KR20150000021A - Water ionizer - Google Patents

Abstract

The present invention relates to an ion water device for supplying sterilization water and alkali water. More specifically, the present invention relates to an ion water device for producing strong acidic water or strong alkaline water with sterilization via electrolysis using a solvent while producing and discharging ion water to drink. The ion water device comprises a second electrolytic cell for generating a sterilization water mixed with the solvent supplied from a solvent part, which has different pH concentration compared with alkaline ion water from a first electrolytic cell wherein the first electrolytic cell generates an alkaline ion water to drink and the second electrolytic cell generates a strong acidic hypochlorous with strong sterilization, thereby providing ion water users want at the same time. Therefore, the present invention relates to the ion water device for supplying alkaline water and the sterilization water at the same time while improving the convenience of users and the efficiency of products. The ion water device comprises a solvent part for supplying solvents; a first electrolytic cell for generating alkaline ion water by electrolyzing water; and a second electrolytic cell which electrolyzes water and generates the sterilization water whose pH concentration is different from the alkaline ion water generated from the first electrolytic cell by mixing the solvent supplied from the solvent part.

Description

[0002] WATER IONIZER capable of simultaneously supplying sterilized water and alkaline water [

The present invention relates to an ionizer for simultaneous supply of sterilized water and alkaline water,

More particularly, the present invention relates to an ionizer for producing strong acidic or strong alkaline water having strong sterilizing power through an electrolysis method using a solvent and simultaneously producing and drinking water,

And a second electrolyzer in which the solvent supplied from the solvent portion is mixed to generate a sterilized water having a pH concentration different from that of the alkaline ionized water of the first electrolytic bath so that alkaline ionized water that can be consumed is produced in the first electrolytic bath, The present invention relates to an ionizer capable of simultaneously supplying disinfected water and alkaline water that can greatly enhance the usability and efficiency of the product because the strong acidic hypochlorous acid water having a strong sterilizing power can be generated to provide the user with the desired ionized water at the same time.

Generally, an ionizer is called an ionized water generator or a reduced water, and an ionizer has a water purifier and an electrolytic cell, and acidic ionized water and alkaline ionized water are produced by electrolysis. The alkaline ionized water thus generated is mainly used for beverage, and the acidic ionized water is used for skin cosmetic or disinfecting water and washing water. However, in the process of producing most of the alkaline water for food, acidic water produced together is wastewater.

In addition, the acidic water produced in a general ionizer is low in sterilizing power, and the acidic water generated in a general alkaline ionizer is electrolyzed in a general water, Lt; / RTI >

On the other hand, the strong acidic ionized water is produced in the general alkaline ionized water, but when the diluted salt solution (0.2% or less) is supplied through the metering pump and subjected to the electrolysis process, strongly acidic hypochlorous acid water having strong sterilizing power is generated.

In order to produce strongly acidic hypochlorous acid having a strong sterilizing power, many developments have been made in order to generate strongly acidic or strongly alkaline ionized water by electrolyzing the purified water mixed in a separate solvent (such as NACL or HCL) Currently, an ionizer has been developed in which alkaline water and strong acidic water are produced in the same electrolytic cell. However, there is no validation result that harmful to the human body is caused when the user generates an odor and drinks with alkaline water after strong acidic water is produced.

The following technologies are known in the prior art related to the above technology.

Patent Registration No. 10-0999956 (registered on Dec. 03, 2010) relates to a device for producing precipitated strong acidic water using anion exchange membranes, which is developed to easily produce and use strong acidic water having strong sterilizing power, It has a structure different from that of the strong direct water type strong water (strong acid water, strong alkaline water) using diaphragm and has a cylindrical shape and can be attached and detached. An anion exchange resin is used to ensure miniaturization of the device and enhance the efficiency of strong acid generation do.

However, in the above-mentioned registered patent, strong alkaline water is generated when a strongly acidic water (strong acidic water, strong alkaline water) generating device is generally generated in one electrolytic bath and inevitably generates strong acidic water. In order to reduce the waste of water resources, the anion exchange membrane is used to minimize waste of the strong alkaline water.

That is, the user can not simultaneously generate strong seawater and weakly alkaline ionized water, so that consumers have to separately provide alkaline ionized water that can be consumed with the strong seawater generating device, respectively, and the user has a problem in that the cost is doubly added.

Patent Document 1: Japanese Patent Application Laid-Open No. 10-2004-0030760 (Apr. 9, 2004) discloses an apparatus for generating ionized water using electrolysis. The apparatus includes a temperature compensation circuit unit for controlling current according to the temperature of water, And the DC voltage is controlled by controlling the average current and the frequency by changing the pulse width according to the PWM method so that the reduction potential (ORP) can be lowered.

The present invention configured for this purpose comprises a power supply unit for supplying power to generate ionized water through electrolysis, a rectifying unit for converting the supplied AC voltage into a DC voltage, A rectifier for converting the supplied AC voltage into a DC voltage, an output for outputting a current so as to generate ionized water through electrolysis through the current controller, A central processing unit for electrolyzing the water passing through both ends of the electrolytic cell for decomposition and separating the electrolytic water into alkaline ionized water and acidic water to control the current to flow out; A flow sensing unit for sensing the current supplied through the central processing unit and an electrolytic cell A display unit for displaying an amount of the electrolytic cell and an overheating state of the electrolytic cell, a sound output unit for when a danger occurs in the state of the electrolytic bath generated through the display unit and for a current state of operation of the electrolytic cell, A temperature compensation circuit for controlling the average current according to the temperature of the supplied water, and a frequency modulator for controlling the frequency modulation through the current controller by changing the pulse width according to the PWM method to a predetermined DC voltage.

The patent discloses that the electrolytic solution is electrolyzed in an electrolytic cell to generate an alkaline ionized water and an acidic ionized water desired by the user. However, since the range of alkalinity and acidity desired by the user is narrow, ionized water having strong alkaline or strong acidity can not be produced. There is a problem in that ionized water or weakly acidic ionized water which can be consumed can not be produced when generating strong alkaline or strongly acidic ionized water.

Regarding Utility Model Registration No. 20-0403493 (registered on Dec. 05, 2005), the present invention relates to an ion water generator having a separate water outlet, and more particularly, to an ion water generator having a water outlet and an ion outlet . According to the present invention, the ionizer is provided with a diverting solenoid valve for introducing the purified water from the water filter into the electrolytic bath or leaving the purified water to the water outlet, and the water can be branched, Is advantageous in that it can conveniently take out the neutralized water that has been purified, or that the alkaline ionized water can be taken through the distinctive outlet.

However, since only the water outlet and the alkaline ionized water outlet are provided, acidic ionized water can not be dispensed separately, and the waste water discharged from the drain to the outside is wasted.

In addition, it is difficult to produce ionized water or weakly acidic ionized water that can be consumed when producing strong alkaline or strongly acidic ionized water by using an electrolyte because the range of alkalinity and acidity desired by the user is narrow and it can not produce strong alkaline or strongly acidic ionized water. .

In addition, Patent Registration No. 10-0944209 (registered on Feb. 18, 2010) is related to "an electrolytic water purifier having controlled water flow rate so that stable production and useful use of electrolytic ionized water" The present invention relates to an electrolytic water purifier capable of obtaining three kinds of functional electrolytic ionized water (drinking water, washing water, washing water). In particular, it is possible to stably produce a pH range of each functional electrolytic ionized water by controlling the water- So that it can be used. Conventionally, there has been an electrolytic water purifier which electrolyzed water twice to generate three functional electrolytic ionized water. However, the pH of the three functional electrolytic ionized water (washing water, washing water, drinking water) The drinking water can not be stably obtained, and three functional electrolytic ionized water are simultaneously discharged. Therefore, there is a problem that water is wasted to users who do not use functional water (washing water, washing water) other than drinking water. Therefore, in the present invention, the three out of the three functional electrolytic ionized water are controlled so that the three functional electrolytic ionized water is always produced at a stable watertight rate with high usability, To provide a water purifier.

However, the above-mentioned patent has a problem in that washing water or washing water discharged inevitably occurs even if the watering rate is adjusted, and drinking water is inevitably produced even if only cleansing water or washing water is desired to be used. This production method is carried out in one electrolytic cell, and strong alkalinity which can not be consumed is produced by using cleaning water or washing water having strong disinfecting power using an electrolyte, so that ionized water capable of drinking simultaneously and strong acidic water having high sterilizing power can not be generated have.

In order to solve the above-mentioned problems, the present invention provides a method of electrolyzing water, comprising electrolyzing a first electrolytic cell and an electrolytic cell for electrolyzing water to generate alkaline ionized water, wherein the solvent supplied from the solvent part is mixed, A sterilizing water of a concentration of sterilizing power is provided, and it is an aqueous solution mainly composed of a chlorine compound of hypochlorous acid ion having alkaline ionized water and strong sterilizing power which can be used for drinking, sterilization of bacteria, fungus, virus and the like. Disinfection ??? It can be used for deodorization purposes, and can be produced in a variety of ways and easily, so that it is possible to provide an ionizer capable of simultaneously supplying sterilized water and alkaline water, which are both convenient and efficient to the user.

Also, since the first and second electrolytic baths have a structure capable of adjusting the number of electrodes of each electrolytic bath according to the amount of producing the desired pH concentration constant, the user can adjust the amount of the alkaline ionized water and the strong acidic ionized water discharged according to the purpose It is an object of the present invention to provide an ionizer capable of simultaneously supplying sterilized water and alkaline water that maximizes the efficiency of use.

In addition, the first electrolytic cell further includes cleaning means for removing scales generated by forming a scale of positive ions on the negative electrode plate, thereby solving the problem that solidification is formed on the negative electrode in the electrolytic cell to prevent electrolysis, There is a need to provide an ion exchanger capable of simultaneously supplying sterilized water and alkaline water that can constantly maintain sterilizing water at a required pH concentration and constantly maintaining the properties of ionized water that can be consumed.

The first or second electrolytic bath further includes a discharge unit including a first water outlet for discharging the alkaline ionized water generated in the first electrolyzer and a second water outlet for discharging the sterilized water generated in the second electrolyzer, There is no possibility that the sterilized water and the alkaline ionized water are mixed with each other, and the first water outlet and the second water outlet have a structure capable of simultaneously discharging ionic water of different pH concentration to simultaneously discharge sterilized water and alkaline water Which is capable of supplying water simultaneously.

According to an aspect of the present invention, there is provided an ionizer for simultaneously supplying sterilizing water and alkaline water,

A solvent portion for supplying a solvent;

A first electrolytic cell for electrolyzing the purified water to generate alkaline ionized water; And

And a second electrolyzer for electrolyzing the purified water, wherein the solvent supplied from the solvent unit is mixed to generate sterilized water having a pH different from that of the alkaline ionized water of the first electrolyzer.

Also, according to the present invention, an ionizer capable of simultaneously supplying sterilized water and alkaline water

The first and second electrolytic baths have a structure capable of adjusting the number of electrodes of each electrolytic bath according to an amount of producing an integer of a desired pH concentration,

The first electrolytic bath is further provided with a cleaning device for removing the generated scale.

In addition, the ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention

Wherein the first or second electrolytic bath comprises a first water outlet for taking out the alkaline ionized water generated in the first electrolytic bath,

And discharging means including a second water outlet for discharging the sterilized water generated in the second electrolytic bath.

According to the present invention, there is provided an ionizer for simultaneous supply of sterilized water and alkaline water, comprising: a strong acidic hypochlorous acid water producing unit that generates strong acidic hypochlorous acid water and produces alkaline ionized water by electrolyzing water to produce alkaline ionized water, A second electrolyzer for electrolyzing the electrolytic cell and the purified water, wherein the solvent supplied from the solvent unit is mixed to generate sterilized water having a pH different from that of the alkaline ionized water of the first electrolytic cell, Which is capable of sterilizing and disinfecting germs that may cause food poisoning, and alkaline ionized water that can be consumed for the prevention and promotion of the user's health, are separately prepared at the same time, And it is possible to improve convenience of use and productivity.

In addition, the first and second electrolytic baths are configured to adjust the number of electrodes of each electrolytic cell according to an amount of producing a desired pH concentration, thereby producing more alkaline ionized water that can be consumed by the user, It is possible to produce more chloric acid water, thereby maximizing the use efficiency of the product.

In addition, the first electrolytic cell further includes cleaning means for removing scales generated by forming a scale of positive ions on the negative electrode plate, thereby solving the problem that solidification is formed on the negative electrode in the electrolytic cell to prevent electrolysis, The sterilizing number of the pH concentration which is always required and the property of the ionized water which can be consumed can be kept constant, thereby improving the reliability and safety to the user.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front perspective view of an ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention; FIG.
2 is a perspective view and an enlarged view of an electrolytic cell of an ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention.
Fig. 3 (A) is a schematic flow chart of a first electrolyzer in an ionizer capable of simultaneously supplying sterilizing water and alkaline water according to the present invention;
FIG. 3B is a schematic flow chart of the second electrolyzer in the ionizer in which sterilizing water and alkaline water can be supplied simultaneously according to the present invention. FIG.
FIG. 4 is a right-side perspective view of an ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention. FIG.
5 is a left side perspective view of an ionizer according to the present invention capable of simultaneously supplying sterilized water and alkaline water.
6 (A) is a photograph of a combination of a washing means and an electrolytic bath in an ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention.
6 (B) is a view showing the connection between the washing means and the electrolytic bath in the ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention.
FIG. 7 is an analysis table of an aqueous solution containing a chlorine compound such as hypochlorous acid ions as a main component in strongly acidic water according to the present invention.
8 is a cross-sectional view of the circulation device according to the present invention
9 is a front view of a tank assembly provided in the storage means according to the present invention.
Figure 10 is a side view and back view of a tank assembly in accordance with the present invention;
11 is a view of another embodiment of a tank assembly according to the present invention
12 is a view of a tank assembly showing a second tank with a handle according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the numerals of the tens and the digits of the digits, the digits of the tens, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

In describing the ionizer S capable of simultaneously supplying the sterilized water and the alkaline water according to the present invention, when it is specified for the sake of convenience that the approximate direction reference is not strict, referring to FIGS. 1 and 2,

The direction is specified in accordance with this standard in the detailed description and claims of the invention relating to the other drawings.

1 to 8 and FIGS. 9 to 12 illustrate different components, and even if they are overlapped with each other, they indicate different objects.

As can be seen in Figures 1 and 2,

The ionizer S capable of simultaneously supplying sterilizing water and alkaline water according to the present invention comprises a flow supply unit 50, a solvent unit 10, a first electrolytic bath 20 and a second electrolytic bath 30, a discharge unit 40, , And a control unit (60).

1 and 2, the flow supply unit 50 includes a filter unit 52 having a water supply valve 51, a first primary filter 52a and a second secondary filter 52b, The user supplies the raw water to the first filter 52a and the second filter 52b of the filter unit 52 by controlling the amount of the raw water flowing into the filter unit 52 using the water supply valve 51.

Referring to the flow diagram of FIG. 3 in accordance with the flow of the flow in one example of the present invention,

The flow rate supply unit 50 further includes a flow rate sensor 53 capable of measuring a flow rate of the first electrolytic bath 20 and the second electrolytic bath 30 to be supplied to the first electrolytic bath 20 and the second electrolytic bath 30, The flow rate of the introduced electrolytic water can be adjusted so that the solvent can be mixed with the second electrolytic bath 30 in an appropriate ratio.

The solvent unit 10 includes an electrolyte tank 11, a metering pump 12, a check valve 13 and a three-way valve 14 so as to select a solvent stored in the electrolyte tank 11, (12). In this case, it is preferable that the solvent contains a different NACL or HCL solvent depending on the strongly acidic or strong alkaline water to be generated by the user.

A metering pump 12 may be provided between the first filter 52a and the second filter 52b so as to receive the solvent discharged from the solvent unit 10 and to discharge an appropriate amount of the solvent. .

The check valve 13 is provided in one direction to prevent the backflow of the solvent discharged from the metering pump 12 and is provided between the first and second filters 52a and 52b to be filtered Way valve (14) by connecting the purified water and the solvent to the pipeline through which the purified water flows.

The three-way valve 14 can separate the mixing water mixed with the solvent through the check valve 13 according to the type of the solvent and supply the mixed water to the second electrolyzer 30. [

In general, an electrolytic cell is divided into two polar chambers by a diaphragm through which only ions having an electrical property can pass. When a positive voltage or a negative voltage is applied to each of the polar chambers, water is electrolyzed and alkaline ionized water and acidic ionized water Is generated.

In the present invention, the first electrolytic bath 20 and the second electrolytic bath 30 are each provided with the same fastening structure. The first electrolytic bath 20 and the second electrolytic bath 30 are assembled into a one-two- 3: 3, 3: 7, 3: 3, 5: 5, and the number of the electrodes of the first electrolytic cell 20 and the second electrolytic cell 30 is 5: 3, 3: 5, 7:

In addition, the second electrolytic bath 30 may generate strong acid, weak acid, and neutral sterilizing water according to the presence or absence of diaphragm.

The acidic water generated in the first electrolytic bath 20 is purified by electrolyzing the general tap water, and is formed into ionic water produced in the anode room, and the pH is about 4.0 to 6.5. The acidic water produced in the second electrolytic bath 30 Strong acidic hypochlorous acid water with strong sterilization power is produced by electrolysis by supplying diluted salt solution (0.2% or less).

As shown in Fig. 7, an aqueous solution containing chlorine compounds such as hypochlorous acid ions of strong acidic water as a main component is used for sterilizing bacteria, fungi, viruses and the like. Disinfection ??? It can be used for deodorizing purposes. The sterilization effect of the hypochlorous acid water generated in the second electrolytic bath 30 can sterilize microorganisms that can cause food poisoning such as Salmonella, Escherichia coli, and enteritis Vibrio on raw materials such as meat and fish products, You can give.

Further, the strong acid hypochlorous acid generated in the second electrolyzer 30 is generated by adding electrolytic salt to general tap water. Since the chemical is not included at all, safety of users is remarkably improved. The nutrient destruction is small, and it is possible to provide a safe and powerful disinfecting power for the sterilization of vegetables, meat, and the like.

Meanwhile, as shown in FIG. 6, it is preferable that the first electrolytic bath 20 has a structure in which positive ions can form a scale on a negative electrode plate and a separate cleaning means 21 is introduced thereinto.

In order to prevent scale formation of the first electrolytic bath 20, the cleaning means 21 switches the polarity of the voltage applied to the pole chamber. In order to prevent the formation of scales in the first electrolytic bath 20, It is possible to synchronously operate the automatic flow path switching device and the feed flow rate regulating device which is the cleaning means (21).

(Not shown) of the first electrolytic cell 20, which alternately switches between the anode chamber and the cathode chamber according to the polarity switching of the applied voltage of the first electrolytic bath, and the second polar room (not shown) And a constant flow of ionized water can always be output from the outlet by using a pair of flow path switching valves (not shown).

1 and 5, the discharging means 40 includes a first water outlet 41 for discharging alkaline ionized water generated in the first electrolyzer 20 and a second water outlet 41 for discharging alkaline ionized water generated in the second electrolyzer 30. [ And a second water outlet (42) for discharging sterilized water, and a drain valve (43) for discharging the strong alkaline water discharged from the second electrolyzer (30).

As shown in FIG. 1, the first water outlet 41 and the second water outlet 42 are formed separately from each other, and the alkaline ionized water discharged from the first water outlet 41 and the second water outlet 42, Acid or strong alkaline ionized water discharged from the ion exchanger, so that the user can receive the desired ionized water while maintaining a safe and constant pH concentration.

It is preferable that the first water outlet 41 is formed as a pipe that can be bent so that the user can drink easily.

As shown in FIG. 5, the second water outlet 42 dedicated for strong acidic water is always exposed, so that the second water outlet 42 can be lifted only during use differently from the first water outlet 41 So that safety can be ensured such that strong acidic water flowing at the second water outlet 42 can not be consumed at any time.

4, the control unit 60 includes an operation unit 62 and a display unit 61. The user can control the operation of the first electrolytic bath 20 through the operation unit 62, So that the desired ionized water can be selectively supplied to the user by selecting the number of alkaline ionized water generated by the second electrolytic bath 30 or by selecting the alkaline ionized water generated by the second electrolytic bath 30, The display unit 61 is provided to further enhance convenience for the user.

In order to prevent the strong acidic water from being consumed, the control unit 60 displays a message of 'strong acidic water is a strong acidic water generating function. Do not drink strong acidic water' It enhances safety not to confuse ionized water with strong acidic water.

Preferably, the display comprises a display icon, an LED lamp or a flashing component.

In addition, the controller 60 generates a melody sound or a warning sound indicating that a strong acidic water is being dispensed, generates a warning message with the same voice guidance display as the above, So that safety and convenience can be ensured.

On the other hand, as shown in FIG. 8

The present invention preferably further comprises a storage means (70) for storing the alkaline ionized water produced in the first electrolytic bath. The storage means 70 mainly comprises a storage unit 71, a cold water unit 72, and a hot water unit 73.

In addition, the storage means 70 has a first water outlet portion capable of drinking the ionized water at room temperature as it is, and further includes a cold water portion 72 and a hot water portion 73 so that the user can drink ionized water of a desired temperature So that the efficiency and usability of the ionizer S can be further enhanced.

In the present invention, the storage unit 71 stores the alkaline ionized water generated at the first electrolytic cell at room temperature and includes the separating plate 71a, the water supply pipe 71b, and the relay pipe 71c so as to be able to be coupled to and separated from the ionizer S) can be easily cleaned during use, and a clean ionizer (S) can be provided. It is preferable that a gap is formed between the separation plate 71a and the water supply pipe 71b so that water can be introduced into the cooling unit from the storage unit 71. [

The cold water portion 72 is provided with a cold water pipe 72a, a cold water discharge hole 72b, a cooling member 72c, a refrigerant pipe 72d and a refrigerant pipe 72e, The cooled ionized water can be cooled to provide cold ionized water. It is preferable that the ionized water discharged to the cold water pipe 72a is discharged to the user through the cold water discharge hole 72b.

The hot water unit 73 includes a water inlet pipe 73a, a heater 73b, a hot water pipe 73c, an air vent 73d, a vacuum inlet pipe 73e, a hot water discharge hole, And can provide the user with warm ionized water.

The water inlet pipe 73a of the hot water unit 73 can introduce the ionized water flowing into the hot water unit 73 from the relay pipe 71c of the storage unit 71. [ The water intake pipe 73a shown in FIG. 8 may be coupled to the hot water portion 73 in any of left, right, and top directions as an example.

In addition, the heater 73b can heat the ionized water introduced through the water inlet pipe 73a from the lower end of the hot water unit 73. [ It is preferable that the heater 73b is disposed at the lower end of the hot water portion 73 in accordance with the general characteristic that the heated hot water does not flow to the lower portion but flows upward.

Further, it is preferable that the hot water pipe (73c) is provided with a moving path for discharging the heated ionized water to the hot water discharging hole, and is wrapped around a heat insulating material (not shown) so that heated ionized water does not cool.

It is preferable that the water warming unit 73 is constructed so as to maximize the heat insulating effect in itself by placing a vacuum 73g in order to keep the heated ionized water and the temperature of the hot water unit 73 itself from being lowered by the external environment Do.

The hot water unit 73 of the present invention further includes a coupling unit 80 to keep the inside of the hot water unit 73 clean. So that the convenience of the user to use the ionizer (S) can be improved, and clean ionized water can be continuously supplied, thereby providing an environment in which more safe ionized water can be consumed.

The coupling means 80 includes a cap 81, a first O-ring 82 and a second O-ring 83 so as to couple and separate the cap 81, It is preferable that the first O-ring 82 and the second O-ring 83 are fitted so that water can not leak or escape.

The first O-ring is provided to prevent the ionized water from flowing out from the inside of the hot water portion 73, and the cap 81 is brought into contact with the first support of the first O- .

The second O-ring is provided to act as a second blocking member for blocking the ionized water flowing out of the hot water unit 73, and the cap 81 abuts against the second support of the second O-ring 83 .

In addition, the first O-ring 82 and the second O-ring 83 and the first and second support rods can protect the durability of the O-ring from dropping due to the hot water and the ionized water leaking into the first and second passages It is possible to secure the durability of the ionizer S and the efficiency of the ionizer S so that there is no leakage of ionized water.

8, the present invention further includes a circulation unit 90 inside the hot water unit 73 so that the ionized water flowing in from the water intake pipe 73a flows into the hot water pipe 73c And the temperature inside the hot water portion 73 being heated can be kept constant at all times, so that the ionized water having an appropriate temperature can be supplied.

Meanwhile, as shown in FIG. 8, it is preferable to provide a plurality of circulation devices 90. It is also preferable that one circulation device 90 is provided.

The rotation plate 93 of the circulation device 90 may have a different height than that of the rotation plate 93 so that the rotation plate 93 is not in contact with the rotation plate 93, The height of the fixing table 91 is preferably lower than the height of the fixing table 91.

Also, the rotation of the rotating plate 93 can maintain the average temperature as a whole by circulating the ionized water, which is the normal temperature supplied from the lower end, and the heated ionized water. It is possible to circulate the heated ionized water without the supply of external electric power by the reflux of the ionized water by the temperature difference, thereby supplying the hot-watered alkaline ionized water having a constant temperature.

The circulation device 90 includes a fixing table 91, a fixing ring 92 and a rotating plate 93 so that a fixing ring 92 is formed at the upper end of the fixing table 91, Or the like.

Further, the circulation device 90 is desirably provided to be staggered with the heater 73b. Further, the circulation device 90 is strong enough to prevent chemical reaction with the heated ionized water, and is made of the same material as the inner wall of the hot water part 73 .

Also, it is preferable that the rotary plate of the circulator (90) is shaped like a furnace wetted in the ship or formed like a general plate plate.

Further, the ionizer for simultaneous supply of sterilized water and alkaline water according to the present invention includes a storage tank assembly connected to the storage means 70 for use in a large-scale building or where water supply is poor, .

The storage tank assembly described below is made up of a first tank 10 and a first tank set T1 composed of a second tank 20 located above the first tank. Such a tank set can additionally be expanded according to the required capacity, and the second and third tank sets T2 and T3 can be connected through the connection portion. The first tank 10 is provided with a support foot (not shown) at a lower portion thereof and has a second tank mounting portion, in particular an opening type mounting portion 10h, And the overflow 13 for discharging in the negative overcharge state can be confirmed in Figs. 11 [B] and [C], and the lower first connection portion 15 used for the extension of the additional tank set Is omitted or closed when not required).

The second tank 20 is provided with a stopper 20s (which has a slanting face on the outer side) to be received in the opening-type mounting portion 10h of the first tank 10 so as to be caught by the reinforcing flange 10f, So that the second tank can be stably coupled to the upper portion of the first tank,

A cover 20c is provided on the upper portion,

And also has a second connection portion 25 for connection of the overflow 23 and the additional extension tank set,

And a second mounting portion 27 for the cabinet 50 on the front surface.

Furthermore, the second tank 20 has a water level confirmation part 20L made of a transparent hose for confirming the water level,

In the state where the first and second tanks are mounted on the upper portion of the first tank 10, the rear surface is fixed to the two fixing plates Tj so as to be prevented from being separated. .

12A showing a storage tank assembly A according to the present invention, a rear view of FIG. 12B, and a side perspective view of FIG. 12C. The handle 20g provided on the front surface and the back surface can be further introduced. Such a handle may have various shapes.

It is preferable that first and second water level sensing means are provided in the first and second tanks 10 and 20 to sense the full water level and to block the inflow of negative water.

10 (A)) 31B (see FIG. 10 (A)) constituting the first and second filling parts 30A and 30B for ensuring the unit price competitive power and the water filling opening / (11) (21) of the ball-top valves (V1) and (V2) (see FIG. 10A)

The first and second filling parts 30A and 30B supplying negative water to the first and second tanks 10 and 20 constituting the first tank set T1 as described above are provided with valves, V1) V2 to smoothly fill the storage means 70 with negative water and to supply the water through the first and second water level sensing means 11, 21, 31A, and 31B.

Particularly, the first filling part 30A is arranged to communicate with the lower part of the second tank 20, that is, the first supply pipe 31A is connected to the bottom surface of the second tank 20, Since the ballast valve V1 is mounted on the supply pipe 31A,

9 and 10, the negative water flowing into the second supply pipe 31B of the second filling part 30B is again supplied to the supply hole 31h and the ball-top valve V2 via the auxiliary supply pipe 31b, And is supplied to the second tank 20,

The negative number immediately fills the first tank 10 first via the first supply pipe 31A of the first supply part 30A,

Negative water is filled in the second tank 20 due to the first water level sensing means, that is, the first valve (V1) is blocked by the first port (11) at the first tank (10)

If additional second and third tank sets T2 (T3) are added to the first tank set T1 as in Fig. 11,

The negative number is the same as that of the second tank 20 of the first tank set T1 → the first tank 10 → the third tank T2a of the second tank set T2 → the fifth tank of the third tank set T3 (T3a) to fill the fifth tank (T3a), the third tank (T2a) and the first tank (10)

By the interruption of the first valve (V1)

The negative water flows into the sixth tank T3b of the third tank set T3 from the second tank 20 of the first tank set T1 to the fourth tank T2b of the second tank set T2, 6 tank (T3b), the fourth tank (T2b), and the second tank (20), so that all tank sets are filled.

The lower third tank T2a and the upper fourth tank T2b of the second tank set T2 and the lower fifth tank T3b of the third tank set T3, as shown in Figs. 11A and 11B, Unlike the first and second tanks 10 and 20 of the first tank set T1, the tank T3a and the upper sixth tank T3b do not communicate with each other but only through the connecting pipes J1a and J1b , J2b), which are supplied with negative water from the preceding tank (negative water is supplied first) of each tank set located on the right side.

Next, in case of discharging the negative water, the water is first discharged from the first discharge portion 40A provided in the first tank 10 and then introduced into the storage means 70. As shown in FIG. 9A, And is forcibly discharged by the pump P connected to the outer tubular portion 43 of the discharge portion.

In the case where only the first tank set T1 is provided, when the negative water starts to be discharged from the first discharge portion 40A, the valve becomes lower than the first water level, (V1) is opened,

Negative water stored in the upper second tank 20 is supplied to the second tank 20 and the water is supplied through the second filling portion 30B of the second tank 20 directly connected to the water supply facility by opening the second valve V2 Can be additionally filled.

In this negative discharge method, water is discharged only from the discharge portion 40A of the first tank 10 even when three sets of tanks T1, T2 and T3 as shown in Fig. 11 are provided, and the other tanks 20, T2b, T3a, T3b are the same as those for supplementing the negative water stored in the first tank 10,

This makes it possible to dispense with the introduction of unnecessary piping and eventually to achieve a satisfactory negative filling and discharging.

10A, the second discharge portion 40B functions as the first supply pipe 31A of the first filling portion 30A,

The discharge portions of the respective tanks T2a, T2b, T3a and T3b of the other tank sets T2 and T3 function as connecting pipes J1a and J1b (J2a and J2b) serving also as a filling portion.

The inner tube 41 connected to the outer tube 43 of the first discharge portion 40A has a first tube body 41a arranged adjacent to the inner bottom surface of the first tank 10 and a second tube body 41b connected to the first tube body, And a second tube body 41b arranged at a position spaced apart from the bottom surface of the tank and penetrating the side wall of the first tank so as to completely discharge all the negative water as much as possible. And is configured to be convenient to connect the outer tube 43 to the connection hole 41h (see FIG. 11 [B]).

The first tubular body 41a shown in an oblique line may be connected to the second tubular body 41b at various angles as required.

9, each of the tank sets, particularly the first tank set T1, in which corrosion prevention, especially inner surface corrosion prevention (material selection such as use of SUS material, or the like can be implemented through painting) The cabinet 50 for mounting the control panel (P) and the control panel (M / B, main board) is mounted on the first and second mounting portions 17 and 27 B]).

As can be seen from Figs. 9A and 11, the cabinet 50 has first to third shelves 51, 53 and 55 from the bottom to the top,

The first shelf 51 is provided with a UPS (uninterruptible power supply, an apparatus for allowing the control panel and the pump to continue to operate even when the main power is lost for a short time)

The second shelf 53 is provided with a pump P and is connected to the outer tubular portion 43 of the first discharge portion 40A,

The third shelf 55 is provided with a box for the control panel M / B.

The negative water supplied through the second filling portion 30B is connected to the supply hole 31h and the ballpoint valve V2 via the auxiliary supply pipe 31b having a relatively small inner diameter,

The outer pipe 43 of the first discharge portion 40A is connected to the pipe 43a via the pump P,

In the case of the simple sprinkler facility, the water left after the water spraying in the event of fire is again introduced into the collection hole 35 through the auxiliary supply pipe 31b and the bypass portion 35 and stored in the second tank.

As can be seen from Fig. 11 [B], a drain 10d is provided at the lower right end of the first tank 10. [

While the present invention has been described in connection with what is presently considered to be the preferred embodiments, it is evident that many alternatives, modifications, and substitutions are possible, And should be construed as falling within the scope of protection of the present invention.

S: Ionizer capable of supplying sterilized water and alkaline water simultaneously
10: Solvent part 11: Electrolyte tank
12: metering pump 13: check valve
14: three way valve 20: first electrolyzer
21: cleaning means 30: second electrolyzer
40: discharge means 41: first outlet portion
42: second water outlet 43: drain valve
50: Flow supply part 51: Water supply valve
52: Filter part 52a: Primary filter
52b: Secondary filter 53: Flow sensor
60: control unit 61: display unit
62: operation unit 70: storage means
71: storage unit 71a: separator plate
71b: water supply pipe 71c: relay pipe
72: cold water part 72a: cold water pipe
72b: cold water discharge hole 72c: cooling member
72d: refrigerant supply pipe 72e: refrigerant pipe
73: hot water part 73a:
73b: heater 73c: hot water pipe
73d: Air vent 73e: Vacuum input tube
73g: jeans study
80: coupling means 81: cap
82: second o-ring 83: first o-ring
90: Circulation device 91: Fixture
92: Fixing ring 93: Spindle

Claims (4)

A solvent portion for supplying a solvent;
A first electrolytic cell for electrolyzing the purified water to generate alkaline ionized water; And
And a second electrolytic cell for electrolyzing the purified water, wherein the solvent supplied from the solvent part is mixed to generate sterilized water having a pH concentration different from that of the alkaline ionized water of the first electrolytic cell. . The method according to claim 1,
Wherein the first and second electrolytic baths are capable of simultaneously supplying sterilized water and ionized water having a structure capable of adjusting the number of electrodes of each electrolytic cell according to an amount of producing a desired pH concentration constant. 3. The method according to claim 1 or 2,
Wherein the first electrolytic bath further comprises cleaning means for removing scales generated by the first electrolytic bath. The method according to claim 1,
Wherein the first or second electrolytic bath comprises a first water outlet for taking out the alkaline ionized water generated in the first electrolytic bath,
And a second water outlet for discharging sterile water generated in the second electrolytic cell. The ionizer according to claim 1, further comprising:

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