rear direction. The heater 230 may be disposed behind the washing pump 220 . The distribution chamber 240 may be disposed to face the heater 230 in the left and right directions. The distribution chamber 240 may be disposed to face the drain pump 250 in the left and right directions. The heater 230 may be disposed on the right side of the distribution chamber 240 . The drain pump 250 may be disposed on the left side of the distribution chamber 240 .

Due to the above-described structure, the flow path structure connecting the drain pipe 253 , the pump inlet pipe 223 , the heater inlet pipe 233 , and the heater discharge pipe 234 may be configured in a 'U' shape. Accordingly, the drain pump 250 , the sump 210 , the washing pump 220 , the heater 230 , and the distribution chamber 240 can all be disposed in a dense space within the driving unit 200 , thereby increasing spatial utilization.

Hereinafter, a form in which the water softener 300 is disposed in the washing tank 100 will be described with reference to FIGS. 4 and 5 . 4 shows the washing tub 100 to which the water softening device 300 is coupled, and FIG. 5 shows the washing tub 100 to which the water softening device 300 is coupled, viewed through the top from above.

The overall appearance of the washing tub 100 may be a square pillar shape with an open front. The washing tank 100 may form a washing space 100S in which a washing object is disposed inside surrounded by the outer walls 101 , 102 , 103 , 104 .

The washing tank 100 includes an upper wall 101 covering the upper side of the washing space 100S, a lower wall 102 opposite to the upper wall 101, and a side wall 103 connecting the upper wall 101 and the lower wall 102. , 104) may be included. The side walls 103 and 104 are a first side wall 103 connecting one side of the upper wall 101 and the lower wall 102, and a second side wall 104 connecting the other side of the upper wall 101 and the lower wall 102. can be divided into

The sump 210 may be disposed below the lower wall 102 and may be connected to the lower wall 102 . The sump 210 may communicate with the washing space 100S through the lower wall 102 . The sump hole 210s may communicate with the washing space 100S through the lower wall 102 .

The side wall 103 and the lower wall 102 may extend in a direction crossing each other to form an edge 105 . The edge 105 may extend forward and backward to connect the side wall 103 and the lower wall 102, and may be formed to be curved in the vertical direction.

The water softener 300 includes a filter 310 in which an ion exchange resin (E) is stored, a regenerator 320 in which a regenerating agent for removing foreign substances adsorbed to the ion exchange resin (E) is stored, and a filter 310 ) and a valve device 330 for connecting the regenerator 320 .

The filter 310 may be disposed on the outside of the sidewall 103 to face the sidewall 103 . The filter 310 may be disposed in parallel with the sidewall 103 , and may be spaced apart from the sidewall 103 . The filter 310 may be attached to the outer surface of the side wall 103 and fixed to the washing tub 100 .

The regenerator 320 may be disposed on the lower side of the lower wall 102 to face the lower wall 102 . The regenerator 320 may be arranged in parallel with the lower wall 102 , and may be spaced apart from the lower wall 102 . The regenerator 320 may be attached to the lower side of the lower wall 102 and fixed to the washing tank 100 .

The valve device 330 may be disposed on the outside of the edge 105 to face the edge 105 . The valve device 330 may be disposed parallel to the edge 105 , and may be spaced apart from the outside of the edge 105 . The valve device 330 may be attached to the outer surface of the edge 105 and fixed to the washing tank 100 .

The lower wall 102 and the side wall 103 may extend in a direction perpendicular to each other. The filter 310 and the regenerator 320 may be connected in a direction perpendicular to each other. The filter 310 and the regenerator 320 may be connected to each other through the valve device 330 at a position corresponding to the edge 105 of the washing tank 100 .

The regenerator 320 may be formed with an upper boss 329 protruding upward. The upper boss 329 may be opened up and down, and the rejuvenating agent may be introduced into the regenerator 320 through the upper boss 329 .

The upper boss 329 may be fixed to the washing tub 100 through the lower wall 102 . The regenerator 320 may be fixed to the washing tank 100 by the upper boss 329 passing through the lower wall 102 .

The water softener 300 may be connected to the sump 210 through the sump inlet pipe 213 . The sump 210 may receive the washing water softened through the filter 310 through the sump inlet pipe 213 .

Hereinafter, the overall structure of the water softener 300 will be described with reference to FIG. 6 . FIG. 6 shows the softening apparatus 300 in which the filter 310 and the regenerator 320 are combined.

The filter 310 is separated from the acquisition port 311a connected to the external water source 50 to be described later, the acquisition flow path 311 through which the washing water introduced through the acquisition port 311a flows, and the acquisition flow path 311 It may include a container 312 in which the ion exchange resin (E) is stored and an outlet flow path 313 formed to surround at least a portion of the container 312 .

The filter 310 may include a valve device 330 connected to the regenerator 320 . However, the valve device 330 may be manufactured integrally with the filter 310 or may be manufactured separately from the filter 310 .

The washing water introduced into the acquisition port 311a may be introduced into the valve device 330 through the acquisition flow path 311 .

The valve device 330 may selectively supply the washing water introduced into the valve device 330 through the acquisition passage 311 to the container 312 or the regenerator 320 .

The washing water introduced into the valve device 330 may flow toward the container 312 and may pass through the ion exchange resin E stored in the container 312 .

Washing water softened by passing through the ion exchange resin (E) may be introduced into the valve device 330 through the outlet water passage 313 .

The washing water introduced into the valve device 330 through the outlet water passage 313 may be introduced into the regenerator 320 .

Hereinafter, the overall structure of the filter 310 will be described with reference to FIGS. 7 and 8 . 7 is a view showing the overall appearance of the assembled filter 310, FIG. 8 is a view showing the disassembled filter 310 for each part.

Referring to FIG. 7 , the filter 310 includes a filter upper end 310c, a first filter side end 310d extending downward from the filter upper end 310c, and a first filter side end opposite to the filter upper end 310c. It may include a filter lower end 310e connected to the 310d, and a second filter side end 310f opposite to the first filter side end 310d.

The extended length of the filter upper end 310c may be longer than the filter lower end 310e. An extended length of the first filter side end 310d may be shorter than an extended length of the second filter side end 310f.

The filter 310 may include a valve device 330 connecting the filter 310 and the regenerator 320, and an inlet end 340 spaced apart from the valve device 330 and having an acquisition port 311a. .

The valve device 330 and the inlet end 340 may be disposed at the same height, the valve device 330 may be connected to the filter lower end 310e, and the inlet end 340 may be connected to the second filter side end 310f. have.

The valve device 330 may be disposed to protrude downward from the lower end of the filter 310e. The inlet end 340 may be disposed to protrude from the second filter side end 310f toward the valve device 330 .

The acquisition flow path 311 may extend toward the second filter side end 310f from the acquisition port 311a formed at the inlet end 340 .

A container 312 in which the ion exchange resin (E) is stored may be formed on the upper side of the valve device 330 , which is disposed separately from the acquisition passage 311 . The container 312 may be formed closer to the first filter side end 310d than the second filter side end 310f. The container 312 may be understood as a space for storing the ion exchange resin E formed in the filter 310 . An inner space of the container 312 may be defined by a first guide 316 and a barrier 315 to be described later.

The container 312 may be connected to the valve device 330 to receive the washing water introduced through the acquisition flow path 311 .

The filter 310 may include an outlet water passage 313 formed to surround at least a portion of the container 312 .

The container 312 may be formed to be spaced apart from the first filter side end 310d, and at least a portion of the water outlet flow path 313 may be formed between the container 312 and the first filter side end 310d.

The container 312 may be formed to be spaced downward from the upper end of the filter 310c, and at least a portion of the water outlet flow path 313 may be formed between the container 312 and the upper end of the filter 310c.

The water outlet flow path 313 may extend along the circumference of the container 312 from the upper side of the container 312 to the lower side of the container 312 . The water outlet flow path 313 may be bent at least once along the circumference of the container 312 .

The washing water that has passed through the container 312 may flow along the water outlet flow path 313 and may be introduced into the valve device 330 .

Referring to FIG. 8 , the filter 310 may include a case 310a in which the ion exchange resin E is stored, and a block 310b coupled to the case 310a.

The block 310b may be connected to the case 310a to cover the acquisition passage 311 and the container 312 . The block 310b may be coupled to the case 310a by a thermal fusion method.

The block 310b may be manufactured in a shape corresponding to the case 310a. The block 310b is a first coupling part 310b1 coupled to the case 310a to cover the container 312, and a second coupling part 310b2 coupled to the case 310a to cover the acquisition flow path 311. ) may be included.

The filter 310 includes a first guide 316 extending in the vertical direction and forming a space in which the ion exchange resin (E) is stored, and a second guide protruding in the space in which the ion exchange resin (E) is stored. 317 and a barrier 315 extending in a direction crossing the vertical direction and forming a space in which the ion exchange resin (E) is stored.

The container 312 may form a space in which the ion exchange resin E is stored by the first guide 316 and the barrier 315 . The washing water flowing into the container 312 may be guided in a flow direction by the second guide 317 .

The first guide 316 and the second guide 317 may extend in the vertical direction, and the barrier 315 may extend in a direction crossing the first guide 316 and the second guide 317 .

The barrier 315 may include a first barrier 315a forming an upper boundary of the container 312 and a second barrier 315b forming a lower boundary of the container 312 .

The first guide 316 may include a first boundary guide 316a forming a boundary on one side of the container 312 and a second boundary guide 316b forming a boundary on the other side of the container 312 .

The first boundary guide 316a may partition the acquisition flow path 311 and the container 312 , and the second boundary guide 316b may partition the water exit flow path 313 and the container 312 .

The second guide 317 may include a first protruding guide 317a extending in the vertical direction, and a second protruding guide 317b extending in the vertical direction and spaced apart from the first protruding guide 317a. have.

The second guide 317 may be formed between the first boundary guide 316a and the second boundary guide 316b.

The first guide 316 and the second guide 317 may provide a fusion surface to which the block 310b is coupled. The block 310b may be coupled to the first guide 316 and the second guide 317 through thermal fusion to contact the ion exchange resin (E). Since the block 310b is coupled to the case 310a through the first guide 316 and the second guide 317, the ion exchange resin E may be protected from heat.

The first coupling part 310b1 may be coupled to each of the first guide 316 and the second guide 317 , and the second coupling part 310b2 may be coupled to the acquisition flow path 311 .

The filter 310 includes a flow meter 314 for measuring the flow rate of the washing water flowing in through the acquisition flow path 311 , a main valve 331 for controlling the flow direction of the washing water flowing into the valve device 330 , and washing water It may include a sub-valve 332 for preventing the reverse flow of the.

Hereinafter, the flow of washing water through the filter 310 will be described with reference to FIG. 9 . 9 shows the filter 310 as viewed from the front.

The acquisition port 311a may be connected to the external water source 50 to receive washing water from the external water source 50 .

The washing water introduced into the filter 310 through the acquisition port 311a may flow through the acquisition passage 311 .

The acquisition flow path 311 has a first intake flow path 311b connected to the acquisition port 311a and the flow meter 314, a second intake flow path 311c extending from the flow meter 314, and a second intake flow path 311c ) and may include a third intake passage 311d formed to be curved, and a fourth intake passage 311e connecting the third intake passage 311d and the valve device 330 .

The flow meter 314 may be disposed in the acquisition flow path 311, and may be disposed between the first intake flow path 311b and the second intake flow path 311c.

The first inflow passage 311b may extend between the ingestion port 311a and the flow meter 314 .

The second intake passage 311c may extend between the flow meter 314 and the third intake passage 311d. The second water inlet flow path 311c may be formed to be curved along the extending direction.

The third intake passage 311d may be connected to the second intake passage 311c, and may form a downwardly convex passage.

The fourth intake passage 311e may extend from the third intake passage 311d to the valve device 330 . The fourth water inlet flow path 311e may be formed to be bent along the extending direction.

The washing water flowing through the fourth water inlet flow path 311e may flow in a direction opposite to the direction of the washing water flowing through the flow meter 314 and the second water inlet flow path 311c. The fourth intake passage 311e and the second intake passage 311c may be disposed adjacent to each other to form a counterflow therebetween.

Washing water introduced into the valve device 330 along the acquisition flow path 311 may flow toward the container 312 .

A diffusion region 318 through which the washing water supplied from the valve device 330 flows may be formed between the container 312 and the valve device 330 .

The container 312 and the valve device 330 may be vertically spaced apart to form a diffusion region 318 therebetween. The diffusion region 318 may be understood as a space between the valve device 330 and the second barrier 315b.

The washing water that has passed through the diffusion region 318 may pass through the second barrier 315b and flow into the container 312 . The barrier 315 may be made of a material that transmits the washing water and does not allow the ion exchange resin E to permeate.

The washing water introduced into the container 312 may be guided by a flow of the guides 316 and 317 .

The washing water that has passed through the second barrier 315b flows between the first boundary guide 316a and the first protrusion guide 317a, between the first protrusion guide 317a and the second protrusion guide 317b, and the second It may flow between the protrusion guide 317b and the second boundary guide 316b, respectively.

By the first guide 316 and the second guide 317 , the washing water can be evenly spread over the entire area of the container 312 and flow upward.

The container 312 may have a width in the lateral direction that increases toward the upper side. The first boundary guide 316a forming the boundary of the container 312 may be formed to be bent upward.

The first boundary guide 316a includes a first extension portion 316a1 connected to one side of the second barrier 315b and extending obliquely upward, and a second extension portion curved upwardly from the first extension portion 316a1. It may include an extension part 316a2 and a third extension part 316a3 extending obliquely upward from the second extension part 316a2.

The third extension portion 316a3 may be located closer to the second filter side end 310f than the first extension portion 316a1 . The first extension 316a1 may be located closer to the second guide 317 than the third extension 316a3 . The second extension portion 316a2 may be bent from the first extension portion 316a1 toward the second filter side end 310f to be connected to the third extension portion 316a3 .

The washing water passing through the container 312 may be introduced into the water outlet flow path 313 in a state in which ions contained by the ion exchange resin E are removed.

The water outlet passage 313 includes a first water outlet passage 313a extending in the transverse direction between the container 312 and the filter upper end 310c, and between the container 312 and the first filter side end 310d in the vertical direction. The second water outlet passage 313b extended, the third water outlet passage 313c extending in the transverse direction between the container 312 and the filter lower end 310e, and the third water outlet passage 313c extending downward from the third water outlet passage 313c. 4 may include an outlet flow path 313d.

The water outlet flow path 313 may be formed to surround at least a portion of the container 312 .

Washing water flowing through the container 312 into the water outlet passage 313 may flow through the water outlet passage 313 along the circumferential direction of the container 312 to be introduced into the valve device 330 .

The valve device 330 may include a first connection port 334 , a second connection port 335 , and a third connection port 336 protruding downward and respectively connected to the regenerator 320 .

The first connection port 334 , the second connection port 335 , and the third connection port 336 may be laterally spaced apart from each other and protrude downward from the valve device 330 , respectively.

The fourth outlet water passage 313d may be connected to the third connection port 336 , and the washing water flowing through the outlet water passage 313 may be introduced into the regenerator 320 through the third connection port 336 . have.

Hereinafter, the overall structure of the regenerator 320 will be described with reference to FIGS. 10 and 11 . 10 is a perspective view showing the overall appearance of the regenerator 320, and FIG. 11 is an exploded view of the regenerator 320 by parts.

Referring to FIG. 10 , the regenerator 320 includes a first rim 324 protruding upward and into which the first connection port 334 is inserted, and a second rim 324 protruding upward and into which the second connection port 335 is inserted. It may include a rim 325 and a third rim 326 protruding upward and into which the third connection port 336 is inserted.

Referring to FIG. 11 , the regenerator 320 includes a regenerating body 320a having a space in which a regenerating agent is stored, a lower cover 320b connected to a lower portion of the regenerating body 320a, and an upper portion of the regenerating body 320a. It may include an upper cover (320c) connected to.

The first rim 324 , the second rim 325 , and the third rim 326 may be horizontally spaced apart from each other and protrude upward from the upper cover 320c.

The regenerator 320 includes a first supporter 324a disposed inside the first rim 324 and connected to the first connection port 334 , and a second connection port disposed inside the second rim 325 . It may include a second supporter 325a connected to the 335 and a third supporter 326a disposed inside the third limb 326 and connected to the third connection port 336 .

The first supporter 324a may be formed in an annular shape and may be inserted into the first rim 324 . The second supporter 325a may be formed in an annular shape and may be inserted into the second rim 325 . The third supporter 326a may be formed in an annular shape and may be inserted into the third rim 326 .

The regenerator 320 includes a first sealer 324b disposed inside the first rim 324 , a second sealer 325b disposed inside the second rim 325 , and a third rim 326 . It may include a third sealer (326b) disposed on the inside of the.

The first sealer 324b may support the first connection port 334 and may prevent the washing water from leaking. The second sealer 325b may support the second connection port 335 and may prevent the washing water from leaking. The third sealer 326b may support the third connection port 336 and may prevent the washing water from leaking.

Hereinafter, the flow of washing water through the regenerator 320 will be described with reference to FIGS. 12 and 13 . 12 is a view showing the water softening device 300 connected to the sump 210 from the upper side as viewed from the top down, and FIG. 13 shows the internal structure of the regeneration body 320a.

12 , the washing water from which ions are removed by the ion exchange resin E while passing through the filter 310 may be introduced into the sump 210 through the regenerator 320 . The washing water may sequentially pass through the filter 310 , the valve device 330 , the regenerator 320 , and the sump inlet pipe 213 , and then flow into the sump 210 .

Referring to FIG. 13 , the regenerator 320 may include a supply passage 323 connected to the sump 210 and through which the washing water passing through the ion exchange resin E flows.

The supply passage 323 includes a supply passage inlet 323a communicating with the third connection port 336 and a supply passage outlet 323b communicating with the water outlet port 320d connected to the sump inlet pipe 213 . can do.

The supply passage 323 may extend from the supply passage inlet 323a to the supply passage outlet 323b, and the washing water introduced into the regenerator 320 through the third connection port 336 is discharged through the water outlet port 320d. can guide you towards it.

The regenerator 320 includes a first regeneration passage 321 through which the washing water that has passed through the valve device 330 flows, a regenerating agent box 327 forming a regenerating space 320s in which the regenerating agent is stored, and the first regeneration The washing water introduced through the flow passage 321 may include a second regeneration passage 322 flowing toward the filter 310 .

The first regeneration passage 321 may include a first regeneration furnace inlet 321a communicating with the first connection port 334 and a second regeneration furnace inlet 321b communicating with the regeneration material box 327 . have. The first regeneration passage 321 may extend from the first regeneration passage inlet 321a to the second regeneration passage inlet 321b, and may be formed to be curved in the extending direction.

The regenerated box 327 may connect the first regeneration flow path 321 and the second regeneration flow path 322 , and the width may be expanded from the first regeneration passage 321 toward the second regeneration passage 322 . can

The regenerating agent stored in the regeneration space 320s can be dissolved in the washing water introduced through the first regeneration passage 321, and the ion exchange resin (E) is dissolved in the washing water through the second regeneration passage 322. can be supplied with

The regenerated material box 327 includes a box front end 327a connected to the first regeneration flow path 321, a box rear end 327e opposite to the box front end 327a, and a box rear end 327e from the box front end 327a. ), a box in contact with a first box side wall 327b extending toward the side, a second box side wall 327c extending obliquely from the box front end 327a toward the box rear end 327e, and a drain pan 328 to be described later. It may include a corner 327d.

The washing water introduced into the regenerant box 327 through the first regeneration passage 321 may flow from the box tip 327a between the first box side wall 327b and the second box side wall 327c. The washing water flowing between the first box side wall 327b and the second box side wall 327c goes around the box corner 327d through the drain pan 328 disposed at the rear end 327e of the box and the second regeneration flow path 322 can be introduced into

In the regenerator 320 , a drain pan 328 for guiding the washing water in the regeneration space 320s to the second regeneration passage 322 may be disposed. The drain pan 328 may be disposed at the rear end 327e of the box, and a plurality of drain holes 328a opened up and down may be formed. The washing water introduced into the drain pan 328 through the drain hole 328a may be introduced into the second regeneration passage 322 around the box corner 327d.

The second regeneration passage 322 may include a first regeneration path outlet 322a communicating with the drain pan 328 and a second regeneration path outlet 322b communicating with the second connection port 335 . .

The second regeneration passage 322 may extend from the first regeneration passage outlet 322a toward the second regeneration passage outlet 322b, and the washing water in which the regeneration agent is dissolved may flow toward the filter 310 . The washing water flowing into the second regeneration passage 322 through the drain pan 328 flows into the filter 310 through the second connection port 335 and is stored in the ion exchange resin E stored in the container 312. can be supplied.

Hereinafter, the valve device 330 when the softening device 300 is operated in the normal training mode will be described with reference to FIGS. 14, 15 (a) and 15 (b). 14 is a front view of the softening device 300 in the general training mode, FIG. 15 (a) is an enlarged view of the valve device 330 according to an embodiment in the general training mode, and FIG. 15 (b) is a general view It is an enlarged view of the valve device 330 according to another embodiment when in the soft water mode.

Referring to FIG. 14 , when the water softening device 300 is operated in the general training mode, the washing water introduced into the valve device 330 through the acquisition flow path 311 does not flow into the regenerator 320 but directly into the container 312 . flows towards

In the general training mode, the washing water supplied from the external water source 50 passes through the acquisition flow path 311 through the acquisition port 311a. The washing water passing through the acquisition flow path 311 is introduced into the hub 337 formed in the valve device 330 . The main valve 331 disposed on the hub 337 regulates the flow flow so that the washing water introduced into the hub 337 flows into the first flow path 338 extending toward the ion exchange resin (E). The washing water flowing into the diffusion region 318 through the first flow path 338 flows into the water outlet flow path 313 after passing through the container 312 . In this process, the sub-valve 332 may prevent the washing water flowing into the diffusion region 318 from flowing back into the valve device 330 . The washing water flowing into the outlet water passage 313 flows into the regenerator 320 through the third connection port 336 , and then is supplied to the sump 210 through the above-described supply passage 323 .

Referring to FIG. 15( a ), the valve device 330 according to an embodiment includes a main valve 331 for controlling the flow direction of washing water, and a filter 310 to block the flow of washing water from the filter 310 to the regenerator 320 . It may include a first sub-valve 332 and a second sub-valve 333 blocking the flow of washing water from the filter 310 to the main valve 331 . However, the valve device 330 does not necessarily include two types of sub-valves, the first sub-valve 332 and the second sub-valve 333, and a single sub-valve 332 as shown in FIG. 15(b). ) alone is sufficient.

The valve device 330 includes a hub 337 in which the main valve 331 is movably disposed and in communication with the acquisition flow path 311, and a hub 337 through a first hub hole 337a formed in the hub 337. ) in communication with the hub 337 through a first flow path 338 extending toward the ion exchange resin E, and a second hub hole 337b formed in the hub 337, toward the regenerator 320 An extended second flow path 339 may be included.

In the general training mode, the controller 330a electrically connected to the main valve 331 is configured to open the main valve 331 to the first hub hole 337a and close the second hub hole 337b to the main valve ( 331) can be controlled. Accordingly, the first flow path 338 is opened, and the second flow path 339 is closed. The washing water flowing into the hub 337 flows into the first flow path 338 through the first hub hole 337a. The washing water flowing into the first flow path 338 flows into the diffusion region 318 after passing through the first flow path hole 338a. The first sub-valve 332 blocks the flow from the diffusion region 318 to the regenerator 320 . At this time, the second sub-valve 333 disposed in the first flow path 338 is spaced upward from the second seating portion 333a in which the second filter inlet hole 333b is formed, and the first flow path 338 . Washing water flowing through may be passed through the diffusion region 318 . The washing water flowing into the diffusion region 318 passes through the ion exchange resin E, then flows into the outlet water passage 313 , and flows into the regenerator 320 through the third connection port 336 .

Referring to FIG. 15B , unlike the valve device 330 according to an exemplary embodiment, the second sub-valve 333 may not be provided.

In the general training mode, the washing water flowing into the hub 337 through the acquisition flow path 311 flows into the first flow path 338 . When the second sub-valve 333 is not provided, the washing water flowing into the first flow path 338 is directly introduced into the diffusion region 318 .

Hereinafter, the valve device 330 when the softening device 300 is operated in the regeneration training mode will be described with reference to FIGS. 16, 17 (a) and 17 (b). 16 is a front view of the softening device 300 in the regeneration training mode, FIG. 17 (a) is an enlarged view of the valve device 330 according to an embodiment in the regeneration training mode, and FIG. 17 (b) is the regeneration It is an enlarged view of the valve device 330 according to another embodiment when in the soft water mode.

Referring to FIG. 16 , when the water softening device 300 is operated in the regeneration training mode, the washing water introduced into the valve device 330 through the acquisition flow path 311 goes through the regenerator 320 and then toward the container 312 . flow

The valve device 330 may include a third flow path 335a in which the subvalve 332 is movable and extending from the regenerator 320 toward the ion exchange resin E.

In the regeneration training mode, the washing water supplied from the external water source 50 passes through the acquisition flow path 311 through the acquisition port 311a. The washing water passing through the acquisition flow path 311 is introduced into the hub 337 formed in the valve device 330 . The main valve 331 disposed on the hub 337 controls the flow of the washing water introduced into the hub 337 to flow into the second flow path 339 extending toward the regenerator 320 . The washing water flowing into the regenerator 320 through the second flow path 339 passes through the regeneration space 320s and then flows into the diffusion region 318 through the third flow path 335a. In this process, the sub-valve 332 may open the third flow path 335a so that the washing water that has passed through the regeneration space 320s flows into the diffusion region 318 . Washing water flowing into the water outlet passage 313 through the diffusion region 318 and the container 312 flows into the regenerator 320 through the third connection port 336, and then through the supply passage 323 described above. It is supplied to the sump 210 .

Referring to FIG. 17( a ), in the regeneration training mode, in the controller 330a electrically connected to the main valve 331 , the main valve 331 closes the first hub hole 337a and the second hub hole The main valve 331 may be controlled to open the 337b. Accordingly, the second flow passage 339 is opened, and the first flow passage 338 is closed. The washing water flowing into the hub 337 flows into the second flow path 339 through the second hub hole 337b. The washing water flowing into the second flow path 339 passes through the second flow path hole 339a and then flows into the regenerator 320 through the first connection port 334 . The washing water flowing into the regenerator 320 flows into the third flow path 335a through the second regeneration passage 322 and the second connection port 335 through the regeneration space 320s. The second sub-valve 333 blocks the flow from the diffusion region 318 to the first flow path 338 . At this time, the first sub-valve 332 disposed in the third flow path 335a is spaced upward from the first seating part 332a in which the first filter inlet hole 332b is formed, and the third flow path 335a. The washing water flowing through may be passed through the diffusion region 318 . The washing water flowing into the diffusion region 318 passes through the ion exchange resin E, then flows into the outlet water passage 313 , and flows into the regenerator 320 through the third connection port 336 .

Referring to FIG. 17B , unlike the valve device 330 according to an exemplary embodiment, the second sub-valve 333 may not be provided.

In the regeneration training mode, the washing water introduced into the hub 337 through the acquisition flow path 311 flows into the second flow path 339 . The washing water flowing into the regenerator 320 through the second flow path 339 flows into the third flow path 335a after passing through the regeneration space 320s. When the second sub-valve 333 is not provided, predetermined washing water may remain in the first flow path 338 .

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and in the technical field to which the present invention belongs, without departing from the gist of the present invention as claimed in the claims Various modifications may be made by those of ordinary skill in the art, and these modifications should not be individually understood from the technical spirit or perspective of the present invention.

1: Dishwasher 10: Cabinet
20: door 30: control panel
50: external water source 100: washing tank
200: driving unit 210: sump
300: water softener 310: filter
311: access flow path 312: container
313: exit flow path 320: regenerator
330: valve device 331: main valve
332: first sub-valve 333: second sub-valve

Claims (20)

a washing tank in which a washing object is accommodated and washing water is sprayed;
a sump disposed below the washing tank and storing the washing water; and
and a water softening device disposed between an external water source for supplying the washing water to the sump and the sump,
The water softener is
a filter having an ion exchange resin stored therein and connected to the external water source; and
and a regenerator for storing a regenerating agent for removing foreign substances adsorbed on the ion exchange resin and connected to the sump,
the regenerator,
The dishwasher is detachably connected to the filter through a valve device for controlling the washing water to selectively flow with the ion exchange resin or the regenerant.
The method of claim 1,
The filter is disposed to face the side wall of the washing tank,
The regenerator is a dishwasher disposed to face a lower wall of the washing tub.
The method of claim 1,
The valve device is
A dishwasher disposed to face an edge formed by connecting a side wall and a lower wall of the washing tub.
The method of claim 1,
The valve device is
a main valve for controlling the flow direction of the washing water; and
and a sub-valve for blocking a reverse flow of the washing water between the filter and the regenerator.
5. The method of claim 4,
The sub-valve is
a first sub-valve blocking the flow of the washing water from the filter to the regenerator; and
and a second sub-valve blocking the flow of the washing water from the filter to the main valve.
5. The method of claim 4,
The valve device is
a hub on which the main valve is movable;
a first passage communicating with the hub through a first hub hole formed in the hub and extending toward the ion exchange resin;
a second flow passage communicating with the hub through a second hub hole formed in the hub and extending toward the rejuvenating agent; and
and a third flow path in which the sub-valve is movably disposed and extends from the regenerator toward the ion exchange resin.
7. The method of claim 6,
The water softener is
It is operated in a general training mode in which the rejuvenating agent is not added to the washing water or in a regenerative training mode in which the regenerating agent is added to the washing water,
The main valve is
The dishwasher closes the second hub hole when the water softener is operated in the general training mode.
7. The method of claim 6,
The water softener is
It is operated in a general training mode in which the rejuvenating agent is not added to the washing water or in a regenerative training mode in which the regenerating agent is added to the washing water,
The main valve is
The dishwasher closes the first hub hole when the water softener is operated in the regeneration training mode.
The method of claim 1,
The filter is
an inflow passage connected to the external water source; and
A dishwasher including a container disposed separately from the acquisition flow path and storing the ion exchange resin.
10. The method of claim 9,
The washing water introduced into the filter is
The dishwasher is introduced into the valve device through the acquisition passage, and flows from the valve device toward the container.
10. The method of claim 9,
The filter is
and a water outlet passage formed to surround at least a portion of the container.
10. The method of claim 9,
The container is
A dishwasher that gets wider as it goes up.
10. The method of claim 9,
The container is
A dishwasher including a first guide extending in a vertical direction and forming a space inside which the ion exchange resin is stored.
10. The method of claim 9,
The container is
and a second guide protruding from a space in which the ion exchange resin is stored.
10. The method of claim 9,
The filter is
Including a block arranged to cover the acquisition flow path and the container,
The block is
A dishwasher in contact with the guide protruding from the container.
10. The method of claim 9,
The filter is
A dishwasher including a flow meter disposed in the acquisition flow path.
The method of claim 1,
The filter is
A dishwasher including a barrier extending in a direction crossing the vertical direction and forming a space inside which the ion exchange resin is stored.
The method of claim 1,
the regenerator,
and a supply passage connected to the sump and through which the washing water passing through the ion exchange resin flows.
The method of claim 1,
the regenerator,
a first regeneration passage through which the washing water passing through the valve device is introduced; and
and a second regeneration passage through which the washing water introduced through the first regeneration passage flows toward the filter.
20. The method of claim 19,
the regenerator,
and a rejuvenating agent box forming a space in which the rejuvenating agent is stored, and having a width wider from the first regenerating flow path toward the second regenerating flow path.

Images