KR101215811B1 - Electrolyzed-water system having Non_diaphragm electrolysis apparatus - Google Patents

Abstract

Electrolytic water system including a membrane-free electrolytic cell according to the present invention is a membrane-free electrolytic cell, a water-repellent bulb comprising a hollow housing having an inlet and a plurality of outlets, and a plurality of electrode plates spaced a predetermined distance within the housing; And a first flow path switching unit disposed on an inlet pipe path connecting the inlet port, and a second flow path switching unit connected to the outlet port.
Electrolytic water system according to the present invention by using a plurality of flow path switching valves to supply the electrolytic water, such as alkaline water and acidic water generated in the membrane-free electrolytic cell alone or supplied by dilution.

Description

Electrolyzed water system including non-diaphragm electrolyzer {Electrolyzed-water system having Non_diaphragm electrolysis apparatus}

The present invention relates to an electrolyzed water system including a non-diaphragm electrolyzer, and more particularly, to extract and combine alkaline and acidic water, which are electrolyzed water discharged from the non-diaphragm electrolyzer, through a plurality of flow path switching valves communicating with the non-diaphragm electrolyzer. An electrolyzed water system including a diaphragm electrolyzer that facilitates this is provided.

A conventional electrolysis method using a diaphragm generally reduces the electrolysis efficiency of the electrode and causes a problem that occurs in the form of a precipitate when the electrode plate is reversed. Accordingly, the electrode which produced alkaline water for a certain condition is an acidic water producing electrode, and the electrode which produced acidic water for a certain condition is replaced with an alkaline water producing electrode to solve the scale problem generated in the electrode. On the other hand, in order to fundamentally solve the problem in the diaphragm-type electrolytic cell, the development of a non-diaphragm type electrolytic cell has been made recently.

The non-diaphragm type electrolytic water device does not have a diaphragm that separates the acidic electrolyzed water generated on the positive side and the alkaline electrolytic water generated on the negative side, so that each electrolyzed water generated on the positive and negative electrodes is separated. Is generated as electrolyzed water mixed with each other. In order to induce the separation of the mixed electrolyzed water, a separate intermediate insulating film may be interposed between the positive electrode and the negative electrode to enable separation of the acidic and alkaline electrolytic water.

In the existing electrolytic water system including the non-diaphragm electrolyzer, it is possible to supply the electrolyzed water discharged from the electrolyzer by variously supplying the electrolyzed water discharged from the electrolyzer by only separating and supplying the generated and separated electrolyzed water into acidic and alkaline water, respectively. In addition, there is a lack of a valve system for properly mixing and distributing the discharged electrolytic water is difficult to supply a suitable concentration of electrolyzed water to the user.

Accordingly, the present invention is a combination of the alkaline water and acidic water generated in the non-diaphragm electrolyzer in order to be treated with alkaline water coke, cooked water faucet, purified water coke, drain, etc., a plurality of flow path switching in communication with the non-diaphragm electrolyzer An electrolytic water system with a valve is provided.

Electrolytic water system including a membrane-free electrolytic cell according to the present invention provided to achieve the above object is a hollow housing having an inlet and a plurality of outlets, and a plurality of electrode plates arranged to be spaced a predetermined distance within the housing And a non-diaphragm electrolyzer including a first flow path switching unit disposed on an inlet pipe path connecting the water inlet and the inlet, and a second flow path switching unit connected to the outlet.

The first flow path switching unit may have a three-way structure connecting the power outlet, the water inlet, and the water purification cock.

The first flow path switching unit may include a two-way structure connecting the faucet and the inlet and a two-way structure connecting the faucet and the water purification cock.

The water outlet may include an alkaline water outlet and an acidic water outlet, and the second flow path conversion unit may have a 4-way structure connecting the alkaline water outlet, the acidic water outlet, alkaline water coke, and the cooked water faucet.

The second flow path conversion unit may include a three-way structure connecting the alkaline water outlet, the acidic water outlet, and the cooking water faucet, and a two-way structure connecting the alkaline water outlet and the alkaline water coke.

The non-diaphragm electrolyzer may further include a spacer interposed between the electrode plates.

Electrolytic water system according to the present invention by using a plurality of flow path switching valves to supply the electrolytic water, such as alkaline water and acidic water generated in the membrane-free electrolytic cell alone or supplied by dilution. Through this supply method, the consumer can be supplied with various concentrations of electrolyzed water from the membrane-free electrolyzer.

1 is a schematic view showing an electrolytic water system including a non-diaphragm electrolyzer according to an embodiment of the present invention;
2 is a perspective view in one direction of the membrane-free electrolyzer;
3 is an exploded perspective view of the membrane-free electrolyzer of FIG. 2, and
4 is a schematic view showing an electrolyzed water system including a non-diaphragm electrolyzer according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an electrolytic water system 100 including a diaphragm electrolyzer according to the present invention. The embodiments described below are provided by way of example for purposes of illustration, and do not limit the technical scope of the invention.

First of electrolytic water system Example (100)

Referring to FIG. 1, an electrolytic water system 100 according to a first embodiment of the present invention will be described. The electrolytic water system 100 includes a diaphragm electrolyzer 10, a first flow path switching valve 50 connected to the inlet 13, and a second flow path switching valve connected to the alkaline water outlet 15 and the acidic water outlet 14. (60).

The first flow path switching valve 50 may function as a three-way valve. The first flow path switching valve 50 flows through the water supply port 1, the water supply pressure reducing safety valve 2, the water filter 8, and the flow rate sensor 3, and then flows the water inlet 13 or water purification. Supply to the cock 4.

The second flow path switching valve 60 may function as a four-way valve. The second flow path switching valve 60 is connected to the alkaline water discharge port 15 through the alkaline water discharge channel 71, and is connected to the acidic water discharge channel 72 through the connection channel 74. Here, the acidic water discharge passage 72 connects the acidic water outlet 14 and the drain 7. The acidic water discharge passage 72 has a unidirectional direction in which a flow path is determined so that the acidic water discharged from the acidic water outlet 14 is supplied to the drain 7, and the flow from the drain 7 to the acidic water outlet 14 is prevented. It has a flow path structure.

The second flow path switching valve 60 is connected to the acidic water discharge flow path 72 through the connection flow path 74. The flow passage direction is determined such that the ionized water introduced into the second flow path switching valve 60 is supplied to the acidic water discharge flow path 72, and the connection flow path 74 is connected to the second flow path switching valve 60 from the acidic water discharge flow path 72. Flow to) has a unidirectional flow path structure that is prevented.

The second flow path switching valve 60 may receive the alkaline water through the alkaline water discharge passage 71 and supply the alkaline water to the alkaline water coke 5 and the cooking water faucet 6. On the other hand, when the polarity of the opposite direction to the non-diaphragm electrolyzer 10 is connected to the acidic water through the alkaline water discharge passage 71 may be supplied to the alkaline water coke (5) and the cooked water faucet (6).

Operation modes that can be driven using the flow path switching valves 50 and 60 of the electrolytic water system 100 may be classified into four types.

First, the purified water mode is the water flow through the water supply port (1), the water supply pressure reducing safety valve (2), the water filter (8), and the flow rate sensor (3) through the first flow path switching valve (50) To be discharged.

In the alkaline mode, the alkaline water through the alkaline water discharge passage 71 may be discharged from the second flow path switching valve 60 to the alkaline water coke 5 or the cooking water faucet 6.

The faucet mode is capable of supplying acidic water which is not suitable as drinking water. Unlike the alkaline mode, the acidic water generated when the polarity in the opposite direction is connected to the non-diaphragm electrolyzer 10 is cooked through the alkaline water discharge channel 71. It can be supplied to the facet (6).

The drain mode discharges the membrane-free electrolytic cell 10 to the drain 7 through the acidic water discharge passage 72 when the diaphragm electrolytic cell 10 is not washed or used as cooking water.

As described above, the present invention can be used in various ways to suit the application by appropriately distributing the alkali and acidic water generated in the membrane-free electrolytic cell 10 through a plurality of flow path switching valve.

A septum To electrolyzer (10)  Description of

Hereinafter, the non-diaphragm electrolyzer 10 according to the embodiment of the present invention will be described with reference to FIGS. 2 to 3. The non-diaphragm electrolyzer 10 is provided on the open side of the hollow housing 11, the electrode plate 20 disposed in the housing 11, the spacer 30 interposed between the electrode plate 20, and the housing 11. The cover 12 is mounted, and a sealing member 40 disposed between the housing 11 and the cover 12 to prevent leakage of electrolytic water from the housing 11.

The housing 11 has an inlet 13 and a plurality of outlets 14, 15. The water outlets 14 and 15 include an acidic water outlet 14 and an alkaline water outlet 15. The inlet 13 communicates with the first reservoir 16 formed inside one side of the housing 11, and the acidic water outlet 14 and the alkaline water outlet 15 are second inside the other side of the housing 11. It communicates with the reservoir 17 and the 3rd reservoir 18, respectively.

The electrode plate 20 includes a positive electrode plate 24 on which the positive electrode terminal 23 is formed and a negative electrode plate 21 on which the negative electrode terminal 22 is formed. The positive electrode plate 24 and the negative electrode plate 21 maintain a constant distance from each other to enable laminar flow of raw water flowing into the housing 11. The electrode plate 20 prevents rocking of the electrode plate 20 by fixing the terminals 22 and 23 to the terminal grooves formed in the housing 11, respectively.

The spacer 30 interposed between the electrode plates 20 maintains a predetermined distance between the positive electrode plate 24 and the negative electrode plate 21 and at the same time receives the electrolytic water flowing through the interior of the membrane-free electrolytic cell 10. 13) to smoothly flow from the outlet 14, 15 side.

On the positive electrode plate 24, an electrode slit 25 is formed to communicate with the acidic water outlet 14 formed in the housing 11. The electrode slit 25 allows the discharge of the flow water moving in close contact with the positive electrode plate 24 in the ionization process of the flow water flowing between the electrode plate 20. In the membraneless electrolysis process according to the present invention, acidic water is formed on the positive electrode plate 24 side, and alkaline water is formed on the negative electrode plate 21 side. Here, in the case of acidic water, the closer to the positive electrode plate 24 side, the higher the acidity is. Alkaline water also has the same tendency as acidic water.

2nd of electrolytic water system Example (100 ')

Hereinafter, an electrolytic water system 100 ′ according to a second embodiment of the present invention will be described with reference to FIG. 4. Here, the same configuration as that of the first embodiment 100 will be omitted, and only distinctive portions will be described.

The first flow path switching valve 50 ′ includes a first intermittent valve 52 and a second intermittent valve 54. The first intermittent valve 52 connects the power receiver 1 and the non-diaphragm electrolyzer 10, and the second intermittent valve 54 connects the power receiver 1 and the purified water cock 4.

The second flow path switching valve 60 'includes a third intermittent valve 62 and a fourth intermittent valve 64. The third intermittent valve 62 connects the alkaline water discharge port 15 and the alkaline water coke 5. The fourth control valve 64 is connected to the acidic water discharge channel 72 through the first connection channel 75, and to the alkaline water discharge channel 71 through the second connection channel 76, and to the second connection channel. Electrolyzed water introduced through the 76 is sent to the cooked water coke 6 or the acidic water discharge passage 72.

In the electrolyzed water system 100 ', the flow of the electrolyzed water generated in the membrane-free electrolyzer 10 is prevented by opening or blocking the flow of the electrolyzed water by the individual intermittent valves 52, 54, 62, and 64 having a simplified structure. Make it possible.

As described above, the electrolytic water system (100, 100 ') according to the present invention by using a plurality of flow path switching valves to separately supply or dilute electrolytic water, such as alkaline water and acidic water generated in the membrane-free electrolytic cell 10 Supply. Through this supply method, the consumer can receive electrolytic water of various concentrations from the membrane-free electrolyzer 10.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the present invention can be changed.

1: Water tap
2: water supply pressure reducing safety valve
3: flow sensor
4: water purification coke
5: alkali water coke
6: Cooked Faucet
7: drain
8: water filter
10: non-diaphragm electrolyzer
11: housing
12: cover
13: inlet
14: acidic water outlet
15: alkaline water outlet
16: first reservoir
17: second reservoir
18: third reservoir
20: electrode plate
21: negative electrode plate
22: negative terminal
23: positive terminal
24: positive electrode plate
25: electrode slit
30: spacer
40: sealing member
50,50 ': 1st flow path switching valve
52: first intermittent valve
54: second intermittent valve
60,60 ': 2nd flow path switching valve
62: third intermittent valve
64: fourth intermittent valve
71: alkaline water discharge passage
72: acidic water discharge passage
74,75,76: Euro connection
100,100 ': Electrolyzed Water System

Claims (6)

A diaphragm electrolyzer comprising a hollow housing having an inlet and a plurality of outlets, and a plurality of electrode plates spaced a predetermined distance from the housing;
A first flow path switching unit disposed on an inlet pipe path connecting the outlet and the inlet; And
A second flow path switching unit connected to the outlet;
/ RTI >
The outlet port includes an alkaline water outlet connected to the second flow path conversion unit and an alkaline water discharge passage, and an acidic water outlet connected to the second flow path conversion unit and an acidic water discharge passage, and the second flow path conversion unit includes the alkaline water outlet. Connecting the acidic water outlet, alkaline water coke, and cooking water faucet to adjust the flow rate,
The connecting flow path connecting the second flow path switching unit and the acidic water discharge flow path is a unidirectional flow path for preventing flow from the acidic water discharge flow path to the second flow path switching valve.
Diaphragm electrolyzer electrolytic water system.
The method of claim 1,
The first flow path switching unit is characterized in that the three-way structure for connecting the faucet, the water inlet and the water purification cock,
Diaphragm electrolyzer electrolytic water system.
The method of claim 2,
The first flow path switching unit includes a two-way structure connecting the faucet and the water inlet and a two-way structure connecting the faucet and the water purifying cock.
Diaphragm electrolyzer electrolytic water system.
delete The method of claim 1,
The second flow path switching unit includes a three-way structure connecting the alkaline water outlet, the acidic water outlet, and the cooking water faucet, and a two-way structure connecting the alkaline water outlet and the alkaline water coke,
Diaphragm electrolyzer electrolytic water system.
The method of claim 2,
The diaphragm electrolyzer is
A spacer interposed between the electrode plates;
Characterized in that it further comprises,
Diaphragm electrolyzer electrolytic water system.

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