KR20120082659A - Water purifier comprising water ionizer - Google Patents

Abstract

PURPOSE: A water treating apparatus including an electrolytic cell is provided to improve the sanitary property of the electrolytic cell and to secure the sufficient initial pH values of water by draining remaining water from the electrolytic cell. CONSTITUTION: A water treating apparatus includes a filtering part(120), an electrolytic cell(160), and a natural water draining bath(180). The filtering part purified feed water. The electrolytic cell is in connection with the filtering part. The natural water draining bath is in connection with the electrolytic cell and drains remaining water from the electrolytic cell. A draining path is in connection with the lower part of the natural water draining bath. An extracting pump(191) is arranged at the draining path. A switch(182) is arranged between the electrolytic cell and the natural water draining bath.

Description

Water Purifier Comprising Water Ionizer

The present invention relates to a water treatment apparatus including an electrolytic cell, and more particularly, to drain the residual water present in the electrolytic cell after generating the ionized water, to generate the cool water or purified water in the next use, and to remove the noise generated in draining the residual water. It is about a water treatment apparatus.

Generally, cold ionizers are devices that produce alkaline and acidic water by electrolyzing water. Alkaline water is used to make food, boil tea, wash vegetables and fruits, and acidic water is discharged to the outside, or it is sterilized and bleached. When washing your back, it can be used for insect bites and skin wounds.

As shown in FIG. 1, a common cold ionizer includes a filter unit 10 for purifying raw water from the raw water unit 16, and a cold water tank 50 for cooling and storing the purified water supplied from the filter unit 10. And a pump 55 for supplying the purified water cooled in the cold water tank 50 to the electrolytic cell 60, and an electrolytic cell 60 provided after the pump 55 to generate acidic and alkaline water. .

In the electrolytic cell 60, acidic water is sent to the drain flow path 62 to be drained or used for washing. Alkali water is sent along the alkali flow path 61 to the discharge valve 63 for drinking.

In such a conventional cold ionizer, residual water is present in the electrolytic cell 60 after the generation of ionized water. Such residual water impairs hygiene of the electrolytic cell 60, and prolonged use in a state in which water is accumulated in the electrolytic cell 60 is maintained. If not, there is a problem that can not implement the initial pH.

In addition, when there is residual water, when the user extracts the extracted cold ionized water or ionized water, there is a problem that the ionized water extracted before is not discharged from the cold water or the purified water, but the ionized water of the temperature desired by the user is not discharged initially.

The present invention is to solve the above problems, an object of the present invention to improve the hygiene of the electrolytic cell by draining the residual water present in the electrolytic cell, and to provide a water treatment apparatus that can improve the initial pH implementation failure phenomenon.

In addition, an object of the present invention is to provide a water treatment apparatus that does not need to drive the gear pump in order to forcibly remove the residual water, thereby reducing the noise caused by the gear pump and quietly removing the residual water.

The present invention provides the following water treatment apparatus in order to achieve the above object.

The present invention provides a water treatment apparatus including a filter unit for purifying raw water and an electrolytic cell connected to the filter unit, the natural drainage tank connected to the electrolytic cell and draining residual water in the electrolytic cell.

According to the present invention, an opening and closing means is disposed between the electrolytic cell and the natural drainage tank, and the opening and closing means communicates the electrolytic cell and the natural drainage tank when there is no water pressure in the electrolytic cell, and the remaining water is discharged from the electrolytic cell to the natural drainage tank. It may be configured to drain.

In addition, the lower end of the natural drainage tank is connected to the drain passage, the drain passage may be disposed in the extraction pump.

At this time, the extraction pump is preferably an impeller pump.

In addition, a check valve may be disposed between the extraction pump and the natural drainage tank.

Furthermore, the present invention may further include a cold water tank disposed between the filter unit and the electrolytic cell so that the cold water cooled in the cold water tank flows into the electrolytic cell.

The water treatment device may further include a first flow path switching valve disposed between the filter part and the cold water tank; And a second flow path switching valve disposed between the cold water tank and the electrolytic cell, wherein the first flow path switching valve and the second flow path switching valve are connected to each other, respectively, of the first flow path switching valve and the second flow path switching valve. Due to the operation, the cold water from the cold water tank or the purified water from the filter unit may flow into the electrolytic cell.

The present invention is to solve the above problems, it is possible to provide a water treatment apparatus that can improve the hygiene of the electrolytic cell by draining the residual water present in the electrolytic cell, and can improve the initial pH implementation failure.

In addition, the present invention does not need to drive the gear pump to forcibly remove the residual water, the noise caused by the gear pump is reduced, it is possible to provide a water treatment apparatus for quietly removing the residual water.

1 is a schematic view of a conventional cold water heater,
2 is a schematic view of a water treatment apparatus according to an embodiment of the present invention,
FIG. 3 is an enlarged view of an electrolytic cell and a natural drainage tank to show an operation in the water treatment device of FIG. 2.

As described in the related art, in the case of using the electrolytic cell, a method of forcibly draining the electrolytic cell may be considered in order to maintain the temperature and pH of the first cup and improve hygiene inside the electrolytic cell.

However, to force draining the electrolyzer, a pump that can suck air and water together, such as a gear pump, must be used. Such a gear pump is capable of draining water, but noise is inevitably generated due to the driving of the pump. In particular, noise in the process of sucking air and water together is inevitable.

As such, when using the water treatment apparatus, if noise occurs, it may be unsatisfactory to the user, and there is a need to develop a technique for draining without noise.

Hereinafter, with reference to the accompanying drawings will be described in detail the water treatment device 100 according to the present invention.

2 is a schematic diagram of a water treatment 100 according to an embodiment of the present invention. The water treatment apparatus 100 may be a desktop or counttop ionizer or a water purifier having a long flow path and a drain line.

The water treatment apparatus 100 of the present invention, as shown in Figure 2, the filter unit 120 for filtering the raw water from the raw water supply source 101; Cold water tank 140 for storing the cold water conveyed from the filter unit 120; An electrolytic cell 160 connected to the cold water tank 140 to receive cold water; Opening and closing means 182 connected to the electrolyzer 160 to be opened and closed by water pressure; And a natural drainage tank 180 connected to the opening and closing means 182 to drain remaining water in the electrolytic cell 160.

A valve 110 may be disposed between the raw water supply source 101 and the filter unit 120 to adjust the raw water supplied to the filter unit 120. In addition, the filter unit 120 is a membrane (hollow fiber, reverse osmosis) for removing carbon, heavy metals, chemicals, etc. to remove chlorine or suspended matter, debris, rust, etc. included when raw water is introduced from the tap water It consists of an integrated or multiple filters. Advances in technology may add or coat various chemicals to carbon to give additional effects.

A first flow path switching valve 130 may be disposed between the cold water tank 140 and the filter unit 120, and the first flow path switching valve 130 may pass the purified water through the filter unit 120. (140) or divided into the electrolytic cell 160 can be supplied.

The purified water supplied from the first flow path switching valve 130 to the cold water tank 140 is introduced into the cold water tank 140 through the flow path 131. The cold water tank 140 stores cold water transferred from the filter unit 120, and includes a cooling coil 142 surrounding or disposed in the cold water tank 140, and is substantially similar to a conventional cold water tank. Since the structure, a detailed description of the operation principle and structure thereof will be omitted.

Then, the outlet of the cold water tank 140 is connected to the second flow path switching valve 150, the second flow path switching valve 150 is supplied from the first flow path switching valve 130 to the electrolytic cell 160. The flow path 132 to be connected is connected. The second flow path switching valve adjusts the flow path so that any one of the outlet of the cold water tank 140 and the flow path 132 can communicate with the electrolytic cell 160.

That is, when the first flow path switching valve 130 is switched to send the purified water to the electrolytic cell 160, the second flow path switching valve 150 sends the purified water to the electrolytic cell 160 to the flow path 132 and the electrolytic cell ( 160 is switched to communicate. On the contrary, when the first flow path switching valve 130 is switched to send purified water to the cold water channel 140, the second flow path switching valve 150 is switched to communicate the cold water tank 140 with the electrolytic cell 160. .

The electrolytic cell 160 is connected to an acidic water flow passage 162, an alkali water flow passage 161, and a natural drainage flow passage 163. The acidic water flow path 162 passes through the acidic water generated in the electrolytic cell 160, and the alkaline water flow path 161 passes through the alkaline water generated in the electrolytic cell 160. In the case of the natural drainage channel 163, when the operation of the electrolytic cell 160 is stopped, the residual water in the electrolytic cell 160 is discharged to the natural drainage tank 180 through the natural drainage channel 163.

The natural drainage tank 180 has the natural drainage passage 163 connected to the upper side, and an air inlet valve 185 is disposed at the upper side to allow air to flow therein. Natural drainage tank 180 is preferably larger than the capacity of the electrolytic cell 160.

The natural drain passage 163 is provided with an opening and closing means 182 that is opened and closed according to the water pressure. The opening and closing means 182 is preferably configured to open when the natural drain flow path 163 is under pressure. However, the opening and closing means 182 may use a general valve to open when there is no use by the controller (not shown).

A drainage passage 164 is connected to a lower end of the natural drainage tank 180, and a pump 191 is disposed in the drainage passage 164, and the drainage passage is combined with the acidic water passage 162 to provide a drain portion 190. Is discharged through. A check valve (not shown) may be disposed in the drain passage 164 and the acidic water passage 162 to prevent backflow.

On the other hand, the alkaline water flow path 161 is discharged so that the user can drink through the discharge unit 170 via the discharge valve 165.

3 is an enlarged view of the electrolytic cell 160, the natural drainage tank 180, the extraction pump 191 of the present invention.

As shown in FIG. 3, the electrolyzer 160 includes electrodes 167 and 168 disposed inside the case 166; And a film 169 separating the electrodes 167 and 168. Since the configuration of the electrolyzer 160 is widely known in the art, only the features are described in the present invention.

The electrolyzer 160 communicates with the natural drainage passage 163, and the opening and closing means 182 is disposed in the natural drainage passage 163 so that when the electrolyzer 160 is driven, that is, the purified water is supplied to the electrolyzer 160. The opening and closing means 182 closes the natural drainage passage 163 when the pressure is supplied and the opening and closing means 182 opens the natural drainage passage 163 when the pressure is not applied because the purified water is not supplied.

The natural drainage tank 180 is connected to the lower part of the electrolyzer 160. Accordingly, when the opening and closing means 182 is opened, the remaining water of the electrolytic bath 160 flows into the natural drainage tank 180 by gravity. . In this case, air may be introduced through the acidic water passage 162 communicating with the drain 190.

Natural drainage tank 180 is preferably formed larger than the capacity of the electrolytic cell 160 to accommodate the remaining water of the electrolytic cell 160. A drainage path 164 is connected to a lower surface of the natural drainage tank 180, and an extraction pump 191 and a valve 192 are disposed between the drainage path 164 and the drain portion 190.

Extraction pump 191 has a small diameter flow path is formed to help the drainage of the residual water that is not drained from the natural drainage tank 180 to the drain portion 190 due to the flow path friction.

On the other hand, the extraction pump 191 is a low noise pump such as an impeller pump is used. Impeller pumps used in this way may replace a gear pump that is not suitable for use in the water treatment device 100 due to the high noise.

In the case of the impeller pump, when the air is introduced is malfunctioned, the reason is that when the impeller of the impeller pump rotates in the air layer, the water does not fall out, only the impeller is idle. On the other hand, in order to smoothly operate the impeller pump, that is, to remove the air layer in the impeller pump, the natural drainage tank 180 of the present invention is used.

That is, the impeller pump malfunctions by discharging the residual water from the natural drainage tank 180 to the drain portion 190 so that the water is always provided inside the natural drainage tank 180 and the impeller pump can receive the remaining amount of the electrolytic tank. You can't. For example, when the residual water is received, the impeller pump is operated at the height h 'to drain only up to the height h, and when the residual water is discharged from the electrolytic cell 160 and rises again to the height h', the height is increased again. By repeating only the drainage up to h), the impeller pump can be operated without malfunction.

In addition, a valve 192 may be disposed at the rear end of the impeller pump so that the impeller pump is always submerged in water, thereby preventing the remaining water from naturally falling into the drain 190. In general, even when there is no such valve 192 when the flow path is long, since the residual water is not discharged from the natural drainage tank 180 to the drain portion 190 due to the flow path friction, the valve 192 may be selectively employed.

Therefore, in the state having such a natural drainage tank 180, the water may always be filled therein, and it is possible to prevent the inflow of air into the impeller pump due to the water from the natural drainage tank 180. have.

In particular, when the impeller pump is directly connected to the electrolyzer 160 without such a natural drainage tank 180, the flow rate discharged from the electrolyzer 160 is not only constant, but the capacity of the inside of the electrolyzer 160 is small, Due to the electrodes 167 and 168, the flow friction is large and does not go smoothly. Accordingly, the air is fast instead of the residual water by the impeller pump, and the impeller pump no longer functions as a pump when air is placed in the impeller pump. It can't be done.

On the other hand, the air inlet valve 185 is disposed on the upper side of the natural drainage tank 180, when the residual water in the natural drainage tank 180 is discharged by the impeller pump, it can provide a volume of air corresponding thereto. .

As described above, by disposing the natural drainage tank 180, the present invention is equipped with the extraction pump in a simple flow path of the natural drainage tank 180, instead of the complicated internal flow path of the electrolytic cell 160. Therefore, air and water are sucked together due to the operation of the extraction pump, so that the noise generated may be significantly reduced.

Furthermore, in the case of using the impeller pump, since air and water are not sucked together, the residual water can be treated without generating noise, and the user's satisfaction can be greatly increased.

In the case of the present invention, it is preferable when the flow path is long, but of course it can be used even when the flow path is short.

Hereinafter, the operation of the water treatment apparatus 100 of the present invention will be described.

First, when the valve 110 is opened, raw water flows into the filter unit 120. The raw water introduced into the filter unit 120 is purified and transferred to the first flow path switching valve 130, and the purified water is transferred to the cold water tank 140 by the operation of the first flow path switching valve 130 or the second flow path. It is transmitted to the switching valve 150.

Next, the purified water delivered to the cold water tank 140 is cooled in the cold water tank 140 having a coil, and then transferred to the electrolytic cell 160 by the operation of the second flow path switching valve 150. The cold water delivered to the electrolyzer 160 generates cold ion water by the electrolytic reaction in the electrolyzer 160, and the cold ion water generated in this way is extracted from the user through the discharge unit 170 such as coke.

As such, after the ionized water is provided, the remaining water remaining in the electrolytic cell 160 is blocked when the water pressure is filled in the electrolytic cell 160 according to the operation of the switch 182 by the water pressure. It is discharged by gravity to the natural drainage tank 180 installed at the rear end. The residual water delivered to the natural drainage tank 180 is prevented from backflow by a check valve (not shown), and the water remaining in the natural drainage tank 180 is extracted by operating the extraction pump 22 (for example, an impeller pump). do.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those skilled in the art.

100: water treatment device 101: raw water supply unit
110 valve 120 filter unit
130: first flow path switching valve 140: cold water tank
150: second flow path switching valve 160: electrolytic cell
165 discharge valve 170 discharge portion
180: natural drainage tank 182: opening and closing means
190: drain 191: extraction pump

Claims (7)

Filter unit to purify raw water,
A water treatment apparatus including an electrolytic cell connected to the filter unit,
And a natural drainage tank connected to the electrolyzer to drain residual water from the electrolyzer. The method of claim 1,
Opening and closing means is disposed between the electrolytic cell and the natural drainage tank,
And the opening and closing means is configured to communicate the electrolyzer and the natural drainage tank when there is no water pressure in the electrolytic cell, so that the remaining water is drained from the electrolyzer to the natural drainage tank. The method according to claim 1 or 2,
A water treatment device connected to a drain flow path at a lower end of the natural drainage tank, and an extraction pump is disposed in the drain flow path. The method of claim 3, wherein
The extraction pump is an impeller pump,
The impeller pump is driven when there is residual water in the natural waste water tank. The method of claim 3, wherein
And a check valve is disposed between the extraction pump and the natural drainage tank. The method according to claim 1 or 2,
And a cold water tank disposed between the filter part and the electrolytic cell so that the cold purified water cooled in the cold water tank flows into the electrolytic cell. The method according to claim 6,
A first flow path switching valve disposed between the filter part and the cold water tank; And
A second flow path switching valve disposed between the cold water tank and the electrolytic cell,
The first flow path switching valve and the second flow path switching valve is connected,
Due to the operation of the first flow path switching valve and the second flow path switching valve, the cold water from the cold water tank or the purified water from the filter unit flows into the electrolytic cell into the electrolytic cell.

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