KR20110019285A - Water ionizer - Google Patents

Abstract

PURPOSE: A water ionizer generating ionized water without wasting purified water is provided to generate alkali ionized water by electrolyzing domestic water discharged from a reverse osmosis membrane filter. CONSTITUTION: A water ionizer generating ionized water without wasting purified water comprises the following: a filter unit(200) including a reverse osmosis membrane filter(260) comprising a domestic water pipe(262); an electrolyzing tank(300) including an ion exchanging film installed in between a positive electrode and a negative electrode; and a purified water pipe(420) for flowing filtered water.

Description

Water ionizer {WATER IONIZER}

The present invention relates to an ionizer.

Preferred water is colorless, as no heavy metals and toxic substances such as various bacteria and the appropriate amount of the mineral-containing water into an odorless state, is known to be ideal to include a weak alkaline of Ca ^{2 +,} Na ⁺ It water present. This is because alkaline ionized water has a small water particle, so it is quickly absorbed into the body, and acts as an antioxidant to remove active oxygen.

To this end, ionized water groups including electrolyzers that electrolyze raw water such as tap water to generate and separate alkaline ionized water containing inorganic cations and acidic ionized water as non-drinking water are widely used.

In general, ionizers generate alkaline ionized water and acidic ionized water by electrolyzing raw water by applying a DC voltage to the electrodes of the positive electrode and the negative electrode.

1 is a block diagram of a generally used ionizer. As shown in FIG. 1, the ionizer 10 is an electrolytic cell that generates alkaline ionized water and acidic ionized water by electrolyzing the filter 20 for purifying the raw water to be supplied and the water purified by the filter 20. 30), the control unit 40 for controlling the operation of the ionizer, an alkaline ionized water discharge pipe 50 for discharging the alkaline ionized water generated in the electrolytic cell 30, and an acidic ionized water discharge pipe for discharging the acidic ionized water generated in the electrolytic cell 30 ( 60), the user is able to extract and drink the alkaline ionized water through the alkaline ionized water discharge pipe (50).

However, according to the ionizer configured as described above, since alkaline ionized water and acidic ionized water are produced by electrolyzing purified water, only alkaline ionized water is consumed and acidic ionized water is separated and discharged. The problem is that the lifetime of the filter is shortened because a positive integer must be made.

In particular, when water is purified using a reverse osmosis membrane filter, the hydrogen ion index (pH) of purified water is low, so it is required to raise it. Since acidic ionized water is generated and discarded in the process of producing the A, there is a problem that the waste of water is very large.

The present invention was devised to solve the problems of the prior art, and an object of the present invention is to provide an ionized water group that generates alkaline ionized water without waste water purified by electrolysis using living water discharged from a reverse osmosis membrane filter.

According to a first aspect of the present invention for achieving the above object, an electrolytic cell having a filter unit including a reverse osmosis membrane filter provided with domestic water pipes, and a negative electrode, a positive electrode, and an ion exchange membrane provided between the negative electrode and the positive electrode The positive electrode side is connected to the purified water pipe is connected to the purified water is filtered in the filter unit, the positive electrode side is connected to the living water pipe is connected to the living water discharged from the reverse osmosis membrane filter, the ion exchange An ion water group is provided characterized by ion exchange between purified water and living water through a membrane.

According to a second aspect of the invention, the ion exchange membrane is an anion exchange membrane.

According to a third aspect of the present invention, the filter unit further includes a purified water tank for storing the filtered water, wherein the purified water pipe is connected to both the inlet and the outlet of the purified water tank, and the water of the purified water tank is Is supplied circulating.

According to a fourth aspect of the present invention, a pump is installed in the purified water pipe.

According to a fifth aspect of the present invention, the apparatus further includes a control unit for controlling the operation of the electrolytic cell, wherein the control unit controls the electrolytic cell to operate only while the raw water is filtered through the filter unit.

According to a sixth aspect of the present invention, the controller controls the electrolyzer to operate at regular time intervals.

According to a seventh aspect of the present invention, a control unit for controlling the operation of the electrolytic cell and a water level sensor for detecting the water level of the purified water tank, wherein the control unit operates the electrolytic cell when the purified water tank is above a predetermined low water level. To control.

According to an eighth aspect of the present invention, a pump is installed in the living water pipe.

According to the present invention, the purified water is not generated by flowing the living water discharged from the reverse osmosis membrane filter to the positive electrode side and the purified water of the purified water tank to the negative electrode side so that all purified water of the purified water tank becomes alkaline ionized water.

In addition, since the water stored in the purified water tank generates alkaline ionized water while circulating, it is possible to simply adjust the hydrogen ion index (pH) of the alkaline ionized water by controlling the driving time.

In addition, since the continuous water flow is generated by circulating the water in the purified water tank, the generation of scale is also prevented.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram of the ionizer 100 according to the embodiment of the present invention.

As shown in FIG. 2, the ionizer 100 includes a filter unit 200, an electrolytic cell 300, and a purified water tank 400.

The filter unit 200 includes a precipitation filter 220, a pre carbon filter 240, a reverse osmosis membrane filter 260, and a post carbon filter 280. The sedimentation filter 220 filters out more than 5 micrometers of debris and contaminants contained in the raw water so that the components of subsequent processes work normally. The pre carbon filter 240 removes harmful components by adsorption of activated carbon in water provided from the precipitation filter 220. The reverse osmosis membrane filter 260 removes most of the ionic substance including heavy metals, microorganisms, and the like from the water provided from the free carbon filter 240. The living water pipe 262 is connected to the reverse osmosis membrane filter 260 to discharge the living water generated in the reverse osmosis membrane filter 260. The living water pipe 262 may be provided with a pump 264 to smoothly discharge the living water. The post carbon filter 280 receives water from the reverse osmosis membrane filter 260 and adsorbs and removes gaseous substances dissolved in the water to supply water to the purified water tank 400.

The purified water tank 400 stores the water filtered and supplied by the filter unit 200. The purified water tank 400 is provided with a purified water pipe 420 in which both the inlet and the outlet are connected to the purified water tank 400. In the purified water pipe 420, a pump 422 for circulating the water of the purified water tank 400 is disposed. In addition, the purified water extraction pipe 440 is installed on one side of the purified water tank 400, the user can extract the water through the purified water extraction pipe 440 to drink. The purified water extraction pipe 440 may be provided with a purified water extraction valve 442 to control the opening or closing of the purified water extraction pipe 440.

The electrolytic cell 300 is connected to the purified water pipe 420 and the living water pipe 262 to supply the water of the purified water tank 400 and the living water discharged from the reverse osmosis membrane filter 260.

3 is an enlarged view of the inside of the electrolytic cell 300 according to the embodiment of the present invention. As shown in FIG. 3, the electrolytic cell 300 includes a negative electrode 320 and a positive electrode 340 so as to electrolyze the water supplied thereto, and an ion exchange membrane between the negative electrode 320 and the positive electrode 340. 360) is installed.

The purified water pipe 420 is connected to the negative electrode 320 side and purified water flows in the purified water tank 400, and the living water pipe 262 is connected to the positive electrode 340 side to discharge the water from the reverse osmosis membrane filter 160. As the water flows, ion exchange is performed between the purified water and the living water through the ion exchange membrane 360.

It is preferable to use an anion exchange membrane as the ion exchange membrane 360. The anion exchange membrane is formed by forming an ion exchange resin into a membrane shape. When the current is passed through the solution by using a diaphragm, the anion is allowed to pass, but the cation passes through the cation.

That is, the anion of the negative electrode 320 side may move to the positive electrode 340 side, but the cation of the positive electrode 340 side may not move to the negative electrode 320 side. Accordingly, alkaline ions such as calcium ions, magnesium ions, potassium ions, and sodium ions are collected on the negative electrode 320 to form alkaline ionized water, and acidic ions such as chloride ions and sulfur ions are collected on the positive electrode 340 to become acidic ionized water.

Water from the purified water tank 400 introduced into the electrolytic cell 300 through the purified water pipe 420 becomes alkaline ionized water from the electrolytic cell 300 and then flows back into the purified water tank 400, so that if it lasts for a predetermined time, the purified water The water in the tank 400 becomes alkaline ionized water. Meanwhile, the living water introduced into the electrolytic furnace 300 through the living water pipe 262 becomes acidic ionized water in the electrolytic cell 300 and then is discharged to the outside.

Since the living water only occurs while being filtered through the reverse osmosis membrane filter 260, the electrolysis in the electrolytic cell 300 should also be made only while being a purified water. However, the electrolysis does not always need to be performed in the purified water, and the electrolysis may be performed at a predetermined time interval in the purified water according to the target hydrogen ion index (pH) of the alkaline ionized water. To this end, a control unit (not shown) for controlling the operation of the electrolytic cell 300 is provided, and the control unit applies electricity to the electrolytic cell 300 only while filtering is performed through the filter unit 200 to operate the electrolytic cell 300. And control the electrolyzer 300 to operate at regular time intervals.

On the other hand, when the purified water tank 400 is empty, since the purified water is not circulated to the negative electrode 320 side, electrolysis cannot be performed. Therefore, a water level sensor (not shown) is installed in the water purification tank 400, and the signal of the water level sensor is transmitted to the controller so that the electrolytic cell 300 is operated only when the water purification tank 400 is above a predetermined low level.

As such, in the related art, water is wasted because electrolyzed purified water generates alkaline ionized water and acidic ionized water, and then acidic ionized water is separated and discharged. However, according to the present invention, the living water discharged from the reverse osmosis membrane filter is positive electrode side The purified water in the purified water tank flows to the negative electrode side so that all purified water in the purified water tank becomes alkaline ionized water.

In addition, since the alkaline ionized water is generated while the water stored in the purified water tank circulates, it is possible to simply adjust the hydrogen ion index (pH) of the alkaline ionized water by controlling the driving time.

In addition, since the continuous water flow is generated by circulating the water in the purified water tank, there is an effect of preventing the generation of scale.

1 is a block diagram of a conventional ionizer 10.

2 is a block diagram of the ionizer 100 according to the embodiment of the present invention.

3 is an enlarged view of the inside of the electrolytic cell 300 according to the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

200 Filter section 260 Reverse osmosis membrane filter

262 living water pipe 300 electrolyzer

320 negative electrode 340 positive electrode

360 ion exchange membrane 400 water purification tank

420 Water Purification Tubing 422 Pump

Claims (8)

A filter unit 200 including a reverse osmosis membrane filter 260 provided with living water pipes 262, An electrolytic cell 300 having a negative electrode 320, a positive electrode 340, and an ion exchange membrane 360 provided between the negative electrode 320 and the positive electrode 340, The purified water pipe 420 is connected to the negative electrode 320 side, and the purified water flowing from the filter unit 200 flows, and the living water pipe 262 is connected to the positive electrode 340 side, so that the reverse osmosis membrane filter ( Water flows from the living water discharged from 260, ion exchanger between the purified water and the living water through the ion exchange membrane (360). The method according to claim 1, The ion exchange membrane 360 is an ion exchanger, characterized in that the anion exchange membrane. The method according to claim 1, Further comprising a purified water tank 400 for storing the water filtered by the filter unit 200, The purified water pipe (420) is an ionizer, characterized in that both the inlet and outlet port is connected to the purified water tank 400, the water of the purified water tank 400 is circulated supply to the electrolytic cell (300). The method of claim 3, Ionizer, characterized in that the pump 422 is installed in the water purification pipe (420). The method according to claim 1, Further comprising a control unit for controlling the operation of the electrolytic cell 300, The control unit is characterized in that the ionizer to control the operation of the electrolyzer 300 only while the raw water is filtered through the filter unit (200). The method according to claim 5, The control unit ionizer, characterized in that for controlling the electrolytic cell to operate at a predetermined time interval. The method of claim 3, A control unit for controlling the operation of the electrolytic cell 300, Further comprising a water level sensor for detecting the water level of the purified water tank 400, The control unit ionizer, characterized in that for controlling the operation of the electrolytic cell 300 when the purified water tank 400 is above a predetermined low water level. The method according to claim 1, Ionizer, characterized in that the pump 264 is installed in the living water pipe (262).

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