KR100458604B1 - Electrolyzed Oxidizer water - Google Patents

Abstract

The present invention relates to an electrolytic oxidizer generating apparatus that is capable of water treatment, and more particularly, first and second electrode plates (1) (2) to which DC electricity is applied; An electrolytic cell 10 in which the first electrode plate 1 and the second electrode plate 2 are fixed such that a flow path 11 is formed therebetween; A first inflow hole 20 and a first outflow hole 14 formed at a predetermined interval in the electrolytic cell 10 on the first electrode plate 1 side; A second inflow hole 20 and a second outflow hole 21 formed at predetermined intervals in the electrolytic cell 10 on the second electrode plate 2 side; The first upper channel 15 connecting the first inlet 13 and the channel 31 and the first outlet hole 14 and the channel 11 are formed in the electrolytic cell 10. The first lower passage 16, the second upper inflow passage 23 connecting the second inflow hole 20 and the flow passage 11, and the second lower connection connecting the second outlet hole 21 and the flow passage 11. By constructing the system including the flow path 24, the electrolytic oxidant generated by electrolysis is applied by applying direct current electricity when water (tap water, ground water) passes through the electrolytic cell for the purpose of purification of water, sewage, water purification plant, swimming pool, lake, etc. The present invention relates to an electrolytic oxidizer generating device that can be subjected to water treatment.

Description

Electrolytic Oxidizer Generator {Electrolyzed Oxidizer Water}

The present invention relates to a generating device for producing an electrolytic oxidizer, and more particularly, water and sewage, water purification plants, swimming pools, lakes, etc. generated by electrolysis by applying direct current electricity when water passes through the electrolytic cell for the purpose of purification. The present invention relates to an electrolytic oxidizer generating device invented to perform water treatment using an electrolytic oxidant.

The electrolytic oxidizing agent means water containing hydrogen ions and hydroxyl ions, and typically, the electrolytic oxidizing agent is generated by inducing electrolysis through direct current electricity to an electrode contained in raw water.

The electrolytic oxidizer produced by the present invention is a device for producing a complex oxidant containing chlorine-based oxidation and ozone, and can function as a disinfection process in various water treatment fields such as water and sewage, water purification plant, swimming pool, and lake purification.

In addition, the alkaline water of the electrolyzed water is very useful for the human body when drinking because of its nature is also used for the treatment of gastrointestinal diseases, high blood pressure, diabetes, neuralgia, and the like. In addition, strong alkaline water is used to promote the growth of crops, improve soil, and to clean soiled objects without the use of synthetic detergents. In addition, acidic water is widely used for sterilization, medical water, sterilization water, food manufacturing process sterilization, odor removal of livestock, disinfection sterilization. In addition, many studies on the application fields of acidic water and alkaline water have been conducted, and accordingly, the demand for electrolytic oxidants is increasing. Therefore, various electrolytic water generating apparatuses for effectively preparing electrolytic oxidants have been researched and developed.

The conventional water treatment apparatus stores raw water in a fresh water tank, and the stored water is stirred by adding chemicals in a stirring tank connected to a plurality of chemical tanks, flowing the chemical and stirred raw water back into the coagulation tank, and then adding a flocculant so that the sludge is aggregated. do.

The condensed water is discharged to the outside through the filtration device, and the sludge is incinerated or landfilled by a cake in a separate treatment facility. There was a problem of generating another water pollution.

The present invention has been invented to solve such a problem, and an object of the present invention is to provide an electrolytic oxidizer generating apparatus capable of effectively producing an electrolytic oxidant and to treat water to prevent secondary environmental pollution and to efficiently treat the water.

An electrolytic oxidant generating device of the present invention includes: first and second electrode plates to which DC electricity is applied;

An electrolytic cell in which the first electrode plate and the second electrode plate are fixed such that a flow path is formed therebetween;

A first inflow hole and a first outflow hole formed at a predetermined interval in the electrolytic cell on the side of the first electrode plate; A second inflow hole and a second outflow hole formed at a predetermined interval in the electrolytic cell on the second electrode plate side; A first upper flow path connecting the first inflow hole and the flow path; A first lower passage connecting the first outlet hole and the passage; The structure includes a second upper flow passage connecting the second inflow hole and the flow path, and a second lower flow passage connecting the second outflow hole and the flow passage, and the present invention provides a relatively simple structure in which a large amount of acidic water and alkali water are used. It is to provide an electrolytic oxidizer generating device that can be continuously processed.

1 is a perspective view of an electrolytic oxidizer generating device according to the present invention.

2 is an exploded perspective view of the electrolytic oxidizer generating device of FIG.

3 is a cross-sectional view of a fluid flow of the electrolytic oxidizer generating device of FIG.

Figure 4 is an installation configuration and overall flow process of the electrolytic oxidizer generating apparatus of the present invention.

<Description of Signs of Major Parts of Drawings>

1,2: First and second pole plates 3,4: Fixing bolt

5: fixing nut 10: electrolytic cell

11: Euro 12: First Electrolyte

13: 1st inflow hole 14: 1st inflow hole

15: the first upper euro 16: the first lower euro

17,18: through hole 19: second electrolytic cell

20: second inflow hole 21: second inflow hole

22: fitting home 23: second business euro

24: Second Lower Passage

Hereinafter, on the basis of the accompanying drawings will be described in detail the invention.

An electrolytic oxidizer generating apparatus includes: first and second electrode plates (1) and (2) to which DC electricity is applied;

An electrolytic cell 10 in which the first electrode plate 1 and the second electrode plate 2 are fixed such that a flow path 11 is formed therebetween;

A first inlet hole 13 and a first outlet hole 14 formed at a predetermined interval in the electrolytic cell 10 on the side of the first electrode plate 1;

A second inflow hole 20 and a second outflow hole 23 formed at a predetermined interval in the electrolytic cell 10 on the second electrode plate 2 side;

The first upper flow passage 15 is formed in the electrolytic cell 10 and connects the first inflow hole 13 and the flow passage 11. A first lower passage 16 connecting the first outlet 14 and the passage 11;

A second upper flow passage 23 connecting the second inflow hole 20 and the flow passage 11, and a second lower flow passage 16 connecting the second outlet hole 21 and the flow passage 11. Characterized in that comprises a configuration.

In the present invention, the electrolytic cell 10 is composed of first and second electrolytic cell 12, 19 of mutually complementary shape,

The first inflow hole 13, the first outflow hole 14, the first upper and lower flow paths 15 and 16 are formed in the first electrolytic cell 12, and the second electrolytic cell 19 is formed in the first electrolytic cell 12. The second inflow hole 20, the second outflow hole 21, and the second upper and lower flow paths 23 and 24 are formed.

In the present invention, a plurality of fixing bolts 3 and 4 are formed on the first and second electrode plates 1 and 2, and the first and second electrolytic baths 12 and 19 are formed.

Next, with reference to the accompanying drawings will be described in detail a preferred embodiment of the electrolytic oxidizer generating apparatus according to the present invention.

1 is a perspective view of an electrolytic oxidant generating device according to the present invention, FIG. 2 is an exploded perspective view of the electrolytic oxidant generating device of FIG. 1, FIG. Shows the installation configuration and overall flow process diagram of the electrolytic oxidizer generating apparatus of the present invention.

The electrolytic oxidant generator of the present invention is composed of first and second electrode plates (1) and (2) to which DC power is applied, and an electrolytic cell (10) in which the first and second electrode plates (1) and (2) are provided.

Each of the first and second pole plates 1 and 2 has a rectangular plate shape, and the material of the first and second pole plates 1 and 2 is plated with platinum, platinum series, iridium, and platinum + iridium on a titanium plate. Each of the first and second pole plates 1 and 2 is provided with a plurality of fixing bolts. In this embodiment, five fixing bolts 3 and 4 are formed. The flow path 11 is formed between the first and second electrode plates 1 and 2 by a predetermined interval.

The electrolytic cell 10 is provided with first and second electrode plates 1 and 2, and includes a first electrolytic cell 12 to which the first electrode plate 1 is fixed, and a second electrolytic cell to which the second electrode plate 2 is fixed. It consists of 19. The first and second electrolytic baths 12 and 19 form a complementary shape.

In the first electrolyte tank 12, a first inlet hole 13 through which fluid flows in and a first outlet hole 14 through which fluid flows out are formed at predetermined intervals, and the first electrode plate 1 is fitted therein. Grooves are formed.

In addition, a first upper flow passage 15 connecting the first inflow hole 14 and the flow passage 11 and a first connection hole connecting the first outflow hole 14 and the flow passage 11 to the first electrolyte tank 12. The lower flow path 16 is formed.

Here, the shapes of the first upper and lower flow paths 15 and 16 form a triangular shape as a whole. In the first electrolytic bath 12, five through holes 18 through which the fixing bolts 5 of the first electrode plate 1 pass are formed.

In the second electrolytic bath 19, the second inflow hole 20 through which the fluid flows in and the second outflow hole 21 through which the fluid flows out are formed at predetermined intervals, and the second electrode plate 2 is inserted therein. The fitting groove 22 is formed.

In addition, the second electrolytic tank 19 has a second upper flow passage 23 connecting the second inflow hole 20 and the flow passage 11, and a second connecting the second outflow hole 21 and the flow passage 11. The lower flow passage 24 is formed. Here, the shape of the second phase, the lower flow paths 23 and 24 has a triangular shape as shown in FIG. 2. In addition, five through holes 18 through which the fixing bolts 5 of the second electrode plate 2 pass are formed in the second electrolytic cell 19.

Here, the fixing bolts 11 and 21 of the first and second pole plates 10 and 20 are evenly distributed and fixed to each pole plate.

The fixing bolts 11 and 21 are penetrated through the through holes of the first and second electrolytic baths 12 and 19, respectively, and then coupled to the fixing nuts 5, thereby allowing the first and second electrode plates 1 and 2 to pass through. ) Is firmly fixed to and attached to the first and second electrolytic baths at regular intervals therebetween. By doing so, the interval of the flow path is kept constant even as time passes.

Here, the first and second electrolytic baths 12 and 19 are assembled with mutual bolt nuts, but this is only the following embodiment, and of course, the first and second electrolytic baths may be integrally formed.

In addition, a sealing bracket for sealing may be interposed between each of the first and second electrolytic baths 12 and 19, and also between each of the fixing bolts 3 and 4 and the through holes 18. Of course, the sealing ring may be interposed.

Referring to the operation of the electrolytic oxidizer generating device of the above structure is as follows.

As shown in FIG. 3, raw water is supplied through the first and second inflow holes 13 and 20 while the DC power is applied to the first and second electrode plates 1 and 2. Then, the raw water passes through the first and second upper flow passages 15 and 23 and the passage 11 and the first and second lower flow passages 16 and 24, respectively. Each one is discharged through 21). That is, as shown in Fig. 3, the raw water introduced into A exits to the upper one side A ', and the raw water introduced into B exits to the upper other side B'.

When DC electricity is applied to the first and second electrode plates 1 and 2, a chemical reaction occurs in the flow path 11 by an electric action, and acidic water containing hydrogen ions (H +) is produced by electrical chemical action from raw water. And alkaline water containing hydroxyl ions (OH-) are produced.

If-electricity is applied to the first electrode plate 1 and + electricity is applied to the second electrode plate 2, a large amount of acidic water containing H + ions is present on the first electrode plate 1 side, and the second electrode plate 2 In the) side, a large number of alkaline water containing OH- ions are present. The acidic water thus generated is discharged through the first outlet hole 14, and the alkaline water is discharged through the second outlet hole 21.

Although the present invention has been described with reference to the above embodiments, this is only one embodiment, and those skilled in the art may implement various other embodiments therefrom.

4 is an installation and overall flow process diagram of the electrolytic oxidizer generating apparatus of the present invention, after the raw water passes through the water softener 40, the electrolyzer by the metering pump 42 through the salt water tank 41 depending on whether the pressure sensor is opened. It may be introduced into (10) or directly from the water softener (40) into the electrolytic cell.

After being electrolyzed in the electrolytic cell 10 and then desalted in the storage tank 43, the water is collected into the treated water storage tag 44 by the metering pump 42 'and flows out to the outside.

Figure 4 illustrates an example of the installation position of the electrolytic cell 10, it is noted that the electrolytic cell of the present invention does not necessarily have a water purification line in the same manner as in FIG.

The present invention thus constructed comprises an electrolytic oxidant generating apparatus having a first electrolytic bath having a first and a second electrode plate therein and a second electrolytic bath, so that a large amount of acidic and alkaline water can be continuously and effectively produced in a relatively simple structure. As a result, it is possible to treat more raw water without generating secondary environmental pollution.

Claims (3)

In the electrolytic oxidizer generating device, wherein the flow path 11 is formed by the first and second electrode plates 1 and 2 to which DC electricity is applied, and the first and second electrode plates 1 and 2, A plurality of fixing bolts 3 and 4 coupled to the first and second electrode plates 1 and 2; The first and second inlet holes 13 and 20 and the first outlet holes 14 and 21 are formed in a mutually complementary shape, and the through holes 17 and 18 through which the fixing bolts 3 and 4 pass are formed. An electrolytic cell 10 composed of first and second electrolytic baths 12 and 19; A first upper flow passage 15 connecting the flow passage 11 and the first inflow hole 13; A first lower flow passage 16 connecting the flow passage 11 and the first outlet hole 14; A second upper flow passage 23 connecting the flow passage 11 and the second inflow hole 20; Electrolytic oxidant generating device characterized in that it comprises a second lower passage (24) connecting the passage (11) and the second outlet hole (21). delete delete