WO2021015313A1 - Series electrolytic apparatus for water ionizer - Google Patents

Abstract

The present invention relates to a series electrolytic apparatus for a water ionizer, and the series electrolytic apparatus for a water ionizer, according to the present embodiment, comprises: a cathode electrolytic cell which provides a cathode plate such that a cathode flow path is formed and alkaline ionized water is generated in the cathode flow path; and an anode electrolytic cell which provides an anode plate such that an anode flow path is formed and acidic ionized water is generated in the anode flow path, wherein a plurality of cathode electrolytic cells and anode electrolytic cells are provided and stacked by being alternately bonded, and wherein the plurality of cathode electrolytic cells are combined so as to be connected in series such that water introduced into the cathode electrolytic cells sequentially flows through the cathode electrolytic cells, and the plurality of anode electrolytic cells are combined to be connected in series such that water introduced into the anode electrolytic cells sequentially flows through the anode electrolytic cells. According to the present invention, a plurality of cathode electrolytic cells are connected in series, and a plurality of anode electrolytic cells are connected in series such that energy can be saved since strong alkaline or strongly acidic ionized water can be generated even when a relatively low voltage is applied to each electrode plate.

Description

Series electrolytic device for water ionizer

The present invention relates to a series electrolytic apparatus for an ionizer, and more particularly, two or more electrolysis cells are provided for generating ionized water by electrolyzing raw water flowing through an inlet and discharging the generated ionized water through an outlet, The present invention relates to a series electrolytic apparatus for an ionizer capable of generating ionized water with high efficiency by being connected in series with each other by connecting an outlet of an electrolytic cell to an inlet of another electrolytic cell.

Recently, as people's interest in life has been increased and there is an economic margin, in addition to meeting basic needs of food, clothing, and shelter, interest in quality of life and health is increasing.

In accordance with this trend, the use of ionizers capable of supplying ionized water has been actively increasing in recent years due to the demand to use water used for drinking, washing, etc. by converting it to water that is more healthy than simply filtering and using water.

Such an ionizer is provided with an electrolytic device for generating ionized water by electrolyzing the raw water in order to generate ionized water using the supplied raw water. The electrolytic device electrolyzes the supplied raw water using an electrode plate to which the voltage of the negative electrode is applied to generate alkaline ionized water formed by collecting alkaline ions such as calcium ions, magnesium ions, potassium ions, and sodium ions, and the voltage of the positive electrode is applied. The supplied raw water is electrolyzed using the electrode plate to generate acidic ionized water that is formed by collecting acidic ions such as chloride ions and sulfur ions.

Alkaline ionized water has small water particles, so it is quickly absorbed into the body and has an antioxidant effect that removes active oxygen, so it can be used for drinking, cooking or washing food, and acidic ionized water has sterilization and bleaching effects, so cleansing and washing cooking utensils , It can be used for disinfection of wounds.

On the other hand, in order to generate an appropriate amount of ionized water, a conventional electrolysis device is constructed by connecting in parallel a plurality of electrolytic cells including electrode plates to which a voltage of the same pole is applied, and such a conventional electrolytic device is a highly acidic or strongly alkaline ionized water. There is a problem in that power consumption is increased because a high voltage must be applied when generating is.

In addition, in the conventional electrolysis device, even if the performance is deteriorated due to the lime material deposited in a specific electrolysis cell, alkaline ionized water having a pH concentration lower than the target pH concentration or acidic ion water having a pH concentration higher than the target pH concentration is discharged, There is a problem in that it is difficult to detect performance degradation of a specific electrolysis cell without a separate pH concentration measuring device because there is no difference in the amount of water discharged because ionized water is discharged through different electrolytic cells connected in parallel. do.

The present invention is to solve the problems of the prior art mentioned above, and the object of the present invention is to provide raw water supplied by connecting a plurality of electrolytic cells in series so that all electrolytic cells forming the same pole are connected to one channel. By allowing water to be discharged after passing through a plurality of electrolytic cells, strong alkali or strongly acidic ionized water is generated even when a relatively low voltage is applied to each electrode plate, and a separate pH concentration measuring device is not provided when lime substances are added from a specific electrolytic cell. It is to provide a series electrolytic device for ionizers that can be found without needing to be found.

Another object of the present invention is to be configured such that a plurality of electrolytic cells constituting a cathode are connected in series and a plurality of electrolytic cells constituting an anode are connected in series in one electrolytic apparatus, so that alkaline ionized water and acidic ionized water can be generated together. In order to achieve this, the type of parts to achieve this is minimized, thereby providing a series electrolysis device for an ionizer that can reduce the production cost.

In the series electrolytic apparatus for an ionizer according to an embodiment of the present invention, a cathode channel inlet and a cathode channel outlet are formed, a cathode channel is formed from the cathode channel inlet to the cathode channel outlet, and alkaline ionized water is generated on the cathode channel. The cathode electrolytic cell, the anode flow path inlet and the anode flow path outlet are formed, the anode flow path is formed from the anode flow inlet to the anode flow outlet, and a positive electrode plate is provided to generate acidic ion water on the anode flow path, and It includes an ion diaphragm interposed between the negative electrode electrolytic cell and the positive electrode electrolytic cell to separate the negative electrode flow path and the positive electrode flow path. The water flowing into the electrolytic cell is connected in series so that the plurality of cathode electrolytic cells flow sequentially, and the plurality of positive electrolytic cells are connected in series so that the water flowing into the positive electrolytic cell flows sequentially through the plurality of positive electrolytic cells. Are combined.

At this time, a separate cathode channel bypass hole is formed in the cathode electrolytic cell, and a separate anode channel bypass hole separated from the anode channel is formed in the anode electrolytic cell, and a cathode channel formed in each of the plurality of cathode electrolytic cells Are connected to each other through an anode channel bypass hole formed in the anode electrolytic cell, and the anode channel formed in each of the plurality of anode electrolytic cells may be connected to each other through a cathode channel bypass hole formed in the cathode electrolytic cell.

In addition, the cathode flow inlet and the cathode flow outlet are formed on the front and rear upper ends of the cathode electrolysis cell, respectively, the cathode flow bypass hole is formed through the lower end of the cathode electrolytic cell in the front and rear directions, and the anode flow inlet and the anode flow outlet are positive electrolysis. The anode flow path bypass holes are formed at the top of the front and rear sides of the cell, respectively, and the anode flow path bypass hole is formed through the bottom of the anode electrolytic cell in the front-rear direction, and the cathode electrolytic cell and the anode electrolytic cell are vertically inverted and coupled to each other.

In addition, the cathode and anode electrolytic cells are laminated so that the cathode flow path outlet communicates with the anode flow path bypass hole and the anode flow path inlet communicates with the cathode flow path bypass hole, or the cathode flow path inlet communicates with the anode flow path bypass hole and the anode The flow path outlet may be stacked and coupled to communicate with the cathode flow path bypass hole.

In addition, the cathode electrolytic cell is intimately coupled to the front surface of the negative electrode sealing frame so as to be spaced apart from the negative electrode plate, the negative electrode plate including the negative electrode sealing frame sealingly surrounding the edge of the negative electrode plate, and the negative electrode flow inlet at one side. And a cathode rear cover plate in which a cathode front cover plate is formed, and a cathode rear cover plate which is closely coupled to the rear surface of the cathode sealing frame so as to be spaced apart from the rear surface of the cathode plate and has a cathode passage outlet formed at one side thereof, and part of the edge section of the cathode plate In the section, a communication hole is formed in a form spaced apart from the cathode sealing frame, and the cathode channel is formed so that water flowing into the cathode channel inlet contacts the front and rear surfaces of the cathode plate through the communication hole and flows out to the cathode channel outlet. I can.

In addition, the positive electrode electrolytic cell is closely coupled to the front surface of the positive electrode plate, the positive electrode plate including the positive electrode sealing frame sealingly surrounding the edge of the positive plate, and the positive electrode sealing frame so as to be spaced apart from the front surface of the positive electrode plate, The anode front cover plate is formed, and the anode rear cover plate is intimately coupled to the rear surface of the anode sealing frame so as to be spaced apart from the rear surface of the anode plate, and has an anode flow outlet at one side, and some of the edge sections of the anode plate In the section, a communication hole is formed in a form spaced apart from the anode sealing frame, and the anode flow path can be formed so that water flowing into the anode flow path inlet contacts the front and rear surfaces of the anode plate through the communication hole and flows to the anode flow outlet. have.

In addition, the cathode front cover plate and the cathode rear cover plate, the anode front cover plate and the anode rear cover plate have through holes formed in the center area, and the ion diaphragm is formed through holes in the rear surfaces of the cathode rear cover plate and the anode rear cover plate. It can be attached and bonded in the form of blocking.

In addition, an intaglio surface is formed on the opposite side of the negative electrode front cover plate and the negative electrode rear cover plate so that the negative electrode plate is inserted and coupled, and the positive electrode plate is inserted and coupled on the opposite surface of the positive front cover plate and the positive rear cover plate. Can be formed.

In addition, the negative electrode front cover plate and the negative electrode rear cover plate are provided with a spacing part to maintain the same distance from the negative electrode in the entire area of the negative electrode plate, and the positive front cover plate and the positive rear cover plate have a space between the positive electrode plate. The spacing part may be formed so as to remain the same in the entire area.

In addition, a plurality of support ribs formed in parallel in a direction crossing the through hole, and a plurality of support ribs are formed on one side of the support ribs so as to protrude toward the negative electrode plate or the positive electrode plate, and the protruding ends are formed to contact and support the negative plate or the positive plate. May include projections.

In addition, a cathode flow path bypass hole is formed in the cathode electrolytic cell in a form that passes through the cathode sealing frame, the cathode front cover plate and the cathode rear cover plate in the front and rear direction, and the anode sealing frame, the anode front cover plate, and the anode rear cover plate An anode flow path bypass hole may be formed to penetrate the cover plate in the front-rear direction.

In addition, a coupling sealing plate is interposed between the negative electrode electrolytic cell and the positive electrode electrolytic cell so as to seal the space between the negative electrode electrolytic cell and the positive electrode electrolytic cell, and the coupling sealing plate includes a cathode flow path and an anode flow path bypass hole, and an anode flow path and a cathode. Sealing connection holes may be formed so that the flow path bypass holes are respectively sealed and communicated.

According to the present invention, a plurality of cathode electrolytic cells are connected in series, and a plurality of anode electrolytic cells are connected in series, so that even when a relatively low voltage is applied to each electrode plate, strong alkali or strongly acidic ionized water can be generated, thereby reducing energy consumption. have.

In addition, when lime material is deposited in a specific electrolytic cell by serial connection, the amount of ionized water rapidly decreases, so it is easy to know the deposition of lime material even without a separate pH concentration measuring device. It can be done early.

In addition, since specific parts perform a number of roles according to the coupling relationship, the types of parts for forming the device can be minimized, thereby reducing the production cost.

1 is a view showing a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

2 is an exploded perspective view of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

3 is a view showing a cathode electrolytic cell of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

4 is a view showing a positive electrode electrolysis cell of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

5 is a view showing a cathode flow path and an anode flow path of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

6 is a view showing a cathode front cover plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

7 is a view showing a cathode plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

8 is a view showing a cathode rear cover plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

9 is a view showing an anode front cover plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

10 is a view showing an anode plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

11 is a view showing an anode rear cover plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

12 is a view showing a cathode front cover plate disposed at the forefront of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

13 is a view showing a cathode rear cover plate disposed at the rear of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

14 is a view showing a coupling sealing plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to elements of each drawing, it should be noted that the same elements have the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

FIG. 1 is a view showing a series electrolytic apparatus 10 for an ionizer according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of a series electrolytic apparatus 10 for an ionizer according to an embodiment of the present invention.

1 to 2, the series electrolytic apparatus 10 for an ionizer according to this embodiment includes a cathode electrolysis cell 100, an anode electrolysis cell 200, an ion diaphragm 300, and a bonding sealing plate 400. do.

The cathode electrolysis cell 100 has a cathode flow path for generating alkaline ionized water by electrolyzing water, and the anode electrolysis cell 200 has an anode flow path for generating acidic ionized water by electrolyzing water.

The cathode electrolysis cell 100 and the anode electrolysis cell 200 are provided in plural and alternately stacked and bonded to each other, and in the plurality of cathode electrolytic cells 100, water flowing into the cathode electrolytic cell flows sequentially through the plurality of cathode electrolytic cells. The plurality of anode electrolytic cells 200 are coupled to be connected in series so that the water flowing into the anode electrolytic cells flows sequentially through the plurality of anode electrolytic cells.

Accordingly, the series electrolytic apparatus for an ionizer according to the present embodiment can generate strong alkaline ionized water or strong acidic ionized water even when a relatively low voltage is applied to each of the electrolysis cells.

In addition, through holes 113, 153, 213, and 253 are formed in the cathode electrolytic cell 100 and the anode electrolytic cell 200 so that the central regions of the front and rear surfaces are opened in order to exchange ionic substances in the cathode and anode flow paths. At this time, the cathode and anode channels are separated so that alkaline ionized water and acidic ionized water are not mixed by the through holes 113, 153, 213, and 253. The diaphragm 300 is interposed.

Specifically, the ion diaphragm 300 is attached to and coupled to the rear surface of the cathode electrolytic cell 100 or the anode electrolytic cell 200 in a form that blocks the through holes 153 and 253 formed on the rear surface of the electrolytic cell, The flow path is separated, but only the ionic material passes so that the exchange of the ionic material between the cathode flow path and the anode flow path is performed. Here, the ion diaphragm 500 may be composed of any one of a proton exchange membrane and a polymer electrolyte membrane through which only ionic materials pass.

A coupling sealing plate is interposed in the space between the negative electrolytic cell 100 and the positive electrolytic cell 200 to seal the space between each negative electrolytic cell 100 and the positive electrolytic cell 200.

In the electrolytic apparatus for an ionizer according to the present embodiment, when the plurality of anode electrolytic cells 200 and the cathode electrolytic cells 100 are alternately arranged, among the anode electrolytic cells 200 and the cathode electrolytic cells 100 at the foremost or rearmost Any electrolysis cells may be disposed, but in general, in an ionizer, the amount of alkaline ionized water is greater than that of acidic ionized water, so that the cathode electrolysis cells 100 are arranged to be disposed at the foremost and the rearmost, so that the number of the cathode electrolytic cells 100 is reduced. It would be desirable to be configured to be one more than the number of anode electrolytic cells 200.

In addition, an open hole is not provided for the cathode electrolytic cell 100′ disposed in the foremost position because the central area of the front surface does not need to be opened, and an open hole is also provided for the rear surface of the cathode electrolytic cell 100′ disposed at the rear. It doesn't work.

3A and 3B are views showing a cathode electrolysis cell 100 of a series electrolysis apparatus for an ionizer according to an embodiment of the present invention, and FIGS. 4A and B are views of a series electrolysis apparatus for an ionizer according to an embodiment of the present invention. FIG. 5 is a view showing a cathode electrolysis cell 200, and FIG. 5 is a view showing a cathode flow path and an anode flow path of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

3A to 5, the cathode electrolytic cell 100 of the series electrolytic apparatus for an ionizer according to the present embodiment has a cathode channel inlet 111 and a cathode channel outlet 151 formed therein, and from the cathode channel inlet 111 Arranged to form a cathode flow path to the cathode flow outlet 151, the cathode plate 131 to generate alkaline ionized water on the cathode channel, the cathode plate 131

Here, since the cathode electrolytic cells 100 are provided in plural and are connected in series with each other, the water flowing through the cathode flow inlet 111 of the cathode electrolytic cells other than the cathode electrolytic cells disposed at the foremost among the cathode electrolytic cells is raw water. It is not alkaline ionized water, and in this case, the alkaline ionized water is electrolyzed again on the cathode flow path, so that strong alkaline ionized water having a higher pH concentration is discharged through the cathode channel outlet 151.

The anode electrolysis cell 200 of the series electrolytic apparatus for an ionizer according to the present embodiment has an anode flow path inlet 211 and an anode flow path outlet 251 formed therein, and from the anode flow path inlet 211 to the anode flow path outlet 251 It is disposed to form a flow path, and a positive electrode plate 231 is provided so that alkaline ionized water is generated on the positive electrode flow path.

Here, since the anode electrolytic cells 200 are provided in plural and are connected in series with each other, the water flowing through the anode flow inlet 211 of the anode electrolytic cells other than the anode electrolytic cells disposed at the foremost among the anode electrolytic cells is raw water. In this case, the acidic ionized water is again electrolyzed on the anode flow path, so that strong alkaline ionized water having a lower pH concentration is discharged through the anode channel outlet 251.

Meanwhile, in the cathode electrolytic cell 100, separate cathode flow path bypass holes 112, 133a, 152 separated from the cathode flow path are formed, and in the anode electrolytic cell 200, a separate anode flow path bypass hole separated from the anode flow path ( 212, 233a, 252) are formed. As described above, the plurality of cathode electrolytic cells 100 and the anode electrolytic cells 200 are alternately coupled to each other, and each cathode channel is connected to a cathode channel and each anode channel is connected to an anode channel. The cathode flow paths formed in each of 100) are connected to each other through the anode flow path bypass holes 212, 233a, 252 formed in the anode electrolytic cell, and the anode flow paths formed in the plurality of anode electrolytic cells 200 are respectively formed in the cathode electrolytic cell. They may be connected to each other through bypass holes 112, 133a, and 152.

Specifically, the cathode passage inlet 111 and the cathode passage outlet 151 are formed on the front and rear tops of the cathode electrolytic cell 100, respectively, and the cathode channel bypass holes 112, 133a and 152 are the cathode electrolytic cells 100. The anode flow path inlet 211 and the anode flow path outlet 251 are respectively formed at the front and rear bottoms of the anode electrolysis cell 200 and are formed at the lower end of the anode flow path bypass holes 212, 233a, 252 Silver is formed through the anode electrolytic cell 200 in the front-rear direction. In addition, in the cathode electrolytic cell 100 and the anode electrolytic cell 200, the cathode flow path outlet 151 communicates with the anode flow path bypass holes 212, 233a, and 252, and the anode flow path inlet 211 is connected to the cathode flow path bypass hole 112. , 133a, 152, or the cathode flow path inlet 111 communicates with the anode flow path bypass holes 212, 233a, 252, and the anode flow path discharge port 251 connects with the cathode flow path bypass holes 112, 133a, 152) may be laminated to communicate with each other.

6A and 6B are views showing a cathode front cover plate of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention, and FIG. 7 is a cathode plate 130 of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention. ) Is a diagram showing. 8A and 8B are views showing a cathode rear cover plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

6A to 8B, in the cathode electrolytic cell 100, a cathode front cover plate 110, a cathode plate 130, and a cathode rear cover plate 150 may be sequentially combined.

The cathode front cover plate 110 is closely coupled to the front surface of the cathode sealing frame 133 so as to be spaced apart from the front surface of the cathode plate 131, and the cathode flow path inlet 111, the first cathode flow path bypass hole 112 , The first cathode flow path through hole 113, the first cathode plate support rib 114a, the first cathode plate support protrusion 114b, the first fixing protrusion 115, the first front coupling protrusion 116, the first front coupling A groove 117, a first rear coupling protrusion 118, and a first rear coupling groove 119 may be included.

The cathode flow path inlet 111 is the upper end of the cathode front cover plate 110 so that alkaline ionized water bypassing the anode flow path from the anode flow path bypass holes 212, 233a, 252 of the front end flows into the cathode flow path of the cathode electrolysis cell 100. It is formed in a shape that penetrates in the front and rear direction and may be connected to the cathode flow path bypass holes 112, 133a, and 152 at the front end.

The first cathode channel bypass hole 112 communicates with the second cathode channel bypass hole 133a and the third cathode channel bypass hole 152 to form a cathode channel bypass hole 112, 133a, 152 of the cathode electrode cell together. do.

The first cathode flow path through-hole 113 is formed in a shape in which a portion of the first cathode passage through-hole 113 penetrates in the front-rear direction. In this case, the first cathode passage through hole 113 may be blocked by an ion diaphragm 300 attached to the anode rear cover plate coupled to the front end of the cathode front cover plate.

Meanwhile, the negative electrode front cover plate 110 maintains the same distance from the negative electrode plate 131 in the entire area of the negative electrode plate 131 so that the first negative electrode plate spacing part is maintained in order to prevent the width of the flow path from narrowing in some sections. Can be formed. Here, in the first negative electrode plate spacing part, a plurality of first negative electrode plate support ribs 114a and a plurality of first negative electrode plate support ribs 114a formed in parallel in the transverse direction of the first negative electrode passage through hole 113 and a negative electrode plate ( A plurality of first negative electrode plate support protrusions 114b may be formed so as to protrude toward the negative electrode plate 131 and have a protruding end thereof in contact with the negative electrode plate 131.

The first fixing protrusion 115 is inserted into the first fixing hole 133b of the negative electrode plate so that the negative electrode plate 130 is fixed to the negative electrode front cover plate 110 so as to protrude from the surface of the negative electrode front cover plate opposite the negative plate. I can. In this case, an intaglio surface may be formed on one surface of the negative electrode front cover plate 110 on which the first fixing protrusion 115 is formed so that the negative electrode plate 130 is inserted and coupled.

The first front coupling protrusion 116 is inserted into the second front coupling groove 157 formed in the negative electrode rear cover plate to form an intaglio so that the negative electrode front cover plate 110 and the negative electrode rear cover plate 150 are mutually coupled. It may be formed in a plurality around the one surface.

The first front coupling groove 117 is formed with an intaglio so that the negative front cover plate 110 and the negative rear cover plate 150 are mutually coupled by inserting the first front coupling protrusion 116 formed on the negative electrode rear cover plate. It may be formed in a plurality around the one surface.

The first rear coupling protrusion 118 is inserted into the fourth rear coupling groove 259 formed in the positive rear cover plate to form an intaglio so that the negative front cover plate 110 and the positive rear cover plate 250 are mutually coupled. A plurality may be formed around the rear surface of the surface.

The first rear coupling groove 119 is formed with an intaglio so that the negative front cover plate 110 and the positive rear cover plate 250 are mutually coupled by inserting the fourth rear coupling protrusion 258 formed on the positive rear cover plate. A plurality may be formed around the rear surface of the surface.

The negative electrode plate 130 may include a negative electrode plate 131 and a negative electrode sealing frame 133.

The negative electrode plate 131 may be connected to a separate power supply to have a negative electrode contact end 131a protruding from an upper end thereof so that a voltage of the negative electrode is applied thereto.

The negative electrode sealing frame 133 is sealed around an edge of the negative electrode plate 131. In this case, the negative electrode sealing frame 133 may be provided so that the lower section of the circumference of the negative electrode plate 131 is spaced apart and enclosed so that the negative electrode flow path communication hole S1 is formed. Here, the cathode flow path may be formed so that the water flowing into the cathode flow path inlet 111 comes into contact with the front and rear surfaces of the cathode plate 131 through the cathode flow path communication hole S1 and flows out to the cathode flow outlet 151. have. Here, the cathode sealing frame 133 may be formed of a silicon material.

In addition, the cathode sealing frame 133 communicates with the first cathode channel bypass hole 112 and the third cathode channel bypass hole 152 to form cathode channel bypass holes 112, 133a, 152 of the cathode electrode cell together. A second cathode flow path bypass hole 133a may be formed at the lower end of the cathode sealing frame 133 to penetrate in the front-rear direction.

In addition, the first fixing protrusion 115 or the second fixing protrusion 155 is inserted into the negative electrode sealing frame 133 so that the negative electrode plate 130 is fixed to the negative front cover plate 110 or the negative rear cover plate 150. A first fixing hole 133b may be formed to pass through in the front-rear direction at the lower end of the cathode sealing frame 133 so as to be possible.

Meanwhile, the negative electrode rear cover plate 150 is closely coupled to the rear surface of the negative electrode sealing frame 133 so as to be spaced apart from the rear surface of the negative electrode plate 131, and the negative electrode flow path outlet 151 and the third negative electrode flow path bypass hole ( 152, second cathode flow path through hole 153, second cathode plate support rib 154a, second cathode plate support protrusion 154b, second fixing protrusion 155, second front coupling protrusion 156, second A front coupling groove 157, a second rear coupling protrusion 158, and a second rear coupling groove 159 may be included.

Here, the negative electrode rear cover plate 150 is a cover plate having the same shape as the negative electrode front cover plate 110, except that the negative electrode rear cover plate 150 is combined from the rear of the negative electrode plate 130 to discharge alkaline ionized water. That is, the negative electrode front cover plate 110 and the negative electrode rear cover plate 150 are manufactured identically to each other, only having different roles and coupling positions.

The cathode flow path outlet 151 is formed in a form that penetrates in the front and rear direction at the top of the cathode rear cover plate 150 so that alkaline ionized water generated in the cathode flow path is discharged to the anode flow path bypass holes 212, 233a, 252 at the rear end. It may be connected to the anode flow path bypass holes 212, 233a, 252 at the rear end.

The third cathode channel bypass hole 152 communicates with the first cathode channel bypass hole 112 and the second cathode channel bypass hole 133a to form cathode channel bypass holes 112, 133a, 152 of the cathode electrode cell together. do.

The second cathode flow path through-hole 153 is formed in a shape in which a partial region penetrates in the front-rear direction in the central region. In this case, the ion diaphragm 300 may be attached and coupled to the rear surface of the negative electrode rear cover plate 150 in a form that blocks the second negative electrode passage through hole 153.

Meanwhile, the negative electrode rear cover plate 150 maintains the same distance from the negative electrode plate 131 in the entire area of the negative electrode plate 131 so that the second negative electrode plate spacing part is maintained in order to prevent the width of the flow path from narrowing in some sections. Can be formed. Here, in the second negative electrode plate spacing part, a negative electrode plate is provided on one surface of the plurality of second negative electrode plate support ribs 154a and the second negative electrode plate support ribs 154a formed in parallel in a direction transverse to the second negative electrode channel through hole 153. A plurality of second negative electrode plate support protrusions 154b may be formed so as to protrude toward the negative electrode plate 131 and have a protruding end thereof in contact with the negative electrode plate 131.

The second fixing protrusion 155 is inserted into the first fixing hole 133b of the negative electrode plate so that the negative electrode plate 130 is fixed to the negative electrode rear cover plate 150 so that the second fixing protrusion 155 is formed to protrude from the surface opposite the negative electrode plate of the negative electrode rear cover plate. I can. In this case, an intaglio surface may be formed on one surface of the cathode rear cover plate 150 on which the second fixing protrusion 155 is formed so that the cathode plate 130 is inserted and coupled.

The second front coupling protrusion 156 is inserted into the first front coupling groove 117 formed in the negative electrode front cover plate to form an intaglio so that the negative electrode rear cover plate 150 and the negative electrode front cover plate 110 are mutually coupled. It may be formed in a plurality around the one surface.

The second front coupling groove 157 is formed with an engraved surface so that the negative rear cover plate 150 and the negative front cover plate 110 are mutually coupled by inserting the first front coupling protrusion 116 formed on the negative electrode rear cover plate. It may be formed in a plurality around the one surface.

The second rear coupling protrusion 158 is inserted into the third rear coupling groove 219 formed in the positive front cover plate to form an intaglio so that the negative rear cover plate 150 and the positive front cover plate 210 are mutually coupled. A plurality may be formed around the rear surface of the surface.

The second rear coupling groove 159 is formed with an intaglio so that the negative rear cover plate 150 and the positive front cover plate 210 are mutually coupled by inserting the third rear coupling protrusion 218 formed on the positive front cover plate. A plurality may be formed around the rear surface of the surface.

9A and 9B are views showing an anode front cover plate 210 of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention, and FIG. 10 is a view showing an anode of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention. It is a view showing the plate 230. 11A and 11B are views showing the anode rear cover plate 250 of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

9A to 11B, in the anode electrolytic cell 200, the anode front cover plate 210, the anode plate 230, and the anode rear cover plate 250 may be sequentially coupled.

Here, the positive electrode electrolytic cell 200 differs only in that the voltage of the positive electrode is applied and the upper side and the lower side are inverted, and have the same shape as the cathode electrolytic cell 100.

The positive electrode front cover plate 210 is closely coupled to the front surface of the positive electrode sealing frame 233 so as to be spaced apart from the front surface of the positive electrode plate 231, and the positive electrode flow inlet 211 and the first positive flow bypass hole 212 , First anode flow path through hole 213, first anode plate support rib 214a, first anode plate support protrusion 214b, third fixing protrusion 215, third front coupling protrusion 216, third front coupling It may include a groove 217, a third rear coupling protrusion 218, and a third rear coupling groove 219.

The anode flow path inlet 211 is the lower end of the anode front cover plate 210 so that acidic ion water bypassing the cathode flow path from the cathode flow path bypass holes 112, 133a, 152 at the front end flows into the anode flow path of the anode electrolysis cell 200. It is formed in a shape that penetrates in the front and rear direction and may be connected to the cathode flow path bypass holes 112, 133a, and 152 at the front end.

The first anode channel bypass hole 212 communicates with the second anode channel bypass hole 233a and the third anode channel bypass hole 252 to form anode channel bypass holes 212, 233a, 252 of the anode electrode cell together. do.

The first anode flow path through-hole 213 is formed in a central region so that a partial region penetrates in the front-rear direction. In this case, the first anode flow path through hole 213 may be blocked by the ion diaphragm 300 attached to the cathode rear cover plate coupled to the front end.

Meanwhile, the positive front cover plate 210 maintains the same distance from the positive electrode plate 231 in the entire area of the positive electrode plate 231 so that the first positive electrode plate gap maintenance part prevents the width of the flow path from narrowing in some sections. Can be formed. Here, in the first positive electrode plate spacing part, a positive electrode plate on one surface of the plurality of first positive electrode plate support ribs 214a and the first positive plate support ribs 214a formed in parallel in a direction transverse to the first positive electrode channel through hole 213 A plurality of first positive electrode plate support protrusions 214b may be formed so as to protrude toward the positive electrode plate 231 and have a protruding end thereof in contact with the positive electrode plate 231.

The third fixing protrusion 215 is inserted into the second fixing hole 233b of the positive electrode plate to protrude from the surface opposite the positive electrode plate of the positive electrode front cover plate so that the positive electrode plate 230 is fixed to the positive electrode front cover plate 210. I can. In this case, an intaglio surface may be formed on one surface of the positive electrode front cover plate 210 on which the third fixing protrusion 215 is formed so that the positive electrode plate 230 is inserted and coupled.

The third front coupling protrusion 216 is inserted into the fourth front coupling groove 257 formed in the positive rear cover plate, thereby forming an intaglio so that the positive front cover plate 210 and the positive rear cover plate 250 are mutually coupled. It may be formed in a plurality around the one surface.

The third front coupling groove 217 has an intaglio surface formed so that the positive front cover plate 210 and the positive rear cover plate 250 are mutually coupled by inserting the fourth front coupling protrusion 256 formed on the positive rear cover plate. It may be formed in a plurality around the one surface.

The third rear coupling protrusion 218 is inserted into the second rear coupling groove 159 formed in the negative electrode rear cover plate, thereby forming an intaglio surface so that the positive front cover plate 210 and the negative rear cover plate 150 are mutually coupled. A plurality may be formed around the rear surface of the surface.

The third rear coupling groove 219 is formed with an intaglio so that the positive front cover plate 210 and the negative rear cover plate 150 are mutually coupled by inserting the second rear coupling protrusion 158 formed on the negative rear cover plate. A plurality may be formed around the rear surface of the surface.

The positive electrode plate 230 is the same as the negative plate 130 except that the positive electrode plate 230 is coupled so as to be inverted up and down compared to the negative electrode plate 130 and a voltage of the positive electrode is applied thereto.

The positive electrode plate 230 may include a positive electrode plate 231 and a positive electrode sealing frame 233.

The positive electrode plate 231 may be connected to a separate power supply to have a positive electrode contact end 231a protruding from the lower end so that the voltage of the positive electrode is applied.

The positive electrode sealing frame 233 is sealed around the edge of the positive electrode plate 231. In this case, the anode sealing frame 233 may be provided so that the upper section of the periphery of the anode plate 231 is spaced apart so that the anode flow path communication hole S2 is formed. Here, the anode flow path may be formed such that water flowing into the anode flow path inlet 211 contacts the front and rear surfaces of the anode plate 231 through the anode flow path communication hole S2 and flows out to the anode flow path outlet 251. have.

In addition, the anode sealing frame 233 communicates with the first anode channel bypass hole 212 and the third anode channel bypass hole 252 to form anode channel bypass holes 212, 233a, 252 of the anode electrode cell together. A second anode flow path bypass hole 233a may be formed on the upper end of the anode sealing frame 233 to penetrate in the front-rear direction.

In addition, a third fixing protrusion 215 or a fourth fixing protrusion 255 is inserted into the anode sealing frame 233 so that the anode plate 230 is fixed to the anode front cover plate 210 or the anode rear cover plate 250. A second fixing hole 233b may be formed on the upper end of the anode sealing frame 233 so as to penetrate in the front-rear direction.

Meanwhile, the anode rear cover plate 250 is closely coupled to the rear surface of the anode sealing frame 233 so as to be spaced apart from the rear surface of the anode plate 231, and the anode flow path outlet 251, the third anode flow path bypass hole ( 252, the second anode flow path through hole 253, the second anode plate support rib (254a), the second anode plate support protrusion (254b), the fourth fixing protrusion 255, the fourth front coupling protrusion (256), the fourth It may include a front coupling groove 257, a fourth rear coupling protrusion 258, and a fourth rear coupling groove 259.

Here, the anode rear cover plate 250 is only different in that acidic ion water is discharged by being combined at the rear of the anode plate 230, and the cathode front cover plate 110, the cathode rear cover plate 150 and the anode front cover It is a cover plate having the same shape as the plate 210. That is, the negative electrode front cover plate 110, the negative electrode rear cover plate 150, the positive electrode front cover plate 210, and the positive electrode rear cover plate 250 are manufactured identically to each other, only having different roles and coupling positions.

The anode flow path outlet 251 is formed in a form that penetrates in the front and rear directions at the bottom of the anode rear cover plate 250 so that acidic ion water generated in the anode flow path is discharged to the cathode flow path bypass holes 112, 133a, 152 at the rear end. It may be connected to the cathode flow path bypass holes 112, 133a, 152 at the rear end.

The third anode channel bypass hole 252 communicates with the first anode channel bypass hole 212 and the second anode channel bypass hole 233a to form anode channel bypass holes 212, 233a, 252 of the anode electrode cell together. do.

The second anode flow path through-hole 253 is formed in a central region so that a partial region penetrates in the front-rear direction. In this case, the ion diaphragm 300 may be attached and coupled to the rear surface of the anode rear cover plate 250 in a form that blocks the second anode flow path through hole 253.

On the other hand, the positive rear cover plate 250 maintains the same distance from the positive electrode plate 231 in the entire area of the positive electrode plate 231 so that the second positive electrode plate spacing part is maintained in order to prevent the width of the flow path from narrowing in some sections. Can be formed. Here, in the second positive electrode plate spacing part, a positive electrode plate is provided on one side of the plurality of second positive electrode plate support ribs 254a and the second positive plate support ribs 254a formed in parallel in a direction transverse to the second positive electrode passage through hole 253. A plurality of second positive electrode plate support protrusions 254b may be formed so as to protrude toward the positive electrode plate 231 and have a protruding end formed in contact with the positive electrode plate 231.

The fourth fixing protrusion 255 is inserted into the second fixing hole 233b of the anode plate to be protruded on the surface opposite the anode plate of the anode rear cover plate so that the anode plate 230 is fixed to the anode rear cover plate 250. I can. In this case, an intaglio surface may be formed on one surface of the anode rear cover plate 250 on which the fourth fixing protrusion 255 is formed so that the anode plate 230 is inserted and coupled.

The fourth front coupling protrusion 256 is inserted into the third front coupling groove 217 formed in the positive front cover plate, thereby forming an intaglio so that the positive rear cover plate 250 and the positive front cover plate 210 are coupled to each other. It may be formed in a plurality around the one surface.

The fourth front coupling groove 257 has an intaglio surface formed so that the positive rear cover plate 250 and the positive front cover plate 210 are coupled to each other by inserting the third front coupling protrusion 216 formed on the positive rear cover plate. It may be formed in a plurality around the one surface.

The fourth rear coupling protrusion 258 is inserted into the first rear coupling groove 119 formed in the negative electrode front cover plate to form an intaglio so that the positive rear cover plate 250 and the negative front cover plate 110 are mutually coupled. A plurality may be formed around the rear surface of the surface.

The fourth rear coupling groove 259 is formed with an intaglio so that the positive rear cover plate 250 and the positive front cover plate 210 are coupled to each other by inserting the first rear coupling protrusion 118 formed on the negative front cover plate. A plurality may be formed around the rear surface of the surface.

12a and b are views showing a cathode front cover plate 110 ′ disposed at the foremost of the series electrolytic apparatus for an ionizer according to an embodiment of the present invention, and FIGS. 13a and b are views according to an embodiment of the present invention. It is a view showing the cathode rear cover plate 150' disposed at the rearmost side of the series electrolytic apparatus for ionizer.

12A to 13B, the cathode front cover plate 110 ′ disposed at the foremost side of the series electrolytic apparatus for an ionizer according to the present embodiment includes a cathode channel inlet 111 ′ and a first cathode channel bypass hole 112 ′. ), a first flow path groove 113 ′, a first negative electrode plate support protrusion 114 ′, a first fixing protrusion 115 ′, a first front coupling protrusion 116 ′, a first front coupling groove 117 ′, A first rear coupling protrusion 118 ′ and a first rear coupling groove 119 ′ may be included.

The cathode flow path inlet 111 ′ of the cathode front cover plate disposed at the forefront receives source water from the outside and allows the source water to flow in. In addition, the first cathode flow path bypass hole 112 ′ of the cathode front cover plate disposed in the foremost part communicates with the second cathode flow path bypass hole 133a and the third cathode flow path bypass hole 152 to form a bypass hole. The raw water is supplied and the raw water bypasses the cathode flow path and flows into the anode flow path inlet 211 communicated to the rear end.

The cathode front cover plate 110 ′ disposed in the foremost position is provided so as to be closed without providing a through hole in the center region as described above, since there is no anode electrolytic cell connected to the front end. In addition, since the through hole is not provided, the support rib is not formed. However, a first channel groove 113 ′ is formed in the center region so that a cathode channel can be formed by being spaced apart from the cathode plate 131 on a surface facing the cathode plate 131. At this time, the first negative electrode plate support protrusion 114b' of the negative electrode front cover plate disposed in the foremost position is disposed in the first flow path groove 113'.

In addition, the first fixing protrusion 115 ′, the first front coupling protrusion 116 ′, the first front coupling groove 117 ′, the first rear coupling protrusion 118 ′ of the cathode front cover plate disposed in the foremost position, and The first rear coupling groove 119 ′ includes the first fixing protrusion 115, the first front coupling protrusion 116, the first front coupling groove 117, and the first rear coupling protrusion of the other cathode front cover plate described above ( 118) and the first rear coupling groove 119 and the same configuration.

On the other hand, the cathode rear cover plate 150 ′ disposed at the forefront of the series electrolytic apparatus for an ionizer according to the present embodiment includes a cathode flow path outlet 151 ′, a third cathode flow path bypass hole 152 ′, and a second flow path groove ( 153 ′), second negative plate support protrusion 154b′, second fixing protrusion 155 ′, second front coupling protrusion 156 ′, second front coupling groove 157 ′, second rear coupling protrusion 158 ′) and a second rear coupling groove 159 ′.

The cathode passage outlet 151' of the cathode rear cover plate disposed at the rearmost side discharges alkaline ionized water to the outside. The alkaline ionized water discharged at this time is the final alkaline ionized water supplied to the user.

And the third cathode flow path bypass hole 152 ′ of the cathode rear cover plate disposed at the rear end communicates with the first cathode flow path bypass hole 112 and the second cathode flow path bypass hole 133a to form a bypass hole. The acidic ionized water introduced from the anode electrolytic cell 200 bypasses the cathode flow path and is discharged to the outside. The acidic ionized water discharged at this time is the final acidic ionized water supplied to the user.

The cathode rear cover plate 150 ′ disposed at the rearmost side is provided so as to be closed without providing a through hole in the center region as described above, since there is no anode electrolytic cell connected to the front end. In addition, since the through hole is not provided, the support rib is not formed. However, a second flow path groove 153 ′ is formed on a surface facing the negative electrode plate 131 so as to be spaced apart from the negative electrode plate 131 to form a negative electrode flow path. At this time, the second negative electrode plate support protrusion 154b ′ of the negative electrode front cover plate disposed in the foremost position is disposed in the second flow path groove 153 ′.

In addition, the second fixing protrusion 155 ′, the second front coupling protrusion 156 ′, the second front coupling groove 157 ′, and the second rear coupling protrusion 158 ′ of the cathode rear cover plate disposed at the rearmost side. And the second rear coupling groove 159 ′ is the second fixing protrusion 155, the second front coupling protrusion 156, the second front coupling groove 157, and the second rear coupling protrusion of the other cathode rear cover plate described above. (158) and the second rear coupling groove (159) and the same configuration.

14 is a view showing a coupling sealing plate of a series electrolytic apparatus for an ionizer according to an embodiment of the present invention.

As described above, a coupling sealing plate 400 may be inserted between the cathode electrolytic cell 100 and the anode electrolytic cell 200 to seal the space between the cathode electrolytic cell 100 and the anode electrolytic cell 200. have. Here, the coupling sealing plate 400 may be formed of a silicon material.

Referring to FIG. 14, the coupling sealing plate 400 may include a first sealing connection hole 410, a second sealing connection hole 420, and a coupling hole 450.

The first sealing connection hole 410 and the second sealing connection hole 420 are sealed with the cathode flow path and the anode flow path bypass holes 212, 233a, 252 and the anode flow path and the cathode flow path bypass holes 112, 133a, 152, respectively. It can be formed to be in communication.

And the coupling hole 450 is the first rear coupling protrusion 118 of the negative front cover plate or the second rear coupling protrusion 158 of the negative rear cover plate or the third rear coupling protrusion 218 of the positive front cover plate or the positive electrode. The fourth rear coupling protrusion 258 of the rear cover plate is inserted through and the coupling sealing plate 400 is inserted into the negative front cover plate 110 or the negative rear cover plate 150 or the positive front cover plate 210 or the positive rear cover. It is formed by penetrating in the front-rear direction around the circumference of the cathode front cover plate to be coupled to the plate 250.

Meanwhile, the cathode front cover plate 110, the cathode rear cover plate 150, the anode front cover plate 210, the anode rear cover plate 250, and the combined sealing plate 400 of the series electrolytic apparatus for an ionizer according to the present embodiment. ) Has a screw hole (H) communicating with each other to be screwed to each other along the periphery of each.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

Claims (11)

1. A cathode electrolytic cell having a cathode channel inlet and a cathode channel outlet, arranged to form a cathode channel from the cathode channel inlet port to the cathode channel outlet port, and having a cathode plate to generate alkaline ionized water on the cathode channel;

   An anode electrolytic cell having an anode flow path inlet and an anode flow channel outlet, arranged to form an anode flow path from the anode flow inlet to the anode flow outlet, and provided with a positive electrode plate to generate acidic ion water on the anode flow path; And

   And an ion diaphragm interposed between the negative electrode electrolytic cell and the positive electrode electrolytic cell to separate the negative electrode flow path and the positive electrode flow path,

   The cathode electrolytic cell and the anode electrolytic cell are provided in plural and are laminated and bonded by alternating each other, and the plurality of cathode electrolytic cells are connected in series so that water flowing into the cathode electrolytic cell sequentially flows through the plurality of cathode electrolytic cells And the plurality of positive electrode electrolytic cells are coupled in series so that water flowing into the positive electrode electrolytic cells flows sequentially through the plurality of positive electrode electrolytic cells.
2. The method of claim 1,

   A separate cathode flow path bypass hole separated from the cathode flow path is formed in the cathode electrolytic cell, and a separate anode flow path bypass hole separate from the anode flow path is formed in the anode electrolytic cell,

   The cathode flow paths respectively formed in the plurality of cathode electrolytic cells are connected to each other through an anode flow path bypass hole formed in the anode electrolytic cell, and the anode flow paths respectively formed in the plurality of anode electrolytic cells are cathode flow path bypass holes formed in the cathode electrolytic cell. A series electrolytic apparatus for an ionizer, characterized in that connected to each other through the.
3. The method of claim 2,

   The cathode passage inlet and the cathode passage outlet are respectively formed on the front and rear upper ends of the cathode electrolytic cell, and the cathode channel bypass hole is formed through the lower end of the cathode electrolytic cell in the front and rear directions,

   The anode flow inlet and the anode flow outlet are formed at the front and rear bottoms of the anode electrolytic cell, respectively, and the anode flow bypass hole is formed through the top of the anode electrolytic cell in the front and rear directions,

   The cathode electrolytic cell and the anode electrolytic cell

   The cathode flow path outlet communicates with the anode flow path bypass hole and at the same time the anode flow path inlet is laminatedly coupled to communicate with the cathode flow path bypass hole, or the cathode flow path inlet communicates with the anode flow path bypass hole and the anode flow path discharge port A serial electrolysis device for an ionizer, characterized in that stacked and coupled to communicate with the cathode channel bypass hole
4. The method of claim 2, wherein the cathode electrolytic cell

   A negative electrode plate including a negative electrode sealing frame sealed around an edge of the negative electrode plate and the negative electrode plate;

   A negative electrode front cover plate which is closely coupled to the front surface of the negative electrode sealing frame so as to be spaced apart from the front surface of the negative electrode plate and has the negative electrode flow inlet at one side thereof.

   And a negative electrode rear cover plate which is closely coupled to the rear surface of the negative electrode sealing frame so as to be spaced apart from the rear surface of the negative electrode plate and has the negative electrode flow path outlet formed at one side thereof,

   A communication hole is formed in a form spaced apart from the negative electrode sealing frame in some of the edge sections of the negative electrode plate, and the negative electrode flow path allows water flowing into the negative electrode flow inlet through the communication hole to the front and rear surfaces of the negative electrode plate. A series electrolytic apparatus for an ionizer, characterized in that it is formed to flow out of the cathode passage outlet by contacting with
5. The method of claim 4, wherein the anode electrolytic cell

   A positive electrode plate including the positive electrode plate and a positive electrode sealing frame sealed around an edge of the positive electrode plate;

   An anode front cover plate which is in close contact with the front surface of the anode sealing frame so as to be spaced apart from the front surface of the anode plate and has the anode flow path inlet formed at one side thereof; And

   And an anode rear cover plate intimately coupled to the rear surface of the anode sealing frame so as to be spaced apart from the rear surface of the anode plate and having the anode flow path outlet formed at one side thereof, and in some of the edge sections of the anode plate, the anode sealing A communication hole is formed in a form spaced apart from the frame, and the anode flow path is formed so that water flowing into the anode flow path inlet contacts the front and rear surfaces of the anode plate through the communication hole and flows to the anode flow outlet. A series electrolytic apparatus for an ionizer, characterized in that.
6. The method of claim 5,

   The cathode front cover plate and the cathode rear cover plate, and the anode front cover plate and the anode rear cover plate have through holes formed in a central region,

   The ion diaphragm is attached and coupled to the rear surface of the cathode rear cover plate and the anode rear cover plate in a form of blocking the through hole.
7. The method of claim 6,

   An intaglio surface is formed on the negative electrode front cover plate and the negative electrode rear cover plate facing each other so that the negative electrode plate is inserted and coupled,

   A series electrolytic apparatus for an ionizer, characterized in that the positive electrode front cover plate and the positive electrode rear cover plate have an intaglio surface formed on the opposite surface of each other to insert and couple the positive electrode plate.
8. The method of claim 6,

   The negative electrode front cover plate and the negative electrode rear cover plate are provided with a distance maintaining part so that the distance between the negative electrode plate and the negative electrode plate remains the same in the entire area of the negative electrode plate

   The positive electrode front cover plate and the positive electrode rear cover plate, characterized in that the distance maintaining portion is formed to maintain the same distance from the positive electrode plate in the entire area of the positive electrode plate.
9. The method of claim 8, wherein the gap maintaining unit

   A plurality of support ribs formed in parallel in a direction crossing the through hole; And

   And a plurality of support protrusions formed on one surface of the support rib so as to protrude toward the negative or positive electrode plate, and having a protruding end formed in contact with the negative or positive electrode plate.
10. The method of claim 6,

    The cathode flow path bypass hole is formed in the cathode electrolytic cell to penetrate the cathode sealing frame, the cathode front cover plate, and the cathode rear cover plate in a front-rear direction,

    And the anode flow path bypass hole is formed in the anode electrolytic cell to penetrate the anode sealing frame, the anode front cover plate, and the anode rear cover plate in a front-rear direction.
11. The method of claim 10,

    A coupling sealing plate is interposed between the negative electrolytic cell and the positive electrolytic cell to seal the space between the negative electrolytic cell and the positive electrolytic cell,

    And a sealing connection hole formed in the coupling sealing plate so that the cathode flow path and the anode flow path bypass hole, and the anode flow path and the cathode flow path bypass hole are respectively sealed in communication with each other.

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