KR100639837B1 - Method of electrolysis water and making apparatus of electrolysis water - Google Patents

Abstract

According to the present invention, a method of producing ionized water includes a cleaning step of cleaning the electrode chamber by changing polarities applied to electrodes respectively provided in at least two electrode chambers separated by an ion separation membrane, and using the washed ion water to And draining the water to be discharged to one of the first and second outlet pipes by combining water to be discharged to the first and second outlet pipes connected to the electrode chamber.

The ionized water production apparatus of the present invention includes an electrolytic cell having at least two electrode chambers separated by a diaphragm, electrodes provided in the electrode chambers, and a voltage applying unit for selectively applying polarities selectively inverted to the electrodes for cleaning. And an alkaline water and acid water outlet pipe connected to each of the electrode chambers, and installed between the alkaline water and acid water outlet pipes, and discharge of one of the alkaline water and acid water outlet pipes when the voltage is applied to the electrode inverted for cleaning. It includes a connecting means for induction discharge into the pipe. In addition, the connection means is installed between the alkaline water and the acidic water outlet pipe connecting the branch and the alkaline water outlet pipe and the branch pipe is installed between the branch and the water discharged through the alkaline water outlet pipe through the branch pipe It may further include a valve for inducing to flow toward the acidic water outlet pipe.

Cleaning, valve, discharge

Description

Ionized water production method and ionized water production apparatus {Method of electrolysis water and making apparatus of electrolysis water}

1 is a schematic cross-sectional view showing an embodiment of the ionized water production apparatus according to the present invention,

2 and 3 are cross-sectional views showing another embodiment of the ionized water production apparatus according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10; Raw water flow control valve 20; Electrolyzer

40; Valve 50; Alkasu Canister

55; Neutral water outlet 60; Acid water outlet

80; A voltage applying unit 300; Controller

The present invention relates to a device for producing ionized water, and more particularly, to an ionized water production method and an ionized water production apparatus capable of inducing and discharging the washed water washed after the electrolytic cell to one discharge pipe.

In general, the electrolytic cell has an ion separation membrane and an electrode chamber separated by the membrane to generate alkaline water and acidic water, and is configured such that electrodes are provided in each electrode chamber. The water flowing into the electrode chamber is electrolyzed while generating a constant voltage on the electrode to generate alkaline water and acidic water.

In the case of long-term use in this manner, a salt-like complex is formed on the surface of the electrode and the ion separation membrane inside the electrolytic cell, and in the case of the electrode, the current density of the surface is reduced, causing a decrease in the performance of the electrolytic cell.

In addition, long-term drinking of salt-type complexes is a causative agent of carcinogenesis in the human body.

In order to solve such a cause, the current commercialized water ionizer is cleaned by applying a semi-electrode voltage to the electrode to clean and discharge the washed water.

In this case, the water inside the cleaned electrolytic cell is moved to the acidic water discharge pipe or the alkaline water discharge pipe and discharged.

In the case of the commercialized ionizer, cleaning is indicated by using display means so that the washing step can be checked externally during the washing operation. In another method, the user is confirmed that the cleaning operation is performed by voice or melody so that the user cannot drink water. However, most of the ionizers do not drink the clean water in the initial operation state relatively to discard the water, there is a problem that the drinking is used when the cleaning is performed during the operation of the ionizer.

The reason for cleaning during ionizer operation is that automatic cleaning can be set so that a certain amount of water can be electrolyzed in order to maintain the performance of the electrolytic cell for a longer time, thereby preventing the electrolytic cell from deteriorating.

There is a continuous water flow type electrolytic ion water generating device disclosed in the Republic of Korea Patent Publication No. 10-0244053 and its reverse cleaning method.

Here, the cleaning of the electrolytic cell is performed without reversing the washing water washed with the acidic water and alkaline water outlet pipe after applying reverse rotation, and configured to have a discharge part for draining the water into the electrolytic cell, and the washed water is discharged through the drain valve. .

The present invention is to solve the problems as described above, to provide the ionized water production method and ionized water production apparatus to be discharged by mixing the washing water after the cleaning of the electrolytic cell to the acid water discharge portion of the washing water rather than being discharged to the alkaline water discharge portion of the drinking water. There is a purpose.

Another object of the present invention is to provide a device for producing ionized water that is harmless to the human body so that the complexed compound in the salt form contained in the washing water after washing is not carcinogenic.

The ionized water production method of the present invention for achieving the above object, the cleaning step of cleaning the electrode chamber by changing the polarity applied to the electrodes respectively installed in at least two electrode chambers separated by an ion separation membrane, And draining the water to be discharged to one of the first and second outlet pipes by combining water to discharge the cleaned ionized water to the first and second outlet pipes connected to the respective electrode chambers.

The ionized water production apparatus of the present invention for achieving the above object is an electrolytic cell having at least two electrode chambers separated by a diaphragm, the electrodes respectively installed in the electrode chamber, and selectively inverted in the electrodes for cleaning A voltage applying unit for applying the polarized polarity, an alkaline water and an acid water outlet tube connected to each of the electrode chambers, the alkaline water and an acid water outlet tube, and an alkaline water when the voltage is inverted to the electrode for cleaning; It includes a connection means for induction discharge to one of the acid water outlet pipe. In addition, the connection means is installed between the alkaline water and the acidic water outlet pipe connecting the branch and the alkaline water outlet pipe and the branch pipe is installed between the branch and the water discharged through the alkaline water outlet pipe through the branch pipe It further includes a valve for inducing to flow toward the acidic water outlet pipe.

Alternatively another feature of the ionized water production apparatus according to the present invention,

Raw water is supplied from the raw water supply tank, and an electrolyzer having at least two electrode chambers separated by a diaphragm, electrodes provided in the electrode chambers, and selectively inverted polarity are applied to the electrodes for cleaning. A voltage applying unit, an alkaline water and acidic water outlet pipe connected to each of the electrode chambers, a respective drain container for receiving water discharged from the alkaline water and an acidic water outlet pipe, and the alkaline water and acidic water outlet pipes. And connecting means for inducing and draining the water of the alkaline water outlet tube to the acidic water outlet tube when the voltage of the inverted polarity is applied to each electrode for the cleaning. In addition, the connection means is installed between the alkaline water and the acidic water outlet pipe connecting the branch and the alkaline water outlet pipe and the branch pipe is installed between the branch and the water discharged through the alkaline water outlet pipe through the branch pipe It further comprises a valve for flowing to the acid water outlet pipe.

In another alternative, another feature of the ionized water production apparatus according to the present invention,

An electrolytic cell having first, second and third electrode chambers separated by a diaphragm, first, second and third electrodes respectively provided in the first, second and third electrode chambers, and first, second and third electrodes for cleaning. A voltage applying unit for selectively applying a polarity to the first electrode; an alkaline water and acid water outlet tube connected to the first and third electrode chambers; and an alkaline water and acid water outlet tube for cleaning. And connecting means for inducing and discharging water to at least one of the alkaline water and the acidic water discharge pipes when the voltage of the inverted polarity is applied to the 2,3 electrodes.

Preferably, a neutral water outlet pipe is further provided in the second electrode chamber, and the connecting means includes a branch pipe connecting the alkaline water outlet pipe, the neutral water outlet pipe, and the acidic water outlet pipe, respectively, and the alkaline water outlet pipe and the branch pipe. And between the neutral water outlet pipe and the branch pipe further includes a valve for inducing water to flow toward the acidic water outlet pipe through the branch pipe to the alkaline water outlet pipe and the neutral water outlet pipe.

The apparatus for producing ionized water according to the present invention is to prepare electrolytic water such as acidic water, neutral water, and alkaline water, and an embodiment thereof is shown in FIG. 1.

Referring to the drawings, the electrolyzer 20 of the ionized water production apparatus 100 has at least two electrode chambers 21 and 23 separated by an ion separation membrane 25, and the electrode chambers 21 and 23. Electrodes 31 and 33 respectively installed at the s), a voltage applying unit 80 to selectively apply polarities selectively inverted to the electrodes 31 and 33 for cleaning, and the electrode chambers 21, respectively. It is installed between the alkaline water and the acidic water outlet pipes 41 and 43 connected to the 23 and the alkaline water and the acidic water outlet pipes 41 and 43 and is inverted in the electrodes 31 and 33 for the cleaning. It includes a connection means 400 for inducing discharge to one of the discharge water of the alkaline water and acidic water discharge pipe (41, 43) when the applied voltage of the polarity. In addition, the connecting means 400 is installed between the alkaline water and acidic water outlet pipe (41, 43) and the branch pipe 45 for connecting them, and between the alkaline water outlet pipe 41 and the branch pipe 45 It is further provided with a valve 40 which guides the water discharged through the alkaline water outlet pipe 41 to flow toward the acidic water outlet pipe 43 through the branch pipe 45.

The ionized water production apparatus 100 configured as described above will be described in detail for each component as follows.

The electrolytic cell 20 has two electrode chambers 21 and 23 partitioned in-line by the ion separation membrane 25, and any of them can be used as long as they are resistant to the generated electrolytic water. For example, organic materials such as polyvinyl chloride, polypropylene, acrylic resin, inorganic materials such as ceramics, glass, and the like may be made of a metal material having an insulating coating. The electrolyzer is not limited to the above-described embodiment and may be any structure having electrode chambers and supporting the electrode and the diaphragm. For example, it may be manufactured using a plurality of divided molding plates as in the embodiment described below.

The ion separation membrane 25 partitioning the internal space of the electrolytic cell 20 may include a filter made of a polymer material such as cellulose, polyethylene, polypropylene, polyester, polystyrene, fluorine resin, and an inorganic material such as ceramic, or the like. Porous films, ion exchange membranes and the like can be used.

Each of the electrodes 31 and 33 provided inside the electrode chambers 21 and 23 is plated or coated on a plate member made of a metal, an alloy, a metal oxide, or the like, and conductive such as sintered carbon. A material may be used, and as the shape, a plate shape, a punching plate, a mesh, or the like may be used. Particularly, the material of the electrode 31 to which the anode is applied is preferably excellent in acid resistance and difficult to oxidize. Pt, Pd, Ir, β-PbO ₂ , NiFe ₂ O ₄ , and the like can be most suitably used. As the quality of the electrode 33 to which the cathode is applied, one having excellent alkali resistance is preferable. For example, Pt, Pd, Preference is given to using Au, carbon steel, stainless, Ag, Cu, graphite, glassy carbon and the like.

The voltage applying unit 80 is for applying a DC voltage to the electrodes 31 and 33, respectively, applying a DC voltage to the anode 31 and a DC cathode voltage to the electrode 33. And power supplies for Here, the poles applied to the first and second electrodes 31 and 33 may be changed as necessary. In addition, the voltage applying unit may be controlled by the control means to adjust the pH value of the discharged electrolytic water, thereby adjusting the DC voltage applied to each electrode.

On the other hand, the cleaning of the electrolytic cell 20 is to alternate the polarity periodically (2 to 10 seconds intervals) in order to prevent the sludge or the like attached to the surface of the electrode (31) 33, apply a voltage of three inverted polarity The lower surface of the electrode 31 is applied with a DC voltage of the negative electrode to generate acidic water in the electrode chamber 21, and the positive electrode DC voltage is applied to the electrode 33 to generate alkaline water in the electrode chamber 23.

The acidic water, which is the cleaned water of the alkaline water outlet pipe 41, of the outlet pipes 41 and 43 for discharging the generated alkaline water and the acidic water, can induce the flow of water on the alkaline water outlet pipe 41. Attached to the valve 40 includes a connecting means 400 for guided discharge to the acidic water outlet pipe 43 to install the branch pipe 45 to be joined to the acidic water outlet pipe 43.

The valve may be composed of one or more valves selected from a two-way valve and a three-way valve, and may further include a well-known valve capable of changing the flow direction of water.

The control means 300 controls the control valve 10 for controlling the amount of raw water supplied to the electrolytic cell 20, and the voltage applying unit of the electrodes 31, 33 of the electrolytic cell 20. Although not shown in the drawing, a microcomputer method of controlling and programming an applied voltage according to a preset pH value is taken.

On the other hand, the connecting means 400 preferably further includes a valve 40 for applying the semi-electrodeness to the electrodes 31 and 33 in the cleaning mode as described above and inducing the flow of water to the alkaline water discharge pipe 41. .

Reference numeral 50 is an alkaline water outlet, and 60 is an acidic water outlet.

Although not shown in the drawings, in another embodiment of the ionized water production apparatus according to the present invention, raw water is supplied from a raw water supply container, each having an electrolytic cell having at least two electrode chambers separated by a diaphragm, and each of the electrode chambers. Electrodes installed, a voltage applying unit for selectively applying polarity reversed to the electrodes for cleaning, alkaline water and acidic water outlet pipes connected to the respective electrode chambers, discharged from the alkaline water and acidic water outlet pipes It is installed between each of the drain and the alkaline water and the acidic water outlet pipe for receiving the water to the water of the alkaline water outlet pipe when the voltage of the inverted polarity is applied to each electrode for the cleaning to the acidic water outlet pipe It includes a connecting means for induction discharge. In addition, the connection means is installed between the alkaline water and the acidic water outlet pipe connecting the branch and the alkaline water outlet pipe and the branch pipe is installed between the branch and the water discharged through the alkaline water outlet pipe through the branch pipe It further comprises a valve for flowing to the acid water outlet pipe.

In the ionized water production apparatus of the above embodiment, the same components as those of the embodiment of FIG. 1 are replaced with the detailed description of the embodiment of FIG.

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Equipped with a raw water supply tank can supply the water flowing into the electrolytic cell through the raw water control valve, and by installing 1.5 to 4 liters of the low water of the raw water supply tank can be installed without being connected to the water supply location You can be free from constraints.

In addition, by providing an alkaline water outlet and an acidic water outlet in each of the alkaline water outlet and the acidic water outlet, it can be configured to be installed in the vicinity of the drainage.

2 and 3 show another embodiment of the ionized water production apparatus according to the present invention.

Referring to FIGS. 2 and 3 in common, the ionized water production apparatus 100 includes an electrolytic cell 20 having first, second and third electrode chambers 21, 22, 23 separated by a diaphragm, and First, second and third electrodes 31, 32 and 33 respectively provided in the 1,2,3 electrode chambers 21, 22 and 23, and the first, second and third electrodes 31 for cleaning. A voltage applying unit (80) for selectively applying polarities reversed to the (32) and (33), an alkaline water discharge pipe (41) connected to the first and third electrode chambers (21) (23), and the first The first, second and third electrodes 31 are installed between the acidic water outlet pipe 43 connected to the two electrode chamber 22 and each of the alkaline water and the acidic water outlet pipes 41 and 43 for cleaning. (32) and (33) includes a connection means 400 for inducing and discharging water to at least one of the discharge pipe of the alkaline water and the acidic water discharge pipe (41, 43) when the voltage is reversed.

Preferably, a neutral water outlet pipe 42 is further provided in the second electrode chamber 22, and the connection means 400 includes the alkali water outlet pipe 41, the neutral water outlet pipe 42, and the acidic water outlet pipe. First and second branch pipes 45 and 49 connecting the 43 and the alkaline water outlet pipe 41 and the first branch pipe 45, and the neutral water outlet pipe 42 and the second minute pipe, respectively. The water discharged from the alkaline water outlet pipe 41 and the neutral water outlet pipe 42 between the engines 49 flows toward the acidic water outlet pipe 43 through the first and second branch pipes 45 and 49. It further comprises a first, second valve 40, 48 to guide the water.

2, the connecting means 400 includes a valve 40 on the alkaline water outlet pipe 41 and a branch pipe 45 extending from the valve 40 and connected to the acidic water outlet pipe 43. Can be done.

The alkaline water outlet pipe 41 sums and discharges the ionized water generated from the electrode chambers 21 and 23, and the acidic water outlet tube 43 discharges the ionized water generated from the electrode chamber 22.

That is, the alkali water generated from the electrode chambers 21 and 23 of the electrolytic cell 20 is moved to the alkali water discharge pipe 41 and discharged, and stored in the alkali water reservoir 50.

On the other hand, the acidic water generated from the electrode chamber 22 of the electrolytic cell 20 is moved to the acidic water discharge pipe 43 is discharged to the acidic water discharge container 60 and stored.

 In the cleaning mode, the acidic water generated from the electrode chambers 21 and 23 of the electrolytic cell 20 is moved to the alkaline water discharge pipe 41 and discharged into the acidic water discharge container 60 by the valve 40. do.

Meanwhile, the alkaline water generated from the electrode chamber 22 of the electrolytic cell 20 is moved to the acidic water discharge pipe 43 and discharged into the acidic water discharge container 60 and then stored.

Referring to FIG. 3, the connecting means 400 extends from the first valve 40 and the valve 40 on the alkaline water outlet pipe 41 and is connected to the acidic water outlet pipe 43. And a second branch pipe 49 extending from the second valve 48 on the neutral water outlet pipe 42 and connected to the acidic water outlet pipe 43.

The alkaline water outlet pipe 41 discharges the ionized water generated from the electrode chamber 21, and the neutral water outlet pipe 42 discharges the ionized water generated from the electrode chamber 22, and the acidic water outlet tube. 43 discharges the ionized water generated from the electrode chamber 22.

That is, the alkali water generated from the electrode chamber 21 of the electrolytic cell 20 is moved to the alkali water discharge pipe 41 and discharged, and stored in the alkali water reservoir 50.

Neutral water generated from the electrode chamber 22 of the electrolytic cell 20 is moved from the alkaline water discharge pipe 42 to be discharged into the neutral water discharge container 55 and then stored.

The acidic water generated from the electrode chamber 22 of the electrolytic cell 20 is moved to the acidic water discharge pipe 43 and discharged into the acidic water discharge container 60 and then stored.

In the cleaning mode, the acidic water generated from the electrode chamber 21 of the electrolytic cell 20 is moved to the alkaline water discharge pipe 41 and discharged to the acidic water discharge container 60 by the first valve 40 and then stored. .

Meanwhile, the alkaline water generated from the electrode chamber 22 of the electrolytic cell 20 is moved to the acidic water discharge pipe 43 and discharged into the acidic water discharge container 60 and then stored.

In addition, the neutral water generated from the electrode chamber 21 of the electrolytic cell 20 is moved to the neutral water discharge pipe 42 and is discharged to the acidic water discharge container 60 by the second valve 48 and then stored.

Unlike the present embodiment, the neutral water generated from the electrode chamber 21 of the electrolytic cell 20 is not discharged to the neutral water discharge pipe 42, and the inlet of the second electrode chamber 22 is circulated therein. It may be made of a connected closed circuit (not shown).

In this case, an electrolyte replenishment unit (not shown) may be included in the internal circulation tube of a closed circuit (not shown). For example, sodium chloride (NaCl) may be added to the internal recirculating water as an electrolyte component in the electrolyte replenishment unit. .

By the addition of the electrolyte component, the pH of the alkaline and acidic water in the electrolytic cell can be prepared with strong alkaline water and strong acidic water.

As described above, the ionized water production apparatus according to the present invention can set the cleaning cycle of the electrolytic cell frequently so that the electrolyzer can be used for a longer time, and separates the discharge pipe so as not to drink the washed water according to the frequent cleaning cycles. It is advantageous to provide a method for producing ionized water and an apparatus for producing ionized water, which is harmless to the human body so as not to ingest a salt-type complex compound as a trigger.

Claims (7)

delete delete delete delete delete An electrolytic cell having first, second and third electrode chambers separated by a diaphragm, First, second and third electrodes respectively installed in the first, second and third electrode chambers; A voltage applying unit for selectively applying polarity to the first, second and third electrodes for cleaning; Alkaline water and acidic water outlet pipes connected to the first and third electrode chambers; Installed between the alkaline water and the acidic water outlet pipe to induce water discharge to at least one outlet of the alkaline water and the acidic water outlet pipe when the voltage applied to the polarity reversed to the first, second, and third electrodes for the cleaning Ionized water production apparatus comprising a connecting means. The method of claim 6, Neutral water outlet pipe is further provided in the second electrode chamber, The connecting means includes a branch pipe connecting the alkaline water outlet pipe, the neutral water outlet pipe and the acidic water outlet pipe, respectively, between the alkaline water outlet pipe and the branch pipe, and the alkaline water outlet pipe and the branch pipe. Ionized water production apparatus further comprises a valve for inducing water to flow toward the acidic water outlet pipe through the branch pipe to the water discharged to the neutral water outlet pipe.

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