KR20210147864A - Water purifier having carbonated water system - Google Patents

Abstract

The present invention relates to a water purifier with a carbonated water system, and more specifically, to a water purifier with a carbonated water system, which provides purified water, cold water, and carbonated water to a user while simultaneously allowing the carbonated water to be discharged to the outside through a drainage unit to maintain an interior of the drainage unit from which foreign substances and water are discharged for a long period of time not clogged, and thus it is possible to secure operation stability of the water purifier and improve user convenience.

Description

Water purifier equipped with carbonated water system {WATER PURIFIER HAVING CARBONATED WATER SYSTEM}

The present invention relates to a water purifier equipped with a carbonated water system, which provides purified water, cold water, and carbonated water to a user while simultaneously discharging carbonated water through a drainage unit so that the inside of the drainage unit through which foreign substances and water are discharged is not clogged for a long period of time It relates to a water purifier equipped with a carbonated water system that can secure operation stability of the water purifier and improve user convenience by maintaining the water purifier.

A generally used water purifier is provided with a drain tube for discharging water for household use discharged through a filtration filter or water not suitable for providing to users (internal washing water, thawed ice water, etc.) to the outside.

US Patent Publication No. 2019-0329168 of COWAY CO., LTD. discloses a conventional water purifier. Such a water purifier is provided with a filtration unit such as a reverse osmosis membrane filter to filter raw water, and a second flow path through which the filtered purified water flows and a third flow path through which the filtered concentrated water flows are connected to the filter unit. The filtered concentrated water flowing through the third flow path means water containing the filtered solid material, and this concentrated water is discharged to the outside through the third flow path. A concentrated water flow control valve is provided in the third flow path through which the concentrated water is discharged to the outside, and it is determined whether the concentrated water flow control valve is malfunctioning or clogged based on the change in the ratio of concentrated water and purified water flow rate. However, it is possible to determine whether the concentrated water flow control valve is clogged in this way and replace it, but the third flow path through which the concentrated water is discharged to the outside is cumbersome to periodically replace before clogging occurs. In addition, this third flow path is connected to the drain pipe under the sink, and when foreign substances in the drain pipe block the third flow path due to the environmental characteristics of the drain pipe through which sewage is discharged, the discharge of water including concentrated water is not smooth. have.

The water purifier disclosed in US Patent Publication No. 2019-0299163 of COWAY CO., LTD. is also provided with a filter unit such as a reverse osmosis membrane filter to filter raw water. The flowing concentrated water flow path is connected to discharge the concentrated water to the outside. However, concentrated water flows repeatedly in the process of using the water purifier in this concentrated water flow path, and due to the environmental characteristics of the drain pipe to which the concentrated water flow path is connected, foreign substances in the drain pipe block the concentrated water flow path, preventing smooth discharge of water including concentrated water. there will be a problem

US Patent Publication No. 2019-0329168 US Patent Publication No. 2019-0299163

In order to solve the above problem, the water purifier equipped with the carbonated water system according to the present invention provides purified water, cold water, and carbonated water to the user while simultaneously discharging the carbonated water through the drain unit to discharge foreign substances and water for a long period of time. The purpose of this is to secure the operation stability of the water purifier and to improve user convenience by keeping the inside of the drain unit not clogged.

The water purifier equipped with the carbonated water system according to an embodiment of the present invention is configured to provide carbonated water to the user by adjusting the flow path of carbonated water through the carbonated water flow path adjusting member, or to relieve clogging of the drainage unit by using carbonated water for user convenience. aims to enhance

A water purifier equipped with a carbonated water system according to an embodiment of the present invention discharges carbonated or carbonated water that is not suitable to be provided to a user due to a reduced carbonate concentration to the drainage unit for a predetermined period of time to solve the clogging of the drainage unit, and after a predetermined period of time, It aims to improve user satisfaction by configuring the carbonated water to be supplied to the water outlet.

In the water purifier equipped with the carbonated water system according to an embodiment of the present invention, even if a high pressure of 1K or higher occurs while the carbonated water is discharged to the drain unit, the first safety valve member is opened and the high pressure is released through the first safety channel member to discharge carbonated water An object of the present invention is to improve the durability of the water purifier by preventing damage to the flow path member.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonate extraction valve for controlling the supply of carbonic acid from the carbonated cylinder member is configured to operate using the pressure of purified or cold water, so that a separate system for driving the carbonated extraction valve is configured. It is possible to supply carbonic acid even if the driving unit is not provided, thereby reducing the weight and improving manufacturability through configuration simplification.

An object of the water purifier equipped with the carbonated water system according to an embodiment of the present invention is to improve the operational stability of the water purifier by stably operating the carbonate extraction valve while the purified or cold water is pressurized to a sufficient pressure through the pressing member.

The water purifier equipped with the carbonated water system according to an embodiment of the present invention is configured so that when the opening/closing door is pressed through the pressure of purified or cold water, the carbonate flow path is opened and carbonic acid is supplied, so that a separate driving unit for driving the carbonate extraction valve is not provided. The purpose of the carbonic acid supply is to reduce the weight and improve the manufacturability by simplifying the configuration.

In the water purifier equipped with the carbonated water system according to an embodiment of the present invention, even when a high pressure of 10K or more occurs while the carbonic acid is supplied, the second safety valve member is opened and the high pressure is released through the second safety flow path member, so that the carbonic acid supply flow path member The purpose of this is to secure the durability of the water purifier by preventing damage to the water purifier, and at the same time, to solve the clogging of the drain part by using high-pressure carbonic acid.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, even if foreign substances and water discharged through the flushing passage member are discharged to the outside through the drain passage member for a long period of time, carbonated water discharged through the carbonated water discharge passage member is disposed in the drain passage member. An object of the present invention is to improve driving stability of the water purifier by maintaining the interior of the drain passage member not to be blocked by being configured to pass therethrough.

Since the water purifier equipped with the carbonated water system according to an embodiment of the present invention discharges the fluid by connecting a number of drain passage members that are smaller than the number of unit valve members, the time taken in the process of installing each flow passage member is shortened, and , an object of the present invention is to improve space efficiency by efficiently using the space occupied by each flow path member.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, the fluid flowing out from each unit valve member flows into the multi-body through the inlet leg and then moves to the drain passage member through the outlet leg, but the multi-body has a plurality of Since the inlet and outlet legs are interconnected, fluid can be discharged using a relatively smaller number of drain channel members than the channel members through which the fluid flows, thereby reducing the installation time of each channel member, and each channel member It aims to improve space efficiency by efficiently using the space it occupies.

In order to achieve the above object, a water purifier equipped with a carbonated water system according to the present invention includes a filtration unit provided with a reverse osmosis filter member to generate purified water by filtering raw water, a purified water storage unit for storing the purified water supplied from the filtration unit, and the A cold water generating unit that receives purified water from the filtration unit or the purified water storage unit to generate cold water, a carbonated water generation unit that receives purified water from the filtration unit or the purified water storage unit, or receives cold water from the cold water generation unit to generate carbonated water , the purified water supplied from the filtering unit or the purified water storage unit or the cold water supplied from the cold water generating unit or the carbonated water supplied from the carbonated water generating unit is discharged from the water outlet, and foreign substances and water discharged from the reverse osmosis filter member are discharged from the outside. and a drainage unit provided with a flushing flow path member to discharge into

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generator further includes a carbonated water flow path adjusting member that controls whether carbonated water is supplied to the water outlet or discharged to the drain.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the water purifier further includes a control unit for controlling an operation of the carbonated water flow path adjusting member, wherein the control unit discharges the carbonated water for a predetermined time before the carbonated water is supplied to the water outlet. It is characterized in that the control so that carbonated water is discharged to the drain part through the flow path member.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generator includes a first safety flow path member branched from the carbonated water discharge flow path member and the carbonated water discharged through the carbonated water discharge flow path member. and a first safety valve member that opens and closes so that carbonated water is discharged through the first safety channel member when the pressure is higher than a predetermined pressure.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generating unit may include a water supply passage through which the purified water supplied from the filtering unit or the purified water storage unit or the cold water supplied from the cold water generating unit moves. member, a carbonic acid supply passage member through which carbonic acid supplied from the carbonic acid cylinder member moves, and a mixing member for generating carbonated water by mixing purified or cold water supplied through the water supply passage member with carbonic acid supplied through the carbonic acid supply passage member Including, wherein the carbonic acid cylinder member is characterized in that it comprises a carbonic acid extraction valve for controlling the carbonic acid to be supplied using the pressure of purified or cold water supplied through the water supply passage member.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generator further includes a pressing member for pressing the purified or cold water supplied through the water supply passage member to a predetermined pressure.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonate extraction valve communicates with an upper frame through which purified or cold water supplied through the water supply passage member passes, and the inside of the carbonated cylinder member. It characterized in that it includes a lower frame through which carbonic acid passes, and an opening/closing door that opens a carbonic acid flow path while being pressed by the pressure of purified or cold water so that the lower frame selectively communicates with the inside of the carbonic acid cylinder member.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generator may include a second safety flow path member branched from the carbonated water supply flow path member and a pressure of carbonic acid supplied through the carbonated water supply flow path member. and a second safety valve member that opens and closes so that carbonic acid is discharged through the second safety passage member when the pressure is higher than a predetermined pressure.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the drain unit includes a drain passage member for discharging foreign substances and water discharged through the flushing passage member to the outside, and the carbonated water discharge passage member includes carbonated water is communicated with the drain channel member so as to be discharged to the outside through the drain channel member.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the drain unit includes n unit valve members (n is an integer greater than or equal to 2) each connected to the flushing flow path member and the carbonated water discharge flow path member, and A multi-tube member for communicating the n number of unit valve members and the k number of drain passage members so that the fluid that has passed through the n number of unit valve members is discharged through k (an integer less than n) number of the drain passage members characterized in that

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the multi-tube member includes n inlet legs respectively connected to the unit valve member, k outlet legs respectively connected to the drain channel member, and , It characterized in that it comprises a multi-body for interconnecting the plurality of inlet legs and the outlet legs.

According to the above configuration, the water purifier equipped with the carbonated water system according to the present invention provides purified water, cold water and carbonated water to the user while simultaneously discharging the carbonated water through the drainage unit to the outside. By keeping the inside not clogged, it provides the effect of securing the operation stability of the water purifier and enhancing user convenience.

The water purifier equipped with the carbonated water system according to an embodiment of the present invention is configured to provide carbonated water to the user by adjusting the flow path of carbonated water through the carbonated water flow path adjusting member, or to relieve clogging of the drainage unit by using carbonated water for user convenience. provides the effect of enhancing

A water purifier equipped with a carbonated water system according to an embodiment of the present invention discharges carbonated or carbonated water that is not suitable to be provided to a user due to a reduced carbonate concentration to the drainage unit for a predetermined period of time to solve the clogging of the drainage unit, and after a predetermined period of time, By configuring the carbonated water to be supplied to the water outlet, the effect of enhancing user satisfaction is provided.

In the water purifier equipped with a carbonated water system according to an embodiment of the present invention, ^{even if a high pressure of 1K (kgf/cm 2} ) or more occurs while carbonated water is discharged to the drain, the first safety valve member is opened and the first safety flow path member is It provides the effect of improving the durability of the water purifier by preventing damage to the carbonated water discharge channel member by relieving the high pressure.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonate extraction valve for controlling the supply of carbonic acid from the carbonated cylinder member is configured to operate using the pressure of purified or cold water, so that a separate system for driving the carbonated extraction valve is configured. Carbon dioxide can be supplied even if the driving unit is not provided, thereby providing an effect of reducing weight and improving manufacturability through configuration simplification.

The water purifier equipped with the carbonated water system according to an embodiment of the present invention provides the effect of improving the operational stability of the water purifier by stably operating the carbonate extraction valve while the purified or cold water is pressurized to a sufficient pressure through the pressing member.

The water purifier equipped with the carbonated water system according to an embodiment of the present invention is configured so that when the opening/closing door is pressed through the pressure of purified or cold water, the carbonate flow path is opened and carbonic acid is supplied, so that a separate driving unit for driving the carbonate extraction valve is not provided. Carbonic acid can be supplied, which provides the effect of reducing weight and improving manufacturability through configuration simplification.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, ^{even if a high pressure of 10K (kgf/cm 2} ) or more occurs in the course of supplying carbonic acid, the second safety valve member is opened and the high pressure is generated through the second safety flow path member. By preventing damage to the carbonic acid supply passage member, the durability of the water purifier is ensured and, at the same time, the clogging of the drain is provided by using high-pressure carbonic acid.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, even if foreign substances and water discharged through the flushing passage member are discharged to the outside through the drain passage member for a long period of time, carbonated water discharged through the carbonated water discharge passage member is disposed in the drain passage member. By being configured to pass through, the inside of the drain channel member is maintained so as not to be blocked, thereby providing an effect of improving the driving stability of the water purifier.

Since the water purifier equipped with the carbonated water system according to an embodiment of the present invention discharges the fluid by connecting a number of drain passage members that are smaller than the number of unit valve members, the time taken in the process of installing each flow passage member is shortened, and , it provides the effect of improving the space efficiency by efficiently using the space occupied by each flow path member.

In a water purifier equipped with a carbonated water system according to an embodiment of the present invention, the fluid flowing out from each unit valve member flows into the multi-body through the inlet leg and then moves to the drain passage member through the outlet leg, but the multi-body has a plurality of Since the inlet and outlet legs are interconnected, fluid can be discharged using a relatively smaller number of drain channel members than the channel members through which the fluid flows, thereby reducing the installation time of each channel member, and each channel member It provides the effect of enhancing space efficiency by efficiently using the space it occupies.

1 is a block diagram illustrating a water purifier equipped with a carbonated water system according to an embodiment of the present invention.
2 is a block diagram illustrating a state in which raw water is filtered and cold water is provided to a user through a water purifier equipped with a carbonated water system according to an embodiment of the present invention;
3 is a block diagram illustrating a state in which carbonated water is supplied to the drain part of a water purifier equipped with a carbonated water system according to an embodiment of the present invention to relieve clogging.
4 is a block diagram illustrating a state in which carbonated water is supplied to a water outlet of a water purifier equipped with a carbonated water system according to an embodiment of the present invention and provided to a user.
5 is a configuration diagram illustrating a state in which the high pressure is resolved when high pressure due to carbonated water or carbonic acid is generated in a water purifier equipped with a carbonated water system according to an embodiment of the present invention.
6 is a cross-sectional view illustrating a carbonate extraction valve provided in a water purifier equipped with a carbonated water system according to an embodiment of the present invention.
7 is a block diagram illustrating a drainage unit provided in the carbonated water system according to an embodiment of the present invention.

Words and terms used in the present specification and claims are not limited to their ordinary or dictionary meanings, but in accordance with the principle that the inventor can define terms and concepts in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea.

Therefore, the embodiments described in this specification and the configurations shown in the drawings correspond to a preferred embodiment of the present invention, and do not represent all of the technical spirit of the present invention, so that the configuration may be replaced by various There may be equivalents and variations.

In this specification, terms such as "comprises" or "have" are intended to describe the existence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but one or more other features It should be understood that this does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

The presence of an element "in front", "behind", "above" or "below" of another element means that, unless otherwise specified, it is directly in contact with another element, such as "front", "rear", "above" or "below". It includes not only being disposed at the “lower side” but also cases in which another component is disposed in the middle. In addition, that a component is "connected" with another component includes not only direct connection to each other, but also indirect connection to each other, unless otherwise specified.

Hereinafter, a water purifier equipped with a carbonated water system according to the present invention will be described with reference to the drawings. 1 is a block diagram showing a water purifier equipped with a carbonated water system according to an embodiment of the present invention, and FIG. 2 is a view showing the filtration of raw water and cold water to the user through the water purifier equipped with the carbonated water system according to an embodiment of the present invention. It is a configuration diagram showing a state in which is provided. In order to clearly explain the present invention, parts not related to the description are omitted from the drawings.

1 and 2, the water purifier equipped with a carbonated water system according to an embodiment of the present invention is provided with a reverse osmosis filter member 110 to filter raw water W1 to generate purified water W2. and a filtration unit 100 . The filter unit 100 may be provided with a pump member for supplying the raw water (W1) pressurized to the reverse osmosis filter member 110, and the purified water W2 filtered through the reverse osmosis filter member 110 moves. A filtering channel member and a flushing channel member 610 through which unfiltered foreign substances and water are discharged to the outside, as will be described later, may be provided. The pump member is configured to supply the raw water W1 at a predetermined filtration pressure or higher to the reverse osmosis filter member, and may be disposed in front of the reverse osmosis filter member 110 . Such a pump member may not be driven during the flushing operation of the reverse osmosis filter member 110 , and in this case, the flushing operation may be performed by the supply pressure of the raw water W1 . For example, the raw water W1 may be tap water having a pressure of ^{4.2 kgf/cm 2 .} A filtration channel member through which the purified water W2 that has passed through the reverse osmosis membrane moves is connected to the filtering side of the reverse osmosis filter member 110, and a flushing channel member 610 through which foreign substances and water that do not pass through the reverse osmosis membrane move are connected to the non-filtration side. do. The filter unit 100 may further include a pre-treatment filter member 120 and a post-treatment filter member 130 . The pre-treatment filter member 120 is disposed at the front end of the reverse osmosis filter member 110, and the raw water W1 is first filtered in this pre-treatment filter member 120 and then further filtered in the reverse osmosis filter member 110. have. The post-treatment filter member 130 is disposed on the filtration passage member connected to the filtration side of the reverse osmosis filter member 110 to further filter the purified water W2 filtered through the reverse osmosis filter member 110 . The number of water filters included in the filter unit 100 other than the reverse osmosis filter member 110 is not particularly limited, and any water filter may be used as long as it is a water filter capable of filtering the raw water W1. Alternatively, the filter unit 100 may be provided with only the reverse osmosis filter member 110 .

In addition, in the water purifier equipped with the carbonated water system according to an embodiment of the present invention, the purified water storage unit 200 , the filter unit 100 or the purified water storage unit 200 stores the purified water W2 supplied from the filtering unit 100 . ) receives the purified water W2 from the cold water generating unit 300 that generates cold water W3, the filtering unit 100 or the purified water storage unit 200 receives the purified water W2, or the cold water generating unit 300 and a carbonated water generating unit 400 that receives the cold water W3 from and generates carbonated water W4. In this case, an ice generating unit 700 that generates ice by receiving purified water W2 from the filtering unit 100 or the purified water storage unit 200 or receiving cold water W3 from the cold water generating unit 300 may be included. may be The ice generated through the ice generating unit 700 may be provided to the user after moving to the ice extracting unit 720 through the ice supply passage member 710 . In addition, hot water may be provided to the user by heating the purified water W2 generated through the filtering unit 100 . The purified water W2 supplied from the filtering unit 100 or the purified water storage unit 200, the cold water W3 supplied from the cold water generating unit 300, or the carbonated water W4 supplied from the carbonated water generating unit 400 is It is provided to the user while water is drawn out through the water outlet 500 . To this end, the water outlet 500 includes a first purified water supply channel member 510 communicating with the filtering unit 100 , a second purified water supply channel member 520 communicating with the purified water storage unit 200 , and a cold water generating unit 300 . ) may include a cold water supply passage member 530 in communication with the carbonated water supply passage member 540 in communication with the carbonated water generator 400 .

In addition, as described above, in the water purifier equipped with the carbonated water system according to an embodiment of the present invention, the flushing passage member 610 is provided so that foreign substances and water discharged from the reverse osmosis filter member 110 are discharged to the outside. part 600 . In this case, the carbonated water generating unit 400 described above includes a carbonated water discharge passage member 410 communicating with the draining unit 600 so that the carbonated water W4 passes through the draining unit 600 and is discharged to the outside. In other words, it is configured such that purified water W2, cold water W3, and carbonated water W4 are provided to the user and at the same time carbonated water W4 passes through the drainage unit 600 and is discharged to the outside, so that foreign substances and water are discharged for a long period of time. By keeping the inside of the unit 600 not clogged, it is possible to secure the operation stability of the water purifier and improve user convenience.

3 is a block diagram illustrating a state in which clogging is eliminated by supplying carbonated water to the drain part of a water purifier equipped with a carbonated water system according to an embodiment of the present invention, and FIG. 4 is a carbonated water system according to an embodiment of the present invention. It is a configuration diagram showing a state in which carbonated water is supplied to the water outlet of the provided water purifier and provided to the user.

3 and 4 , in the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generator 400 supplies carbonated water W4 to the water outlet 500 or drains the water. It may further include a carbonated water flow path control member 420 for controlling the discharge to the unit (600). A control unit 800 , which will be described later, may be provided to adjust the flow path of the carbonated water flow path adjusting member 420 . That is, since the clogging of the drain unit 600 can be resolved by using the carbonated water W4 provided to the user, a separate configuration for resolving the blockage of the drain unit 600 is not required. In this way, by adjusting the flow path of the carbonated water W4 through the control unit 800 to provide carbonated water W4 to the user, or to use the carbonated water W4 to solve the clogging of the drainage unit 600, the user Convenience may be improved.

3 and 4 , in the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the water purifier further includes a control unit 800 for controlling the operation of the carbonated water flow path adjusting member 420 , the control unit Reference numeral 800 controls the carbonated water W4 to be discharged to the drain unit 600 through the carbonated water discharge passage member 410 for a predetermined time before the carbonated water W4 is supplied to the water outlet 500 . After the carbonated water W4 is provided to the user, carbonated or carbonated water W4 remains in many flow passage members provided in the carbonated water generating unit 400 . At this time, there is no problem in the case where the carbonated water W4 is continuously provided to the user, but as time elapses after the provision of the carbonated water W4 is finished, many flow path members provided in the carbonated water generator 400 remain The concentration of carbonic acid is reduced, and carbonated water or carbonated water having such a concentration is not suitable to be provided to the user. Therefore, before providing carbonated water to the user, carbonated or carbonated water having a reduced concentration remaining in many flow passage members provided in the carbonated water generating unit 400 is discharged to the drainage unit 600 for a certain period of time, thereby resolving clogging of the drainage unit 600 . will do For example, the time for which the carbonated water W4 is discharged to the drain unit 600 may be about 2 to 3 seconds. The controller 800 controls so that the carbonated water W4 is supplied to the water outlet 500 after such a predetermined period of time, so that the carbonated water W4 having an appropriate concentration can be provided to the user. That is, the carbonated or carbonated water W4, which is not suitable to be provided to the user due to the decrease in the carbonate concentration, is discharged to the drainage unit 600 for a predetermined time to solve the blockage of the drainage unit, and the carbonated water W4 is discharged after a predetermined time. By configuring it to be supplied to the unit 500, it is possible to improve user satisfaction.

At this time, the carbonated water flow path control member 420 may be provided with a carbonated water extraction valve and a carbonated water drain valve, respectively, and when the user wants to drink the carbonated water W4, the carbonated water W4 is supplied through the carbonated water extraction valve to the water outlet 500 . control to move to, and when it is necessary to remove the blockage of the drain unit 600 , the carbonated water drain valve (allowable pressure: 0 to 5 kgf/cm ² ) may be opened to control the movement to the drain unit 600 . That is, when the carbonated water W4 is provided to the user, the control unit 800 opens the carbonated water extraction valve, closes the carbonated water extraction valve when the carbonated water W4 is finished, and opens the carbonated water drain valve to open the carbonated water W4. By controlling the water to be discharged to the drainage unit 600 at one time, product failure or leakage problems due to clogging of the drainage unit 600 do not occur in the water purifier equipped with a carbonated water system in which a user can drink carbonated water W4. Alternatively, the clogging of the drainage unit 600 may be eliminated by flowing carbonated water remaining after the carbonated water W4 is generated to the carbonated water discharge channel member 410 .

5 is a configuration diagram illustrating a state in which the high pressure is resolved when high pressure due to carbonated water or carbonic acid is generated in a water purifier equipped with a carbonated water system according to an embodiment of the present invention.

5 , in the water purifier equipped with the carbonated water system according to the embodiment of the present invention, the carbonated water generator 400 includes a first safety flow path member SL1 branched from the carbonated water discharge flow path member 410 . ) and a first safety valve member ( SV1) may be included. As an example, the first safety flow path member SL1 may be configured to be opened by the carbonated water W4 pressure of ^{about 1K (kgf/cm 2 ).} At this time, the first sea ice water discharge passage member 661 through which the sea ice water discharged from the ice generating unit 700 flows, or the second sea ice water discharge passage member 662 through which the sea ice water discharged from the ice extraction unit 720 flows. may be provided, and a drain tank member 660 having a predetermined capacity may be provided to accommodate the thawed water discharged therefrom, and the first safety flow path member SL1 communicates with the drain tank member 660 to provide a predetermined capacity. By configuring the carbonated water W4 of high pressure exceeding the pressure to move into the inside of the drain tank member 660, the high pressure is eliminated. The thawed water accommodated in the drain tank member 660 and the carbonated water W4 introduced as the first safety flow path member SL1 operates are discharged through the first discharge flow path member 620 , and the cold water generating unit 300 . The cold water W3 discharged from ) is discharged through the second discharge passage member 630 , and the fluid such as sea ice water discharged through the first and second discharge passage members 620 and 630 is discharged through the discharge pump member 640 . ) and then discharged to the outside through the third discharge passage member 650 . ^{That is, even when a high pressure of 1K (kgf/cm 2} ) or more occurs in the process in which the carbonated water W4 is discharged to the drain unit 600 , the first safety valve member SV1 is opened while the first safety flow path member SL1 is It provides the effect of improving the durability of the water purifier by preventing damage to the carbonated water discharge channel member by relieving the high pressure.

As shown in FIG. 4 , in the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generating unit 400 includes the purified water W2 supplied from the filtering unit 100 or the purified water storage unit 200 . ) or the water supply passage member 430 through which the cold water W3 supplied from the cold water generating unit 300 moves, the carbonic acid supply passage member 450 through which the carbonic acid supplied from the carbonic acid cylinder member 440 moves, and water A mixing member 460 for generating carbonated water W4 by mixing purified water W2 or cold water W3 supplied through the supply flow path member 430 and carbonic acid supplied through the carbonated supply flow path member 450 is included. , the carbonic acid cylinder member 440 may include a carbonic acid extraction valve 441 for controlling carbonic acid to be supplied by using the pressure of the purified water W2 or the cold water W3 supplied through the water supply passage member 430 . . That is, when the user wants to drink carbonated water W4, purified water W2 or cold water W3 is mixed with carbonated water contained in carbonated cylinder member 440 to generate carbonated water W4, and the carbonated water W4 is mixed with carbonated water W4. The carbonated water is provided to the user through the carbonated water extraction valve provided in the carbonated water flow path control member 420 . For example, the carbon dioxide cylinder member 440 may be a carbon dioxide gas cylinder having the following specifications.

Cylinder capacity: 425g

Carbonation production: 50L

Internal pressure: 40 ~ 70kgf/cm ²

Allowable vessel pressure: 250bar

Weight: 0.62kg

A water supply passage member 430 through which purified water W2 or cold water W3 moves and a carbon dioxide supply passage member 450 through which carbonic acid moves are connected to this carbon dioxide cylinder, and various tubes may be used as these flow passage members. have. For example, in the case of a 1/4 tube, a tube having a diameter of 4 mm and an outer diameter of 6.3 mm may be used. That is, as described above, the carbonic acid extraction valve 441 that controls the supply of carbonic acid from the carbonic acid cylinder member 440 is configured to operate using the pressure of the purified water W2 or the cold water W3, so that the carbonic acid extraction valve ( 441) It is possible to supply carbonic acid even if a separate driving unit for driving is not provided, so that weight reduction and manufacturability can be improved through configuration simplification.

As shown in FIG. 4 , in the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the carbonated water generator 400 includes purified water W2 or cold water ( It may further include a pressing member 470 for pressing W3) to a predetermined pressure. For example, for smooth operation of the carbonic acid extraction valve 441, purified water W2 or cold water W3 may be configured to be pressurized in a range of about ^{8 to 9K (kgf/cm 2 ).} In addition, the water supply passage member 430 to which the purified water W2 or the cold water W3 is supplied includes the first supply passage member 431 disposed at the front end of the pressing member 470 , the rear end of the pressing member 470 , and It may include a second supply flow path member 432 disposed between the carbonic acid extraction valves 441 and a third supply flow path member 433 disposed at a rear end of the carbonic acid extraction valve 441 . As described above, as the purified water W2 or the cold water W3 is pressurized to a sufficient pressure through the pressing member 470 , the carbonate extraction valve 441 is stably operated, thereby improving the operational stability of the water purifier.

6 is a cross-sectional view illustrating a carbonate extraction valve provided in a water purifier equipped with a carbonated water system according to an embodiment of the present invention.

As shown in FIG. 6 , in the water purifier equipped with the carbonated water system according to the embodiment of the present invention, the carbonate extraction valve 441 includes purified water W2 or cold water ( The upper frame 441a through which W3) passes, the lower frame 441b through which carbonic acid (G) passes through communication with the inside of the carbonic acid cylinder member 440 , and the lower frame 441b inside the carbonic acid cylinder member 440 . It may include an opening/closing door 441c that opens the carbonic acid flow path while being pressed by the pressure of the purified water W2 or cold water W3 to selectively communicate with the . The opening/closing door 441c may be provided with an elastic spring that applies an elastic force in a direction to close the carbonate flow path. That is, when the pressure of the purified water W2 or the cold water W3 is not applied to the opening/closing door 441c, the carbonic acid flow path is closed and the carbonic acid is not supplied from the carbonic acid cylinder member 440 . In addition, the opening and closing door 441c may be provided with a plunger as a medium for transmitting the pressure of the purified water (W2) or the cold water (W3). Pure water W2 or cold water W3 flows to one side of the plunger, and carbonic acid flows to the other side of the plunger. As such, when the opening/closing door 441c is pressed through the pressure of the purified water W2 or the cold water W3, the carbonic acid flow path is opened and the carbonic acid G is supplied, so that a separate driving unit for driving the carbonic acid extraction valve 441 is provided. Carbon dioxide (G) can be supplied even if it is not done, so weight reduction and manufacturability are improved through configuration simplification.

As shown in FIG. 5 , in the water purifier equipped with the carbonated water system according to the embodiment of the present invention, the carbonated water generator 400 includes a second safety flow path member SL2 branched from the carbonated water supply flow path member 450 . and a second safety valve member SV2 that opens and closes so that carbonic acid is discharged through the second safety flow path member SL2 when the pressure of the carbonic acid supplied through the carbonic acid supply flow passage member 450 is equal to or greater than a predetermined pressure. . For example, the second safety valve member SV2 may ^{be configured to be opened to a carbonic acid pressure of about 10K (kgf/cm 2} ), and the aforementioned second safety flow path member SL2 communicates with the drain unit 600 . can be ^{That is, even if a high pressure of 10K (kgf/cm 2} ) or more occurs in the process in which carbonic acid is supplied, the second safety valve member SV2 is opened and the high pressure is released through the second safety flow path member SL2, so that the carbonic acid supply flow path member ( By preventing damage to the water purifier 450 , it is possible to secure the durability of the water purifier and at the same time eliminate the clogging of the drainage unit 600 by using high-pressure carbonic acid.

7 is a block diagram illustrating a drainage unit provided in the carbonated water system according to an embodiment of the present invention.

As shown in FIG. 7 , in the water purifier equipped with the carbonated water system according to the embodiment of the present invention, the drain unit 600 is a drain for discharging foreign substances and water discharged through the flushing passage member 610 to the outside. It includes a flow path member 670 , and the carbonated water discharge flow path member 410 may communicate with the drain flow path member 670 so that carbonated water passes through the drain flow path member 670 and is discharged to the outside. As described above, the sea ice water discharged from the ice generating unit 700 or the ice extracting unit 720 is accommodated in the drain tank member 660 through the first and second sea ice water discharge passage members 661 and 662 . . The thawed water (including carbonated water in some cases) accommodated in the drain tank member 660 is discharged through the first discharge flow path member 620 , and the cold water W3 discharged from the cold water generator 300 is discharged through the second discharge flow path. The fluid such as sea ice water discharged through the member 630 and discharged through the first and second discharge flow path members 620 and 630 is pressurized through the discharge pump member 640 and then the third discharge flow path member 650 ) is discharged to the outside, and for this purpose, the third discharge passage member 650 is also configured to communicate with the drain passage member 670 . That is, even if foreign substances and water discharged through the flushing passage member 610 are discharged to the outside through the drain passage member 670 for a long period of time, carbonated water discharged through the carbonated water discharge passage member 410 passes through the drain passage member 670 . By being configured to do so, the inside of the drain passage member 670 is maintained so as not to be blocked, thereby improving driving stability of the water purifier.

In addition, as shown in FIG. 7 , in the water purifier equipped with the carbonated water system according to the embodiment of the present invention, the drain unit 600 is connected to the flushing passage member 610 and the carbonated water discharge passage member 410 , respectively. n (n is an integer greater than or equal to 2) number of unit valve members 680, and the fluid that has passed through the n number of unit valve members 680 is discharged through k (an integer less than n) drain passage members 670 It may include a multi-tube member 690 connecting the n unit valve members 680 and the k drain passage members 670 as possible. At this time, the fluid such as sea ice water discharged through the third discharge passage member 650 is also discharged to the outside through the drainage unit 600 , and for this purpose, the unit valve member 680 connected to the third discharge passage member 650 . ) may also be provided. Fluids such as thawed water passing through the unit valve member 680 can also be configured to be discharged to the outside (3 IN - 1 OUT structure) after moving to the drain channel member 670 through the multi-tube member 690. . That is, since the fluid is discharged by connecting a number of drain flow path members 670 that is smaller than the number of unit valve members 680 , the time required for installing each flow path member is shortened, and each flow path member is occupied Space efficiency is improved by efficiently using the space to be created. In this case, it is also possible to directly connect the carbonated water discharge channel member 410 to the drain channel member 670 .

In addition, as shown in FIG. 7 , in the water purifier equipped with a carbonated water system according to an embodiment of the present invention, the multi-tube member 690 includes n inlet legs 691 connected to the unit valve member 680, respectively. and k outlet legs 692 respectively connected to the drain channel member 670 , and a multi-body 693 connecting the plurality of inlet legs 691 and the outlet legs 692 to each other. The multi-tube member 690 may be manufactured by an injection method such that the inlet leg 691 , the outlet leg 692 , and the multi-body 693 are integrally formed. In this way, the fluid flowing out from each unit valve member 680 flows into the multi-body 693 through the inlet leg 691 and then moves to the drain channel member 670 through the outlet leg 692, but the multi-body Since 693 interconnects the plurality of inlet legs 691 and outlet legs 692 with each other, fluid can be discharged using a relatively smaller number of drain channel members 670 than the channel members through which the fluid flows, so that each flow path The time for installing the members is shortened, and space efficiency is improved by efficiently using the space occupied by each flow path member.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same spirit. , changes, deletions, additions, etc. may easily suggest other embodiments, but this will also fall within the scope of the present invention.

100: filtration unit 110: reverse osmosis filter member
120: pre-treatment filter member 130: post-treatment filter member
200: purified water storage unit 300: cold water generation unit
400: carbonated water generator 410: carbonated water discharge flow path member
420: carbonated water flow path control member 430: water supply flow path member
431: first supply passage member 432: second supply passage member
433: third supply passage member 440: carbonic acid cylinder member
441: carbonic acid extraction valve 441a: upper frame
441b: lower frame 441c: opening and closing door
450: carbon dioxide supply flow path member 460: mixing member
470: pressure member 500: water outlet
510: first purified water supply flow path member 520: second purified water supply flow path member
530: cold water supply flow path member 540: carbonated water supply flow path member
600: drain 610: flushing flow path member
620: first discharge flow path member 630: second discharge flow path member
640: discharge pump member 650: third discharge flow path member
660: drain tank member 661: first thawed water discharge flow path member
662: second sea ice water discharge flow path member 670: drain flow path member
680: unit valve member 690: multi-tube member
691 inlet leg 692 outflow leg
693: multi-body 700: ice generating unit
710: ice supply flow path member 720: ice extraction unit
800: control unit G: carbonic acid
SL1: first safety flow path member SL2: second safety flow path member
SV1: 1st safety valve member SV2: 2nd safety valve member
W1 : foe W2 : integer
W3 : cold water W4 : carbonated water

Claims (11)

a filtration unit provided with a reverse osmosis filter member to filter raw water to generate purified water;
a purified water storage unit for storing the purified water supplied from the filtering unit;
a cold water generating unit receiving purified water from the filtering unit or the purified water storage unit to generate cold water;
a carbonated water generator configured to receive purified water from the filtration unit or the purified water storage unit or receive cold water from the cold water generator to generate carbonated water;
a water outlet through which the purified water supplied from the filtering unit or the purified water storage unit, the cold water supplied from the cold water generating unit, or the carbonated water supplied from the carbonated water generating unit is discharged; and
a drain unit provided with a flushing passage member to discharge foreign substances and water discharged from the reverse osmosis filter member to the outside;
includes,
and wherein the carbonated water generating unit includes a carbonated water discharge passage member communicating with the drainage unit so that carbonated water is discharged to the outside through the drainage unit. The method of claim 1,
The carbonated water generator according to claim 1, wherein the carbonated water generator further includes a carbonated water flow path adjusting member for controlling whether carbonated water is supplied to the water outlet or discharged to the drain. 3. The method of claim 2,
Further comprising a control unit for controlling the operation of the carbonated water flow path control member,
The water purifier provided with a carbonated water system, wherein the control unit controls the carbonated water to be discharged to the drain unit through the carbonated water discharge passage member for a predetermined period of time before the carbonated water is supplied to the water outlet. 3. The method of claim 2,
The carbonated water generator includes a first safety flow path member branched from the carbonated water discharge flow path member, and opens and closes such that carbonated water is discharged through the first safety flow path member when the pressure of the carbonated water discharged through the carbonated water discharge flow path member is a predetermined pressure or higher A water purifier equipped with a carbonated water system, characterized in that it includes a first safety valve member. 3. The method of claim 2,
The carbonated water generating unit may include a water supply passage member through which purified water supplied from the filtering unit or the purified water storage unit or cold water supplied from the cold water generating unit moves, a carbonated water supply passage member through which carbonic acid supplied from the carbonated cylinder member moves; and a mixing member for generating carbonated water by mixing purified or cold water supplied through the water supply passage member and carbonic acid supplied through the carbonic acid supply passage member,
and the carbonated cylinder member includes a carbonated extraction valve for controlling the supply of carbonic acid by using the pressure of purified or cold water supplied through the water supply passage member. 6. The method of claim 5,
The carbonated water generator according to claim 1, wherein the carbonated water generator further includes a pressing member for pressing the purified or cold water supplied through the water supply passage member to a predetermined pressure. 6. The method of claim 5,
The carbonic acid extraction valve includes an upper frame through which purified or cold water supplied through the water supply passage member passes, a lower frame communicating with the inside of the carbonic acid cylinder member and allowing carbonic acid to pass through, and the lower frame including the carbon dioxide cylinder member. A water purifier equipped with a carbonated water system, comprising an opening and closing door that opens a carbonate flow path while being pressed by the pressure of purified or cold water to selectively communicate with the inside. 6. The method of claim 5,
The carbonated water generator may include a second safety flow path member branched from the carbonic acid supply flow path member, and opens and closes such that carbonic acid is discharged through the second safety flow path member when a pressure of the carbonic acid supplied through the carbonic acid supply flow path member is equal to or greater than a predetermined pressure A water purifier equipped with a carbonated water system, characterized in that it includes a second safety valve member. The method of claim 1,
The drain unit includes a drain passage member for discharging foreign substances and water discharged through the flushing passage member to the outside,
wherein the carbonated water discharge passage member communicates with the drain passage member so that carbonated water passes through the drain passage member and is discharged to the outside. 10. The method of claim 9,
The drain unit may include n unit valve members (n is an integer greater than or equal to 2) respectively connected to the flushing channel member and the carbonated water discharge channel member, and k pieces (less than n) of fluid passing through the n unit valve members. and a multi-tube member communicating the n unit valve members and the k drain channel members so that purified water is discharged through the drain channel member. 11. The method of claim 10,
The multi-tube member includes n inlet legs respectively connected to the unit valve member, k outlet legs respectively connected to the drain passage member, and a multi-body connecting the plurality of inlet legs and the outlet legs to each other. Water purifier equipped with carbonated water system, characterized in that it comprises.

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