KR100850375B1 - Ionizer with the Collect and Removal Function of Reaction Material - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ionized water generating device having a function of capturing and removing an ionization reactant which is an ionization reaction scalp foreign substance remaining in a reservoir of ionized water after electrolysis reaction and causing deposition and clogging. In the ionized water generating device, a simple ionized water storage reservoir or a reservoir equipped with a cooling function is manufactured so that the bottom portion is inclined at an angle to the bottom, and the partition plate mounted inside the reservoir has a predetermined angle below the horizontal, that is, 5 It is designed to be inclined at -45 degrees so that the ionization reaction material of ionized water introduced into the reservoir can be easily moved to the bottom and bottom of the reservoir by the separator plate, and the compartment separator plate inside the reservoir bounds the compartment separator plate. Water temperature is configured differently by preventing the water of upper and lower furnaces from mixing with each other Configured such that the tube is provided to enable the outlet according to the application.

Ionized water, ionization reactants, compartment separators, reservoirs

Description

Ionizer with the Collect and Removal Function of Reaction Material

1 is a configuration of a cold ion water generator equipped with a conventional reservoir.

Figure 2 is a perspective view of the cold ion water heater equipped with a cold ion water generator of the present invention.

Figure 3 and Figure 4 is a schematic view of the cold ion water generating device equipped with a reservoir of the present invention.

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Figure 5 is a structure of the reservoir outlet port acting on the cold ionized water generating device of the present invention.

6 and 7 are a perspective view and a structural view of the reservoir compartment separator plate applied to the cold ionized water generating device of the present invention.

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Figure 8 is an operating structure showing the flow of reactants and water in the reservoir applied to the cold ionized water generating device of the present invention.

9 is a flow chart of reactant discharge in the reservoir of the cold ionized water generating device according to the present invention.

* Explanation of symbols for main parts of the drawings

2,22: water filter 3: pressurized pump

4: electrolytic cell 8: reservoir

31,32: compartment separation plate 10: room temperature water outlet

20: cold ion water outlet 36: ionization reactant outlet

101: room temperature ionized water withdrawal coke 201: cold ionized water withdrawal coke

34 open and close valve 35 pressurized pump

9a: compressor 61a: room temperature ionized water

61b: cold ionized water 71: ionization reactant

81: insulation material

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ionizer having a function of capturing and removing reactive scale materials generated during storage in a reservoir after purifying an ionization reaction. After the deionization ionization reaction, the ionization reaction scale material is easily moved to the bottom and bottom of the reservoir by using a partition plate inside the reservoir, and the collection is induced. The present invention relates to an ionized water generating device having a function of capturing and removing an ionization reactant, which can be extracted to the outside.

In general, ionized water generator cleans raw water such as tap water through a complex filter or a general water filter of several stages (multi-stage), and then receives electrolysis of the anode and cathode across the membrane in the electrolytic cell under the command voltage of the controller. As an ion, alkali water is ionized at the cathode and acidic water at the anode, and alkaline water is taken. The acidic water is discharged to the outside through the discharge valve or, if necessary, extracted through a dedicated pipe.

In the case of most ionized water generators, direct water at room temperature is passed through a water filter to remove raw water, such as tap water, and then ionized in an electrolytic cell, and immediately outflows of room temperature ionized water through a water tap attached to the front of the device. However, a cold ionized water generator is also provided, which is ionized as needed and then cooled in a reservoir with a cooling function to extract when needed.

In devices where the flow rate of raw water flowing into the ionized water generator is small or requires a large amount of electrolyzed water, that is, a large capacity device that continuously uses a large amount at a time in a restaurant or a public place, ionized water is inevitably A storage tank will be needed separately. In addition, in the case of cold water ionizer, after the ionization after purification, to use the ionized water to cool the separate cooling reservoir is required.

The purified water flowing into the electrolytic cell is separated into both the alkaline water generated at the cathode side and the acidic water generated at the anode side by electrolysis. Although it is possible to adjust differently by about 50% and at most 70%: 30%, in principle, the amount of raw water introduced and the amount of extracted water are the same. Therefore, in the case of alkaline water, which is required drinking water, the limit of not more than 70% of the maximum amount of raw water inflow is inevitably felt that the flow rate of the outflow water is inevitably felt especially when the amount of inflowing raw water is low or continuously extracted.

Ionized water refers to water ionized by an electrochemical reaction obtained by losing an electron, and is classified into alkaline ionized water and acidic ionized water. When water is electrolyzed, the negative electrode contains a large amount of hydroxyl ions (OH-) by the reaction of generating hydrogen gas (H2), and alkaline ionized water rich in minerals such as Ca2 +, Mg2 +, and K2 + is produced. In the pole, hydrogen ions (H +) are contained in a large amount by the reaction of generating oxygen gas (O2), and acidic ionized water rich in ions such as Cl-, S2-, and P3- is produced.

As a result of the reaction, the mineral components are stored in alkaline water used as drinking water as time goes by. Is a sediment (scale) substance in which water is deposited or remains suspended. As a result, deposits and blockages occur over time in containers or pipes stored for a certain time. Therefore, this problem of periodic cleaning (cleaning) of scale is a major problem.

The countermeasures for ionization reactants are commonly required in both reservoirs for storing room temperature ionized water and reservoirs for the production and storage of cold ionized water.

1 is a block diagram of a cold ion water generating device equipped with a conventional reservoir.

First, the inflow water from the water pipe 1 becomes purified water through the composite filter 22, and the purified water is water into which the pressurized pump 3 located in front of the electrolytic cell 4 flows into the electrolytic cell 4. Acid and alkaline water are produced after electrolysis by pressurizing and supplying acidic acid, acidic water flows out through the discharge valve (6), and drinkable alkaline water flows into the cooling reservoir (8) and then stored. If necessary, the structure is used externally through the cold ionized water outlet coke 201 connected to the reservoir 8 and the cold ionized water outlet 20.

However, as shown in FIG. 1, the reservoir 8 of the conventional cold ionized water generator was composed of a single reservoir with a simple reservoir and a cooling function. Therefore, the ionized water stored in the reservoir (8) for a certain time has the disadvantage that the ionization reactant is deposited on the bottom of the reservoir and must be cleaned after a certain time, even if the cleaning is usually the outlet (20) connected to the bottom of the reservoir (20) In the hall, a large amount of scalable material is already attached, and cleaning is hardly performed without using a special chemical at the time of cleaning.

Therefore, there are many difficulties in terms of convenience of use and maintenance of the device, such as preventing the failure of the device and preventing the trouble of cleaning.

Therefore, the present invention is to provide a structure and a method for removing the ionization material of the reservoir configured to facilitate the collection and removal of the ionization reactant commonly applied to both the storage tank of the room temperature ionized water generator or the cooling reservoir of the cold ionized water generator.

From the present invention, by applying the function of capturing the scale material of the ionized water storage reservoir of the room temperature ion generating device or the cold ion water generating device and the easy outflow structure, it is possible to prevent the failure of the device in the long time use due to the attachment of the scale material. In addition, it is possible to safely supply clean ionized water by keeping clean at all times.

Specific application embodiments of the present invention are the same as FIG.

2 is a view illustrating an external structure having a cold ionized water generating device according to the present invention. The cold ionized water according to the present invention includes one or a plurality of cold ionized water generators on one side of a control panel 701 having an operation display function and an external case 501 or 601. Water extraction coke (101,201) is attached to provide a structure that can be extracted from the room temperature ion water as needed with cold ion water from the outside easily.

Figure 3 and Figure 4 shows the overall configuration of the cold ion water generating device equipped with a reservoir of the present invention, the configuration of the generating device is largely composed of a filter section, a fixed section, a reservoir and a cooling section, the control unit, first tap water The control panel 701 of the operation display function in the electrolytic apparatus 4 via the purified water 2 composed of multiple stages such as sediment 2a, carbon 2b, 2d, UF membrane 2c, etc. Alkali ionized water and acidic ionized water are generated by the electrolysis by the application command of the electric control device 702 associated with the < RTI ID = 0.0 >), and < / RTI > The outflow and acidic water flow out to the outside through the discharge valve 6. At this time, the extraction of the ionized water from the reservoir 8 is divided into the upper portion 51a and the lower portion 51b of the partition separator 32, that is, the room temperature ion water of the upper portion and the cold ion water of the lower portion, as necessary. Room temperature ionized water and cold ionized water may be extracted through the water extraction cocks 101 and 201 connected to the 10 and the cold water outlet 20, respectively.

The reservoir 8 for storing the ionized water is composed of a reservoir tank 82 and internal partition separators 31 and 32. The separator plate inside the reservoir may be configured in one stage or two or more stages as necessary. The outer wall of the reservoir 8 is equipped with a compressor 9a, an evaporator 9b, a dryer 9c, and a refrigerant tube 9 for evaporator, which is a vapor rock type cooling cycle cooling structure, to produce cold ion water of a target water temperature. Provides a structure to In addition, if necessary, the upper portion of the partition separator 32, room temperature ionized water, the cold ionized water can be extracted from the lower portion.

In addition, the ionized water generating reaction material inside the reservoir 8 stored for a long time is moved along the surface of the upper plates of the partition separators 31a and 32a to the side portions and finally easily moves from the upper portion of the reservoir 8 to the lower portion. Thus, the open and close valve 34 and the pressure pump 35 operate according to the setting control command of the control device 702 to provide a structure that is discharged to the outside through the ionization reactant outlet 36.

Particularly, the partition separators 31 and 32 mounted inside the reservoir 80 are manufactured to be inclined at a predetermined angle, that is, 5-45 degrees below the horizontal, so that ionization reaction of the ionized water introduced into the reservoir 8 is performed. The material is characterized in that it is made by the partition separators 31, 32 to facilitate movement to the bottom of the reservoir bottom 61 along the upper surface of the partition separator. In addition, the tank 82 of the reservoir 8 is also configured to be inclined at a predetermined angle so that the scale is moved downward along the partition separator plates 31 and 32 to easily attach to the bottom of the bottom 81 of the reservoir. It is done. The lower portion 81 of the reservoir is connected to the reaction material outlet 36 which is a removal passage of the scalable material, the side of the reservoir 8 is the outlet port 10, 20 from which the ionized water without the scalp suspended matter is extracted The piping is configured separately.

The scaled ionization reaction material formed by depositing on the bottom of the reservoir 81 is configured to be discharged to the reactant outlet 36 through a discharge pipe having an opening and closing device periodically attached thereto when the ionization reaction material is deposited after a predetermined time. And, the opening and closing device of the discharge pipe is configured to be automatically performed periodically in the main control device 702. The discharge of the reactant is discharged for a predetermined time and the reactant is first exited through the discharge pipe, and the secondary ion-free general ionized water is discharged to remove the ionization reactant from the bottom of the reservoir 81. It is characterized in that the cleaning is made.

Therefore, the partition separators 31 and 32 mounted inside the reservoir 8 not only prevent the floating of the float water due to the flow of the water in the bottom of the reservoir when inducing the lower deposition of the ionization reactant and extracting the side ionized water. The lower cold ion water 51b of the reservoir 8 is configured to prevent temperature deviation and dilution due to the prevention of mixing with the upper room temperature ion water 51a. As shown in FIG. 3, in a mechanical apparatus having both room temperature ionized water and cold ionized water at the same time, a separate extraction structure may be provided, and partition separator plates 31 and 32 serve as a separator plate for separating room temperature water and cold ionized water. Do this.

Unlike the basic embodiment of FIG. 3 described above, in the application embodiment of FIG. 4, a partition separator 31 mounted and inserted into the water storage tank 8 is formed as a single device for extracting cold ionized water of a simple form through a filter. Purified water produces ionized water by electrolysis of the electrolytic cell 4, and the generated ionized water flows into the reservoir 8 to be cooled and stored to form cold ionized water 51, and as necessary, to the reservoir 8 It is a structure that flows out from the water extraction cock 201 through the connected water outlet 20. The ionization reactant collected by moving to the bottom of the bottom 81 of the reservoir along the surface of the partition separator 31 mounted inside the reservoir 8 is opened and closed by a set application command of the controller 702. 34 and the pressure pump 35 is operated to provide a structure that is discharged to the outside through the ionization reactant outlet (36).

5 is a view illustrating a reservoir outlet port applied to the apparatus for generating cold ionized water according to the present invention, and attaching the outlet port 20 attached to extract the cold ionized water 51 stored in the reservoir 8 to the outside. It is possible to attach it directly to the side surface 82 or the bottom surface 81 of the water storage tank 8, but it is possible to configure freely according to the convenience in manufacturing a device, or the amount and the amount of extracted ionized water.

6 and 7 illustrate a reservoir partition plate of the cold ionized water generating device according to the present invention, wherein the partition plates 32 and 31 are circular flat head plates 32a, which are inclined at an upper angle. 31a) and the lower support pillars 32b and 31b, and the upper partition separator 32 and the lower partition separator 31 are separately configured as needed or used alone or in combination of convex and concave protrusions. (32c, 31c) can be combined.

In particular, in the form of separating and extracting cold and normal temperature water in the water storage tank 8, that is, in a structure for imparting a temperature deviation to the upper water 51a and the lower water 51b on the boundary of the partition separator 32. It is possible to impart a heat insulation effect by forming the inside of the upper shaded slope plate 32a of the partition separator 32 into an empty space or by inserting the heat insulation material 81.

FIG. 8 illustrates the flow patterns of reactants and water in the reservoir of the cold ionizer generator according to the present invention. The ionized water generated through the electrolysis of the electrolyzer 4 is first introduced into the reservoir 8, The introduced water is stored as room temperature ionized water and cold ionized water, and separated from the room temperature ionized water and cold ionized water through the room temperature outlet (10) and the cold outlet (20) as needed, and extracted to the outside. In this case, the inflow and outflow paths are 61a, 62a, 62b in the case of room temperature ionized water, and 61a, 63a, 63b in the case of cold ionized water.

In addition, the ionized water in the reservoir 8 has a different pattern on the boundary plates (31a, 32a), respectively, the lower portion (51c) of the lower partition plate (31a) is the water for discharge, the lower partition plate (31a) ), And the middle portion 51b between the upper partition separator 32a is a cold ionizer, and the upper part 51a of the upper partition separator 32a is separated and preserved without mixing with each other, so that independent extraction is required. to provide.

In addition, the ionized water stored in the reservoir 8 for a long time is moved to the upper and lower surfaces of the partition separation plates 31a and 32a as time passes by the ionization reactant 71, and finally is deposited on the lower floor. The device has a structure that flows out of the device through the ionization reactant outlet 36 by the operation of the device, the path of which is represented by the reference numerals 61b, 61c, 61d, 61e, 61f.

Therefore, the ionization reactant generated in the ionized water in the reservoir 8 is not accumulated in the reservoir, so that the inside of the reservoir 8 is always clean and hygienic, and it is possible to prevent equipment failure and the like in advance.

FIG. 9 is a flow chart illustrating reactant discharge in a reservoir of the cold ionized water generating device according to the present invention. The ionization reactant deposited on the lower portion of the reservoir 8 is discharged to the outside in accordance with a set time and an operation time. A control method is provided to keep the interior of the reservoir 8 clean and sanitary at all times.

In particular, when the machine is installed and started to be used (91a) and the predetermined constant holding time (91b) has elapsed, the opening command (91c) of the control device is applied to the pump and the opening and closing device connected to the outlet valve, and the setting operation is performed. When the time 91d is reached, the closing command 91e is applied to the pump and the opening and closing device by the control device. At this time, the reactant is first discharged from the discharge valve, followed by the second discharge of general water. As the material is removed, the inside of the reservoir 8 is cleaned.

As described above, the cold ion water generating device having the function of capturing and removing the ionization reaction material according to the present invention is applied to the collection function of the scaled ionization reaction material of the ionized water storage reservoir and the easy outflow structure to maintain the device for a long time. It is possible to prevent the failure of the device due to the ionization reaction material attached in advance, and also to keep the clean state at all times, so that clean ionized water can be supplied with confidence.

Claims (4)

In the ionized water generating device provided with a reservoir, The lower part of the reservoir of the ionized water storage and cooling function is formed to be inclined so that the water of the upper part and the lower part of the reservoir is not mixed with each other, and the partition separator mounted inside the reservoir is inclined 5-45 degrees below the horizontal. Formed and composed of products, The reservoir is organically opened and closed in accordance with periodic or manual operation by a control device command, and discharges the ionized reactants collected at the lower portion of the reservoir to the outside so that the cleaning and cleaning functions are provided to the outside. And pump and valve of opening and closing function are connected, Said partition plate is at least one alone or one or more of the plurality of ionized water generating device having a function of collecting and removing the ionization reactant, characterized in that it is configured inside the reservoir. delete delete The method of claim 1, The reservoir is an ionized water generating device having a function of capturing and removing the ionization reactant, characterized in that the room temperature ionized water and cold ionized water outlet is further connected to the side portion with the ionized water outlet connected to the lower portion.

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