KR20140016223A - Electrolytic cell of a water purifier using an electrolysis - Google Patents

Abstract

The present invention relates to an electrolytic tank of an electrolysis water purifier which is capable of obtaining acidic water, alkaline water, and weak alkaline water, to provide an improvement in electrolysis efficiency, manufacturing availability, economic feasibility, and the removal of malfunctions of the electrolytic tank, and to enable users to easily mount the electrolytic tank to the water purifier. The electrolytic tank collects acidic water generated from first electrolysis and acidic water generated from second electrolysis in one place for discharging, smoothens the flow of ions by forming electrode plates into a net form during the second electrolysis, and accurately blocks the ion-separated water by including an airtight maintaining element on the edge of a partition wall installed among the electrode plates. The electrolytic tank includes a unit for maintaining the air tightness of the electrolytic tank and a unit for mounting the electrolytic tank to the water purifier for preventing existing problems.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double electrolyzer for an electrolytic water purifier,

The present invention relates to an electrolytic cell applied to an electrolytic water purifier capable of obtaining acidic water, alkaline water and weak alkaline water, and more particularly, to an electrolytic cell which is capable of increasing electrolytic efficiency while eliminating defects in the electrolytic cell, To provide ease of use.

Currently, it is a known fact that the present applicant has already registered a number of patents in order to obtain alkaline water by separating water into acidic water and alkaline water by electrolysis to obtain alkaline water.

The most important part of such electrolysis is the electrolytic cell. The water is firstly separated into acidic water and alkaline water while passing through the electrolytic cell, and then water obtained from the electrolytic cell is discharged from the acidic water due to the strong alkaline solution, , Strong alkaline water and weakly alkaline water to obtain only the number of alkaline ions most useful for the body by the secondary electrolysis and discharge the remainder is already known by the present applicant.

However, in this case, the flow of water in the electrolytic cell must be provided separately for the discharge port for discharging the acidic water obtained by the first electrolysis and the discharge port for discharging the acidic water obtained in the second electrolysis, It is difficult to obtain a weak alkaline water. In the course of the secondary electrolysis, there is a problem that the ion movement is unavailable in the electrode plate, and there is no close interception between the electrode plates, The efficiency of the electrolysis is deteriorated.

In addition, there is a problem that the pH of the water separated by the flow of water in the electrolytic cell can not be adjusted.

Also, in the past, when the electrolytic cell was mounted on a water purifier, a separate component was used to mount the electrolytic cell.

Accordingly, in the present invention, the structure of the electrolytic cell is improved to control the pH of the water, as well as to smooth the flow of ions in the diaphragm and to completely block the diaphragm, .

For this purpose, the acidic water generated in the first electrolysis and the acid water generated in the second electrolysis are collected and discharged from one place, and the electrode plates are implemented in the second electrolysis process as a mesh to smooth the flow of ions As well as an airtightness element at the edge of such an electrode plate to enable precise isolation of the ion-separated water.

In addition, the electrolytic cell is provided with a means for mounting it on the water purifier and a means for maintaining the airtightness of the electrolytic cell, thereby solving the problems that have occurred in the past.

Therefore, it is possible to obtain a sufficient alkaline water obtained by electrolysis and an adequate amount of water obtained by electrolysis while adjusting the total pH of the water obtained by electrolysis, so that the efficiency of weak alkaline water obtained by electrolysis is improved, The easiness of the production, as well as the installation of the electrolytic cell in the water purifier, was the same.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
2 is a state in which the electrolytic bath of the present invention is assembled.
3 is a view showing a state in which electrodes of the electrode plate of the present invention are assembled.
4 is an internal structural view of the electrolytic bath main body of the present invention.
FIG. 5 is a detailed structural view of an electrode plate incorporated in an electrolytic bath body of the present invention. FIG.
6 is a layout view showing an electrode hole of the electrolytic bath body of the present invention.
7 is a state in which the electrode plate and diaphragm of the present invention are laminated.
8 is a state in which an electrode is mounted on the electrode plate of the present invention.
Fig. 9 is a view showing a state in which the electrode of the present invention is fixed
10 is a cross-sectional view illustrating electrode fixation of the present invention
11 is a structural view illustrating an electrode according to the present invention.
12 is a view showing the structure of an electrode plate and a diaphragm according to the present invention.
13 is an internal structural view of the electrolytic bath main body of the present invention.

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

1 and 2, the structure of the present invention is a structure in which the water received through the inlet 1 into the electrolytic bath body 100, which is covered with the lid 200 and sealed, As shown in FIG. 4, when the inlet volume is controlled by the control membrane 10 and then flows into the primary space 110 for primary electrolysis, as shown in FIG. 5, The electrolytic water is electrolyzed by the two planar electrode plates 20 and 21 provided therebetween and the diaphragm 30 interposed therebetween to be separated into the acidic water and the alkaline water so that the acidic water is separated from the acidic water discharge port 2, And the alkaline water is discharged through the alkaline water discharge port 3 and moved to one side of the secondary space part 130 for the secondary electrolysis through the moving flow path 4.

As shown in FIG. 1, the alkaline water passing through the alkaline water transfer channel 4 and moved to one side is regulated by the secondary water intake control film 40, 130).

At this time, a mesh electrode plate 24 is placed between the two planar electrode plates 22 and 23 in the secondary space portion 130, and between the planar electrode plates 22 and 23 and the mesh electrode plate 24 The diaphragms 31 and 32 are displayed, respectively.

In the present invention, the mesh electrode plate 24 serves as a channel through which electrons can move due to an electrical reaction between a positive electrode plate and a weakly-alkaline electrode plate. By increasing the total cross-sectional area serving as a channel, This is a lot to happen.

Therefore, it is possible to increase the production amount of weak alkaline water for drinking.

The structure of the diaphragms 30, 31, and 32 installed in the primary space unit 110 and the secondary space unit 130 may be such that the planar electrode plates 22 and 23 are in close contact with each other, And reinforcing pieces 33 for reinforcement inside the frames 31a and 32a are formed in a lattice so as to intersect with the vertical frame 33a and the horizontal frame 33b.

At this time, as shown in Fig. 7, the planar electrode plates 22 and 23 are provided at both ends of the frames 31a and 32a so as not to closely contact the frames 31a and 32a, The planar electrode plates 22 and 23 are formed with the gaps 31b and 32b with the molds 31a and 32a so that the flow of water flows through the gaps 31b and 32b to one side of the diaphragms 31 and 32 .

This is because the vertical frame 33a forming the reinforcement frame 33 forming the diaphragm has a height lower than that of the horizontal frame 33b so that the flat electrode plates 22 and 23 are in contact with only the horizontal frame 33b When the flow of the water moves left and right, the flow is slightly blocked by the vertical frame 33a, and flows again, so that the ion is separated and generated accurately and completely.

In order to prevent mixing of the ion-separated water when the diaphragms 30, 31 and 32 are mounted in the primary and secondary spaces 110 and 130 of the electrolytic bath body 100, 30, 31, 32) are closely contacted with the bottom surface of the electrolytic bath body forming the primary and secondary spaces 110, 130, the partition dividing the acidic water storage tank and weak alkaline water storage tank, The grooves 34 are formed at the edges of the diaphragm to be inserted into the grooves 5 and then the packing rings 35 are protruded to the grooves so that the packing rings The airtightness is maintained while the diaphragms 30, 31 and 32 are shut off from each other as the diaphragms 30, 31 and 32 are tightly adhered to each other while being inserted into the inner groove 5, 100, even when the internal pressure is generated.

Thus, accurate ion separation and efficiency due to the generation of a uniform amount of separated ions are increased.

In order to cover the electrode plates 20, 21, 22, 23, 24 and the diaphragms 30, 31, 32 sandwiched in the primary and secondary space portions 110, 130 of the electrolyzer, Even when the elastic pad 300 is placed inside the elastic pad 300 and then the lid 200 is covered to ensure the airtightness, the elastic pad 300 is not limited to the diaphragm having the packing ring, The irregular portion 310 formed by the recessed portion 311 and the protruded portion 312 is closely adhered to the partition wall separating the boring water control membrane and the space portion and the partition wall partitioning the acidic water storage tank and the weak alkaline water storage tank This allows for tight coupling.

In addition, the alkaline water flows into the secondary space part 130 through the alkaline water passage 4 while being separated into the acidic water and the alkaline water by the electrode plate and the diaphragm in the primary space part 110, The acid water outlet 2a is formed in a partition wall separating the secondary space portion 130 so as to separate only the alkaline water from the acidic water, the strong alkaline water and the weak alkaline water, And the strong alkaline water is separated from the weak alkaline water by being separated from the weak alkaline water by forming a separate drain hole 6 in a region directly under the mesh electrode plate 24 so that the alkaline water is separated from the mesh electrode plate 24 Is stored in the weak alkali storage part (140) through the weak alkaline discharge port (7) separated from the diaphragm (32) closely attached to the lower alkaline discharge port (8).

At this time, the partition 120a for partitioning the acidic water storage compartment 120 is formed over the primary space 110 where the primary electrolysis is generated and the secondary space 130 where the secondary electrolysis is generated, The respective acidic water outlets (2, 2a) are formed in the form of grooves only at the upper end of the partition wall (120a).

Therefore, the concentration of Ph in the electrolytic bath is maintained.

An acidic water outlet (7) is formed on the bottom surface of the acidic water reservoir (120) and is discharged to the outside.

In addition, the acidic water generated in the primary space 110 is not discharged immediately to the acidic water reservoir 120 but is formed in the form of a groove to be inserted into the outer wall constituting the electrolytic bath main body, And then discharged through a discharge groove formed only at an upper end of the partition 120a partitioning the acidic water storage tank 120 to maintain the pH of the water and to be subjected to a primary electrolysis process in the primary space unit 110 So that the acidic water is discharged into the acidic water reservoir 120. [0050] As shown in FIG.

The alkaline water separated in the first space 110 passes through the alkaline water transfer passage 4 and passes through the second water intake control film 40 so that the inflow amount and the inflow position are uniformly introduced into the entire electrode plate The weak alkaline water, which is secondarily charged in the secondary space 130 when the secondary alkaline water flows into the secondary space 130 and is electrolyzed in the secondary, is discharged through a weak alkaline water outlet (not shown) so as to secure a large amount of discharged water for drinking. 7 are formed as long cut-away grooves on the partition wall 140a for partitioning the weak alkali storage part 140. [

At this time, when weakly alkaline water is discharged to the weak alkaline water discharge port 7, the alkaline water storage port 140 is discharged to the front of the weak alkaline water discharge port 7 in order to smooth the discharge flow while guiding the entire passage to the diaphragm 32 By forming the creping film 141 so as to cover the incision groove forming the channel as a whole, the weak alkaline water is prevented from being immediately discharged through the weak alkaline discharge port 7, so that the electrode plates 22, 23 , 24 and the diaphragms (31, 32).

In addition, the diaphragm 30 is positioned between the two electrode plates 20, 21 mounted on the primary space portion 110 for the primary electrolysis, Two sheet members 31 and 32 are joined between two electrode plates 22 and 23 mounted on the sheet member 130 and the mesh electrode plate 24 is positioned between the two sheet members 31 and 32 The electrolytic bath main body 100 is injected and molded by plastic into the interior of the electrolytic bath main body 100, that is, the primary spatial part 110 and the secondary spatial part 130, and the electrode plates 20 and 21 And the electrodes 20a, 21a, 22a, 23a and 24a for supplying power to the electrolytic bath main body 100 are exposed to the outside of the main body 100 of the electrolytic bath, So that the hole 106 is made to pass through the electrolytic bath main body 100 during injection molding.

However, since the electrolytic bath main body 100 is filled with water and electrolysis is performed at this time, the electrolytic bath main body 100 may be damaged due to the plastic nature of the electrolytic bath main body due to the shrinkage and expansion of the electrolytic bath main body or the electrodes 20a, 21a, 22a, And 24a are injection-molded in a fine error range so as to be easily coupled to the electrode holes 106 and to be tightly coupled with each other, it is impossible to join the electrode plates one by one.

This is because the inside of the electrolytic cell is filled with water so that airtightness must be maintained. In addition, the electrode hole 106 formed in the main body of the electrolytic cell must be tightly fitted and easily inserted.

In addition, the electrode plate and the diaphragm must be closely adhered to each other under pressure by being pressed together. Otherwise, the electrode plate and the diaphragm may not be assembled, and the efficiency of electrolysis may deteriorate. Each of the electrode plates can not be individually inserted into the first and second space portions of the electrolytic cell so that the electrodes can be made to fit into the electrode holes 106.

Therefore, in this state, the electrode assembly 20, 21, 22, 23, 24 and the diaphragms 30, 31, 32 are tightly pressed against each other, The electrodes 20a, 21a, 22a, 23a, and 24a are automatically inserted into the electrode holes 106 while being inserted into the secondary space 130. [

Accordingly, in the present invention, in order to precisely align the electrodes formed on the electrode plate with the electrode holes 106 of the electrolytic bath, partition walls 110a and 130a, which constitute the primary space portion and the secondary space portion, The electrode plate and the diaphragm are pressed together by the inner groove 107 and the inner space 108 and the electrode is inserted into the inner groove 107 and the inner space 108, The electrode is automatically inserted into the electrode hole 106 formed in the electrolytic bath main body so as to be brought into close contact with the inner space 107 and the inner space 108 and then to be inserted into the primary space 110 and the secondary space 130, It becomes possible.

In addition, when the electrode is inserted into the electrode hole of the electrolytic cell, the electrolytic cell is formed by injection molding. Therefore, even if injection molding is performed with accuracy, a space is formed for fitting the electrode, A packing ring is mounted on the electrode, and the packing ring 50 is formed in a shape of a packing in which the packing ring is inserted into the inner jaw while the inner jaw 109 is formed so that the packing ring can be closely fitted on the outer surface of the electrode hole of the electrolytic bath. The ring is tightly attached to the upper layer by tightening by the washer 60 and the tightening nut 70 so that the packing ring is tightly adhered to maintain airtightness.

At this time, since the electrode is necessarily formed with a thread, the packing ring is tightly pressed against the electrode hole by tightening with the tightening nut, thereby preventing water from leaking.

In addition, the screw thread formed on the electrode can be exchanged while allowing the connection of the terminal for connection of the power source to the electrode to be easily connectable by the tightening nut.

In order to fix the electrodes 20a, 21a, 22a, 23a, and 24a to the electrode plate, the electrode is previously fixed by simple welding to one side of the electrode plate so that the electrode is only in line contact with the electrode plate, There is a drawback that the precision of the work can not be maintained by attempting to make contact with the surface and that there is a cause of defects caused by defective welding. Therefore, the electrode plate and the diaphragm are pressurized and combined in the first and second spaces of the electrolytic cell body It was impossible to assemble it.

Therefore, the efficiency of the electrolysis was lowered by coupling one by one in the state of being separated from each other.

Accordingly, the staggered grooves 25 and the curved protrusions 26 are formed on the electrode plates 20, 21, 22, 23, and 24 on both sides of the electrode plate by the press method, 27 are formed so that the electrodes are forced into the recesses 27 and fixed by spot welding.

Therefore, when the electrode is always inserted in the correct position, when the electrode plate and the diaphragm are tightly pressed together and inserted into the primary charger and the secondary storage unit of the electrolytic bath body in a state of being lined, the electrode is automatically engaged with the electrode hole .

In addition, a platinum coating layer 28 is formed on one surface of the electrode plate, that is, on the surface where the diaphragms are in close contact with each other, for electrical discharge, and on the back surface thereof, Thereby forming an oxide film layer 29 by coating treatment.

By doing so, it is possible to reduce the cost and improve the electrolysis efficiency.

Further, when fixing the lid 200 of the electrolytic bath, the electrolytic bath body 100 is merely fused by the high frequency to the electrolytic bath body 100, so that when a large pressure is applied to the inside of the electrolytic bath body 100, The present invention is capable of coping with a changing water pressure by causing the fastening joint to be performed simultaneously by the tightening means at the same time as the fusion.

A tightening protrusion 103 having a tightening hole 104 is formed on the outer side of the electrolyzer body 100 at equal intervals so as to protrude to the outside of the flange 102 for high frequency bonding, A tightening protrusion 202 having a tightening hole 201 is formed so as to penetrate the tightening hole 104 so that the tightening protrusion 202 is tightly engaged with the fastening protrusion 202 and tightened.

In addition, the electrolytic bath can be installed in the water purifier by providing the fixing means 105 for mounting the electrolytic bath main body 100 in the water purifier in the state where the lid is coupled.

The fastening means 105 and 203 are formed so as to extend outward from the fastening protrusions 103 and 202 at both side ends of the electrolytic bath main body 100 and the lid 200 so that they can be easily assembled and mounted.

The fixing means is formed in such a manner that one side of the pinched assembly is opened for fixing, and then the opened portion is formed to be curved for fastening and fixing using a screw or the like.

At this time, the fastening means 105 is formed on the flange, and at the same time, the fastening protrusion is projected on the side wall of the electrolytic bath main body 100 so as to be easily mounted even when the water purifier is mounted side by side, 105a.

10: 1 lined feed regulating membrane
20: electrode plate
30: diaphragm
40: 2 feed rate regulating membrane
50: Packing ring
60: Watsha
100: electrolytic bath main body
200: Cover
300: elastic pad

Claims (2)

In the electrolytic water purifier to which the electrode plate is mounted,
The insertion hole 27 is formed on both sides of the electrode plate by the press method in the electrode plate, and the insertion hole 27 is formed so that the electrode is sandwiched therebetween by forming the curved groove 25 and the curved protrusion 26. The electrode is always clamped by spot welding after being forced to be pinched by the welding. Therefore, the electrode plate and the diaphragm are tightly pressed and inserted into the primary storage unit and the secondary storage unit of the electrolyzer body while being laminated. In this case, the electrode is automatically bonded to the electrode hole The method of claim 1,
One surface of the electrode plate, that is, the surface where the diaphragm is in close contact with each other, forms a platinum coating layer 28 for discharging for electric separation, and on the rear side thereof, an oxidation is performed to prevent the generation of harmful substances to the human body by chemical reaction. Forming the oxide film layer 29 by the film treatment

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