KR200401444Y1 - Cooled and Supplied Water Ionizer - Google Patents

Abstract

The present invention relates to an ionizer, it is possible to combine the cold or normal temperature water by the selection according to the user's needs.

The combined cold and cold water ionizer according to the present invention is provided with a purified water filter part 2 in the tap water supply pipe 1 supplied at room temperature, and the branch pipe 4 is connected to the purified water supply pipe 3 connected to the purified water filter part 2. The first purified water supply pipe (5) and the second purified water supply pipe (6) are respectively connected to the branch pipe (4), and the cold storage water tank (8) and the cold purified water required for generating cold ion water are connected to the first purified water supply pipe (5). The supply pipe 11, the purified water pump 12, the first solenoid valve 13, and the first electrolyte tank 14 are connected in series, and the first electrolyte tank 14 has a first acidic water outlet 15 and a first alkaline water. The outlet 16 is connected to each other, and the second purified water supply pipe 6 is connected to the second solenoid valve 7 and the second electrolytic bath 23 which are necessary for generating room temperature ionized water in series, and to the second electrolytic bath 23. The second acidic water outlet 25 and the second alkaline water outlet 24 are connected to each other.

According to the combined cold and cold water ionizer of the present invention, the inconvenience of refrigeration and storage of the ionized water for drinking, which is a disadvantage of the conventional wall-mounted room temperature water ionizer, and the weakening of the ion water characteristics in the refrigerating process are solved. Disadvantages of water shortage during continuous water extraction and utilization of ionized water as functional water in the kitchen Using water bowl to prevent water from discharging into the kitchen and use of functional water of ionized water, which does not have to be cold ionized water, prevent unnecessary use of cold ionized water. You can save.

Description

Cold room temperature combined ionizer {Cooled and Supplied Water Ionizer}

The present invention relates to an ionizer capable of ionizing water into acidic ionized water and alkaline ionized water, and more particularly, cooling the purified water through the purified water filter unit by electrolysis to generate cold ionized water or room temperature. The purified water of electrolyzed to generate room temperature ionized water to produce ionized water by cold and cold combined use.

Recently, with the improvement of living standards, interest in water, especially functional water, has been increasing, various ionizers have been developed and introduced. Existing ionizer groups can be roughly classified into two types, room temperature ionizer and cold ionizer group in the generation of acidic and alkaline ionized water by electrolysis of water supplied to the ionizer. Room water ionizers are the most common type of water ionizers so far, commonly referred to as wall-mounted, wall-mounted, or direct-attached, and purified by tapping the water at room temperature supplied through tap water supply pipes to produce room temperature ionized water.

Cold ionizer purifies the supplied tap water, as in the case of Utility Model Patent Application No. 20-2001-0019363, and cools the purified water in a cold water tank, and then generates cold ionized water by electrolyzing the cooled purified water. do.

Other cold ionized water generation methods are the same as Utility Model No. 20-2001-0034625, 'Cold Alkaline Water Maker', but this method uses the method of electrolyzing the purified water first and ionizing it, and then storing the cooled water and cooling the ionized water in the cold water tank. In the process of storage, calcium crystallized, calcium scale was generated in the cold water tank, and the characteristics of the ionized water were weakened.

The two kinds of water ionizers, which have been classified as above, have problems in utilization. The room temperature water ionizers are excellent in the use of the ionized water as kitchen cooking water, while the characteristics of the ionized water decrease in the process of storing the ionized water in the refrigerator for drinking the ionized water. In addition, the cold water heater is convenient for drinking the ionized water, but the inconvenience of having to move the ionized water to the kitchen using the water bowl in the use of the ionized water in the kitchen and the waste of energy required for cooling generated by using the cold ionized water that is unnecessary in the use of the cooked water in the ionized water. After the withdrawal of the water stored in the cold storage tank has a problem that it is not possible to continuously supply the required amount of water when using the kitchen cooking water of the ionized water.

Therefore, the present invention was devised in view of the conventional problems as described above, and its purpose is to provide room temperature ionized water that is not subjected to a cooling device by the user's choice when it is necessary to continuously discharge ionized water at room temperature such as kitchen cooking water. When water generation is continuously generated and cold ionized water is needed for drinking the ionized water, cold ionized water can be generated and extracted by the user's selection to improve the convenience of the ionizer user, the utilization of the ionized water, and energy saving.

In order to achieve the above object, the combined cold and cold water ionizer of the present invention is a purified water filter, which is generally composed of a four-stage composite filter such as a pre-filter, a carbon filter, a hollow fiber membrane filter, and a post-carbon filter in a tap water supply pipe into which tap water is introduced at room temperature. Purge water by connecting the purified water supply pipe to the purified water supply unit, and install a branch pipe connected to the purified water supply pipe to enable the purified water flowing from the purified water supply pipe through the two pipes. Connect the 1st purified water supply pipe and the 2nd purified water supply pipe respectively so that the purified water flows through the two pipes, and install and install the cold water tank to store and cool the purified water to generate cold ion water in the 1st purified water supply pipe, Connect the cold purified water supply pipe to discharge the purified water from the cold storage tank. High and low temperature purified water supply pipe is connected to the purified water pump for discharging the cooled purified water from the cold water tank, and the first solenoid valve connected to the purified water pump to allow the inlet or shut off of the purified water from the purified water pump In addition, the first solenoid valve is connected to the first electrolytic bath in which the cold purified water can be electrolyzed into the acidic ionized water and the alkaline ionized water, and the cold acidic water and the alkaline ionized water generated inside the electrolytic cell are discharged to the first electrolytic cell. The first acidic water outlet and the first alkaline water outlet are connected to each other to discharge cold acidic and alkaline ionized water, and a second solenoid valve can be connected to the second purified water supply pipe to inlet or block the purified water at room temperature. The solenoid valve has a second electric field that can electrolyze purified water at room temperature into acidic and alkaline water. Installing the tank connection, and a second acidic feeding outlet and a second outlet alkaline second so that the acidic water and alkaline ionized water at room temperature generated in the electrolytic bath in the electrolytic cell may be constructed by respectively connecting each outlet installed.

In particular, a branch pipe is installed in the purified water supply pipe so that purified water flows through the first purified water supply pipe and the second purified water supply pipe, and the purified water introduced through the first purified water supply pipe is cooled to generate cold ion water through the first electrolytic bath. The purified water introduced into the room temperature through the second purified water supply pipe generates room temperature ionized water through the second electrolytic bath, and the inflow of the purified water from the first purified water supply pipe and the second purified water supply pipe enables selective operation of the first solenoid valve and the second solenoid valve. It is characterized by adjusting by.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the present invention cold water combined water ionizer.

1 illustrates a structure of a cold room temperature combined ionizer configured by a basic embodiment of the present invention, and the tap water introduced through the tap water supply pipe 1 is typically a pre-filter, a carbon filter, a hollow fiber membrane filter, a post-carbon filter, or the like. It is configured to purify water through the purified water filter unit 2 consisting of a four-stage composite filter, the purified water filter unit 2 may be equipped with an additional filter or replaced with another filter as necessary.

The inflow of purified water purified by the purified water filter unit 2 is made through two pipes, namely, the first purified water supply pipe 5 and the second purified water supply pipe 6, by the branch pipe 4 installed in the purified water supply pipe 3. .

The purified water flowing through the first purified water supply pipe (5) is to generate cold ionized water and is connected to the cold storage tank (8) for cooling. The purified water cooled in the cold storage tank (8) is operated by the purified water pump (12). When the solenoid valve 13 is operated, the solenoid valve 13 is introduced into the first electrolytic tank 14 through the cold purified water supply pipe 11 connected to the cold water tank 8. To this end, the cold purified water supply pipe 11 is connected to the cold storage tank 8, and the purified water pump 12 is connected to the purified water pump 12, and the purified water pump 12 is subsequently connected to supply or block the purified water. The first solenoid valve 13 is connected and installed, and the first solenoid valve 13 is connected to the first solenoid valve 13 to install a first electrolytic cell 14 capable of electrolyzing cold purified water into acidic and alkaline ionized water.

The operation of the purified water pump 12 and the first solenoid valve 13 is performed by an electronic control unit (not shown) as an optional operation for generating cold ion water of the first electronic control key input unit (not shown).

The cold purified water introduced into the first electrolytic bath 14 is electrolyzed to generate cold acidic water and alkaline ionized water, and the first acidic water outlet 15 and the first alkaline water connected to the first electrolytic bath 14 are installed. It is discharged through the outlet 16, respectively.

The operation of the first electrolytic cell 14 during the electrolysis is performed by controlling the power supply by operating the electronic control unit (not shown) by the operation of the first electronic control key input unit (not shown).

Purified water flowing through the second purified water supply pipe (6) is to generate room temperature ionized water, and is connected to the second purified water supply pipe (6) to connect or install a second solenoid valve (7) capable of introducing or blocking purified water at room temperature, The second solenoid valve 7 is provided with a second electrolytic tank 23 capable of electrolyzing purified water at room temperature into acidic and alkaline ionized water.

The operation of the second solenoid valve 7 is caused by the operation of the electronic control unit (not shown) by a selective operation for generating the room temperature ionized water of the second electronic control key input unit (not shown).

When the second solenoid valve is operated, purified water at room temperature flows into the second electrolytic cell 23 to be electrolyzed to generate acidic and alkaline ionized water at room temperature, and the acidic and alkaline ionized water at room temperature is supplied to the second electrolytic cell 23. The second acidic water outlet 25 and the second alkaline water outlet 24 which can be discharged are connected to each other.

The operation of the second electrolytic cell 23 during the electrolysis is performed by the operation of the second electronic control key input unit (not shown) to operate the electronic control unit (not shown) to adjust the power supply.

The first electronic control key input unit (not shown) is selectively operated to generate cold ionized water, and the second electronic control key input unit (not shown) is provided to be selectively operated to generate room temperature ionized water, respectively. It may be provided as an electronic control key input unit (not shown in the drawing) integrating the provided.

Cooling of the cold storage tank (8) uses a vapor pressure refrigerator consisting of a compressor (19), a condenser (18), a dryer (17), a refrigerant pipe (10), etc., which are typically applied to a cold and hot water condenser. Coolant passing through) is cooled by the gas liquefaction heat passing through the coolant tube 10 wound outside the cold water tank 8 through the dryer 17 and the capillary tube.

The generation and discharge of hot water from the cold combined temperature water heater of the present invention is connected to the hot water inlet pipe 22 to the separator plate 9 installed inside the cold water tank 8 generally applied to the cold and hot water heater, to the hot water inlet pipe 22 The hot water tank 20 may be connected and installed, and the hot water outlet 21 may be connected to and installed in the hot water tank 20.

Figure 2 shows the structure of the cold room temperature combined ionizer configured by the application of the present invention, the first electrolytic bath 14 for generating cold ion water and the second electrolytic bath 23 for generating room temperature ionized water, respectively, Unlike the basic embodiment of FIG. 1, in order to allow the cold purified water and the room temperature purified water to flow into a single installed electrolytic cell 31, the first branch pipe replaces the branch pipe 4 of FIG. 1, and the second The branch pipe 26 is installed by connecting between the first solenoid valve 13, the second solenoid valve 7, and the electrolytic cell 31, respectively, and the first solenoid valve 13 and the second solenoid valve 7 are installed. By the selective operation of the cold purified water or room temperature purified water is selectively introduced into the electrolytic cell 31 through the second branch pipe (26) to allow the cold or room temperature water to be selectively generated in a single electrolytic cell.

That is, when the purified water pump 12 and the first solenoid valve 13 are operated by the selective operation of the first electronic control key input unit (not shown), the cold purified water flows into the electrolytic cell 31 to generate cold ionized water. When the second solenoid valve 7 is operated by the selective operation of the second electronic control key input unit (not shown in the drawing), room temperature purified water flows into the electrolytic cell 31 to generate room temperature ionized water, and cold ionized water in a single installed electrolytic cell 31. Or room temperature ion water is selectively generated.

In addition, the acidic water outlet 32 and the alkaline water outlet pipe 33 for discharging the alkaline ionized water and the alkaline ionized water generated during the electrolysis to the electrolytic cell 31 are connected to the alkaline water outlet pipe 33. 27) is connected, and the first alkali export outlet 28 and the second alkali export outlet 29 are connected to the third branch pipe 27.

According to the cold room temperature combined ionizer of the present invention configured as described above, it is possible to selectively generate cold ion water and room temperature ion water according to the use of the ion water to be utilized can solve the problem of the existing ionizer.

In other words, the room temperature water heater is excellent in the use of the ionized water as a kitchen cooking water, while the ionized water characteristics are reduced in the process of storing the ionized water in the refrigerator for drinking the ionized water, cold ionized water is convenient for drinking the ionized water in the kitchen In the use of ion water, the inconvenience of having to transfer the ionized water to the kitchen using the water grout, and the use of unnecessary cold ion water in the use of the kitchen cooking water of the ionized water, leads to the waste of energy required for cooling and the water stored in the cold water tank. While there is a problem in that it is not possible to continuously withdraw the required amount of water when using the kitchen cooking water, according to the cold room temperature combined ionizer of the present invention, when the user's choice requires continuous extraction of uncooled ionized water such as kitchen cooking water. Generate room temperature ionized water When you want to spill and drink cold ionized water can be generated and discharged to prevent the problems of the existing cold and normal temperature water heater.

1 is a configuration of a cold room temperature water ionizer according to a basic embodiment of the present invention.

Figure 2 is a block diagram of a cold room temperature dual ionizer according to an embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

1: tap water supply pipe 2: purified water filter

3: purification water supply pipe 4: branch pipe

5: 1st purified water supply pipe 6: 2nd purified water supply pipe

7: 2nd solenoid valve 8: cold water tank

9: Separator 10: Refrigerant Tube

11: cold purified water supply pipe 12: purified water pump

13: first solenoid valve 14: first electrolytic cell

15: first acidic water outlet 16: first alkaline water outlet

17: dryer 18: condenser

19: compressor 20: hot water tank

21: hot water outlet 22: hot water inlet pipe

23: 2nd electrolyte tank 24: 2nd alkaline water outlet

25: second acidic water outlet 26: second branch pipe

27: 3rd branch engine 28: 1st alkali export outlet

29: 2nd alkali export outlet 30: 1st branch pipe

31: electrolyzer 32: acid export outlet

33: alkaline water outlet pipe

Claims (3)

Purified water filter unit 2 for purifying tap water is connected to the tap water; A purified water supply pipe 3 connected to the purified water filter to supply purified water; A branch pipe (4) connected to the purified water supply pipe (3) to allow the introduction of purified water through the first purified water supply pipe (5) and the second purified water supply pipe (6); A first purified water supply pipe 5 and a second purified water supply pipe 6 respectively connected to the branch pipes 4 to introduce purified water; A cold storage tank 8 connected to the first purified water supply pipe 5 to cool the purified water; A cold purified water supply pipe (11) connected to the cold storage tank (8) for introducing cooled purified water; A purified water pump 12 connected to the cold purified water supply pipe 11 to discharge cold purified water of the cold storage tank 8; A first solenoid valve 13 connected to the purified water pump 12 to control inflow or blocking of the purified water discharged from the purified water pump 12 into the first electrolytic tank 14; A first electrolytic tank 14 connected to the first solenoid valve 13 to electrolyze the introduced cold purified water into cold acidic water and alkaline water; A first acidic water outlet 15 and a first alkaline water outlet 16 connected to the first electrolyte tank 14 to discharge cold acidic water and alkaline water; A second solenoid valve 7 connected to the second purified water supply pipe 6 to control inflow or blocking of purified water at room temperature into the second electrolytic tank; A second electrolytic tank 23 connected to the second solenoid valve 7 to electrolyze the purified water introduced at room temperature into acidic ionized water and alkaline ionized water at room temperature; It is connected to the second electrolytic tank (23), respectively, having a cold acidic temperature water ionizer characterized in that it comprises a second acidic water outlet (25) and the second alkaline water outlet (24) for discharging the acidic and alkaline ionized water at room temperature. The method of claim 1, The branch pipe 4 is replaced with the first branch pipe 30, and the second electrolytic tank 23, the second acidic water outlet 25, and the second alkaline water outlet 24 are removed, respectively. The first electrolytic cell 14 is replaced with the electrolytic cell 31, and the second branch pipe 26 is installed between the second solenoid valve 7, the second solenoid valve 13, and the electrolytic cell 31, and The first solenoid valve 13 is operated by the operation of the electronic control key input unit (not shown) to allow the coolant to flow into the electrolytic cell 31, or by the operation of the second electronic control key input unit (not shown). The second solenoid valve 13 is operated to allow the room temperature purified water to flow into the electrolytic cell 31 to produce a cold ion water or room temperature ionized water in a single electrolytic cell, characterized in that it is provided with a cold and cold water. The method of claim 1, A first electronic control key input unit (not shown) for operating the first solenoid valve 13, the purified water pump 12, and the first electrolytic tank 14 to electronically control operations; And a second electronic control key input unit (not shown) for operating the second solenoid valve 7, the purified water pump 12, and the second electrolytic tank 23 to be electronically controlled. Water ionizer.