KR200206196Y1 - Manufacturing apparatus for electric analysis water - Google Patents

Abstract

The present invention relates to an electrolytic water generating device which maximizes the contact area between the electrode plate and the raw water to increase the efficiency of the electrolytic action, and induces the addition of a small amount of electrolyte to reduce the maintenance cost and increase the amount of electrolytic water produced. In that,

The electrolyzer 100 has a rectangular parallelepiped shape formed at a sharply higher ratio than the width b and the width w, and the cross-sectional shape of the electrolytic cell 100 case is approximately 'Τ' shaped. The channel type recess groove 104 is formed,

The diaphragm 101 is inserted and fixed through the concave groove 104 so as to have a cross-sectional shape of 'Ι' shape, and thus, a fastening structure of the male body is promoted.

The positive electrode chamber 102 and the negative electrode chamber 103 separated by the diaphragm 101 correspond to the height h of the electrolytic cell 100, and one side of the plate-shaped metal member is a high-conductor such as stainless steel and titanium. The electrode plate assembly is fixed in close contact with the inner wall of the electrolytic cell 100, and the plurality of separate plates 201 which are provided with the same material as that of the electrode plate 200 in the vertical direction on the other side in the vertical direction. Characterized in that to accommodate.

Description

Manufacturing apparatus for electric analysis water}

The present invention relates to a strong electrolyzed water generating device. More specifically, the structure of an electrode plate is improved in an electrolyzed water generating device that electrolyzes water into strong acidic water and strong alkaline water, thereby increasing the acidity and alkalinity and increasing the amount of generated electrolytic water. To achieve.

In general, electrolyzed water refers to acidic or alkaline water produced by electrolyzing water.

In particular, when applied to agriculture, acidic water can be used for livestock, as well as to suppress the use of pesticides, as it can be sterilized, disinfected and deodorized.

Alkaline water has the effect of promoting the growth of crops to improve productivity and sugar content in the case of fruit.

The electrolyzed water having such a feature is provided with an electrolytic cell 10 in the form of a schematic box, as shown in FIG. 1, with an insulator and permeable and ion permeable membrane 11 interposed in the center of the anode chamber on both sides. The positive electrode plate 14 and the negative electrode plate 15 are disposed in each of the two chambers 12 and the cathode chamber 13.

An inlet tube 16 of raw water supplied to the anode chamber 12 and the cathode chamber 13 is formed at the lower end of the electrolytic cell 10, and a discharge port 17 for discharging the electrolytic water is formed above.

In addition, an inlet pipe 16 is formed with an additive supply line 18 for adding a chlorine-based electrolyte such as saline solution or potassium chloride solution to promote electrolytic action.

The electrolyzed water generating device 1 introduces electrolytic water into the positive electrode plate 14 and the negative electrode plate 15 after flowing raw water containing the electrolyte into the electrolytic cell 10 and electrolytically decomposing the positive electrode chamber 12. In the cathode chamber 13, strong alkaline electrolytic water is produced.

In order to utilize the generated electrolytic water in the above-mentioned agriculture, the pH value is about 2.5-2.8 for acidic water, and about 11.5 for alkaline water, and decomposition of strong acid and strong alkaline water is required.

However, when electrolyzing general raw water, the pH value changes slowly to produce electrolyzed water which is insufficient to be used for the whole of agriculture, and complements this by adding electrolytes such as salt or potassium chloride to raw water to improve electrolytic performance. It was induced to generate strong seawater.

In order to generate strong seawater, a large amount of electrolyte must be added, and this large amount of electrolyte ultimately causes excessive maintenance expenses, thus causing a burden on the user's economic giant.

In addition, when the above-described general electrolytic water generating device is used, a very small amount of the generated electrolytic water generating device is required when it is applied to agriculture in general.

For example, when 100 liters of raw water is electrolyzed, strong acidic water and strong alkaline water each have a production amount of about 34 ml / min, and the actual application is only insignificant compared to the effect of strong electric water.

The problem of the series of electrolytic water generating apparatuses 1 as described above is, of course, the electrode plates 14 and 15 or the electrode rods provided in the electrode chambers 12 and 13 are interposed in the singular,

In the case of the electrode plates 14 and 15, the shape was due to the limited contact area with the raw water due to the flat plate shape.

Thus, in order to increase the amount of strong seawater and the amount of generation, the electrode plates were stacked in the electrode chamber. However, in this case, the structure was complicated and acted as a cause of deterioration of the electrolyte due to the current interference between the electrode plates.

In order to solve the above problems, the present invention maximizes the contact area between the electrode plate and the raw water, thereby increasing the efficiency of the electrolytic action, and inducing the addition of a small amount of electrolyte, thereby reducing the maintenance cost and increasing the amount of electrolytic water produced. For the purpose of

To this end, the shape of the electrolytic cell is formed to be higher than the width and width at a sharp rate, and the electrode plate interposed therebetween is correspondingly provided, and then a plurality of separate plates are further provided at equal intervals.

1 is a simplified cross-sectional view showing the overall configuration of a general electrolytic water generating device,

Figure 2 is an overall perspective view showing the electrolytic cell of the strong electric water generating device of the present invention,

Figure 3 is a longitudinal sectional view showing an electrolytic cell of the strong electric water generating device to which the present invention is applied,

Figure 4 is a cross-sectional view showing an electrolytic cell of the strong electric water generating device of the present invention,

5 is a partially broken perspective view showing an electrode plate in an electrolytic cell which is a main part of the present invention;

Figure 6 is a cross-sectional view showing another embodiment of the present invention.

* Description of the symbols used in the main parts of the drawings *

100; electrolytic bath 101; diaphragm

Positive and negative electrode chamber 200; Electrode plate assembly

201; Separate 204; Protrusion

205; separate cover 207; plate

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

2 is an overall perspective view showing an electrolytic cell of the electrolyzed water generating device to which the present invention is applied, FIG. 3 is a longitudinal sectional view showing an electrolytic cell of the electrolyzed water generating device to which the present invention is applied, and FIG. 4 shows an electrolytic cell of the electrolyzed water generating device of the present invention. 5 is a partially broken perspective view showing an electrode plate in an electrolytic cell which is a main part of the present invention, and FIG. 6 is described together with a cross-sectional view showing another embodiment of the present invention.

The electrolytic water generating device of the present invention for achieving the above object is an electrolytic cell 100 divided into a positive electrode chamber and a negative electrode chamber centered on an insulator and strong ion permeability membrane, and for the electrolysis of water in each electrode chamber of the electrolytic cell 100. It is formed of an electrode plate 200,

The electrolyzer 100 is formed in a rectangular parallelepiped form as high as the height (h) at a noticeable ratio compared to the width (b) and width (w) as shown in FIG.

The electrolyzer 100 as described above is divided into a positive electrode chamber 102 and a negative electrode chamber 103 by an insulator and excellent ion permeability as shown in FIGS. 3 and 4,

The diaphragm 101 interposed for the separation of the electrode chambers 102 and 103 is inserted and fixed in the electrolytic cell 100 to maximize ion permeability through maintaining a constant surface tension and to prevent flow by the power line.

To this end, the channel type recess groove 104 having a cross-sectional shape of the shape of a substantially 'Τ' is formed on the inner wall of the case of the electrolytic cell 100, and the diaphragm 101 corresponding thereto has a cross-sectional shape of 'Ι' shape. It forms the fixed structure of the body.

The positive electrode chamber 102 and the negative electrode chamber 103 separated by the diaphragm 101 formed as described above are interposed with each electrode plate assembly 200 for supplying power required for electrolysis of water.

The electrode plate assembly 200 is formed of a plate-like metal member of a thin plate, which is a high conductor such as stainless steel and titanium, as shown in FIGS. 3, 4, and 5 to correspond to the height h of the electrolytic cell 100. Is fixed close to the inner wall of the electrolytic cell (100),

On the other side;

The shape is roughly iron, and a plurality of separators 201 made of the same material as the electrode plate 200 are mounted at equal intervals in the vertical direction.

The electrode plate assembly 200 as described above is separated into the positive electrode plate 202 and the negative electrode plate 203, and centers the diaphragm 101 at a position close to the positive electrode chamber 102 and the negative electrode chamber 103 in the electrolytic cell 100. Mounted symmetrically with each other,

For this reason, in order to prevent the interference phenomenon of the current through the front end of the separate 201, the protrusion 204 of the electric field 1 is further provided with a cover 205 of the insulating material.

In addition, the electrode plate assembly 200 has a flat plate shape in the recessed portion 206 of the separator 201 adjacent to the discharge port 300 so that the electrolyzed water can be smoothly discharged when mounted in the electrolytic cell 100 as shown in FIG. 5. A diaphragm 207 is further provided to facilitate the discharge of the electrolyzed water.

Referring to the operation state of the present invention as described above compared with the problems of the conventional configuration as follows.

First, the electrolyzed water generating device fills the initial water by supplying raw water into the positive electrode chamber 102 and the negative electrode chamber 103 separated by the diaphragm 101 through the raw water inlet pipe located at the bottom of the electrolytic cell,

At this time, a small amount of salt and potassium sulfate are added to facilitate the electrolytic performance to facilitate the generation of strong electrolytic water.

Then, the electrode plate assembly 200 interposed in each of the electrode chambers 102 and 103 is energized with a constant current and voltage through the rectifier to perform electrolysis of water.

At the same time as the electrolysis is carried out as described above, strong acidic water is generated in the positive electrode chamber 102 and strong alkaline water is generated in the negative electrode chamber 103.

The generated strong seawater flows between the phases of the separator 201 and finally discharges smoothly with the help of the diaphragm 207 of the separator 201 adjacent to the discharge port 300 to generate the strong seawater.

As described above, the generation and the electrolytic concentration of the electrolyzed water due to the separator 201 interposed in the electrode plate are superior to those of the conventional plate or rod-shaped electrode plate.

Whereas conventionally 100 liters of raw water is electrolyzed to produce about 34 ml of strong acidic and strong alkaline water,

Electrolytic device using the electrode plate assembly 200 is interposed the separator 201 of the present invention;

When electrolyzing about 100 liters of raw water, strong acidic water and strong alkaline water each produce about 6 liters, which is a significant change in production.

In addition, a large amount of additives such as salt and potassium chloride were required to generate conventional strong seawater.

The electrolyzed water generating device to which the present invention is applied has an advantage of deriving the same pH value of the electrolyzed water as the conventional potassium sulfate at a low price rather than a very small amount of salt and expensive potassium chloride.

This series of electrolytic water generation operations can be achieved by contacting the electrode plate assembly 200 interposed in each electrode chamber 102 and 103 with the maximum contact area in a limited space of the electrolyzer.

In particular, a plurality of separate 201 mounted at equal intervals through the electrode plate assembly 200 or by welding or the like to maximize the contact area with the raw water,

It is possible to solve problems such as the complexity of the configuration due to the stacking of the conventional flat electrode plate and the decrease in electrolytic performance due to current interference.

The electrolytic water generating device of the present invention as described above ultimately aims to improve the contact area between the electrode plate assembly 200 and the raw water to generate strong electrolytic water,

In addition to the above-described configuration, as shown in FIG. 6, the electrolytic cell case 400 is formed in a columnar shape having a maximum cross-sectional area among various figures.

Inwardly, the diaphragm 401 and the electrode plate 402 which are excellent in ion permeability are mounted concentrically for the isolation structure of an electrode chamber.

The columnar electrolytic cell is to utilize the case 400 itself as an electrode plate 402, the inner wall of the separator 403 of a conductor having a predetermined width in a spiral (spiral) shape,

In the electrode chamber 404 separated by the diaphragm 401, a cylindrical electrode plate 402 having a shape corresponding to the case 400 is provided on the outer periphery of the separator 403.

The columnar electrolytic cell has an advantage of easily generating the above-mentioned strong electrolytic water by maximizing the contact area between the raw water and the electrode plate 402.

The strong electric water generating apparatus of the present invention as described above is a useful design capable of miniaturizing the electrolytic water generating apparatus by greatly simplifying the configuration and reducing the maintenance cost for generating the strong electric water, thereby increasing the amount of generated strong electric water.

Claims (2)

An electrolytic cell 100 divided into a positive electrode chamber 102 and a negative electrode chamber 103 around the diaphragm 101 having an insulator and strong ion permeability; In the electrolytic water generating device via the electrode plate 200 for the electrolysis of water in each electrode chamber (102, 103) of the electrolytic cell (100); The electrolyzer 100 has a rectangular parallelepiped shape having a height h at a sharp rate compared to the width b and the width w. On the inner wall of the electrolytic cell 100, a channel type recess groove 104 having a cross-sectional shape of approximately 'Τ' is formed, The diaphragm 101 is inserted and fixed through the concave groove 104 so as to have a cross-sectional shape of 'Ι' shape, and thus, a fastening structure of the male body is promoted. In the positive electrode chamber 102 and the negative electrode chamber 103 separated by the diaphragm 101, Corresponding to the height (h) of the electrolytic cell 100, a plate-like metal member of a thin plate is a high conductor such as stainless and titanium, one side is closely fixed to the inner wall of the electrolytic cell 100, On the other side; Strong electric water, characterized in that the shape of the iron plate to accommodate the electrode plate assembly with a plurality of equal intervals in the vertical direction (separate 201) provided with the same material as the electrode plate 200 in a substantially iron shape Generating device. The method of claim 1; Separation 201 of the electrode plate assembly 200; In order to prevent current interference between the positive electrode plate and the negative electrode plate which are mounted in close proximity, the protrusion 204 further includes a cover 205 of an insulating material on the electric field l. A separate plate 201 is provided at the recess 206 adjacent to the discharge port 300 so as to be orthogonal to the mounting direction of the separator 201. Strong electric water generating device, characterized in that configured to discharge the electrolyzed electrolytic water smoothly.