KR20030062663A - An electrolytic liquid manufacturing device - Google Patents

Abstract

PURPOSE: A high efficiency electrolyzed water manufacturing device is provided to manufacture high efficiency strong acidic water and strong alkaline water during a short period of time in which water passes through electrolytic cells and easily remove impurities generated in the electrolytic cells as water is being electrolyzed. CONSTITUTION: The high efficiency electrolyzed water manufacturing device comprises a main body(100) on the upper part of which electrolytic cells(150) are formed as they are extended zigzag so that the electrolytic cells are alternated to each other in a semicircular shape, and which is consisted of lower plate, upper plate and intermediate plate; a positive electrode(500) fixed to an electrode fixture(140) formed on the upper plate inside the electrolytic cells formed in a circular shape by the upper plate and intermediate plate; a negative electrode(600) fixed to an electrode fixture formed on the lower plate inside the electrolytic cells formed in a circular shape by the lower plate and intermediate plate; cleaning means(320) respectively inserted into the electrolytic cells formed in a circular shape as the upper plate, intermediate plate and lower plate formed in a semicircular shape are being united with each other; motive gears(210) formed on the center of a part where the electrolytic cells are bent to rotate the cleaning means inserted into the electrolytic cells respectively; a motor(200) for rotating any one motive gear in a plurality of motive gears fixed to one side of the main body to rotate the cleaning means; and a metal element(400) filled in the electrolytic cells into which the cleaning means rotated by the motive gears of the motor are inserted.

Description

An electrolytic liquid manufacturing device

The present invention relates to an electrolytic water production apparatus for generating acidic water and alkaline water through electrolysis, and more particularly, to a high efficiency electrolytic water production apparatus capable of continuously producing highly efficient strong acidic and strong alkaline water.

The electrolyzed water divided into acidic water and alkaline water is divided according to pH concentration, and the pure neutral water is pH 7, and if it is smaller than this, it is classified as acidic, and if it is greater than 7, it is classified as alkaline. The concentration is around 11.5 and it is divided into strong acid and strong alkaline water.

In this case, the pH refers to the hydrogen ion index, the acidic acid and the alkaline water as described above are manufactured by flowing an inorganic or organic aqueous solution containing an electrolyte between the electrodes through the electrolysis as is known and used where necessary in industry have.

Electrolyzed water production apparatus that electrolyzes into acidic water and alkaline water, as is known, is located in the center of the insulator and the permeability and ion-transmitting diaphragm in the center, and divided into the anode chamber and the cathode chamber with the center of the positive electrode and the negative electrode inside each By energizing and electrolyzing, strongly acidic electrolyzed water is produced in the anode chamber and strongly alkaline electrolyzed water is used in the cathode chamber.

However, since alkaline water and acidic water generated by the above method are produced by electrolysis of water at a short time passing through the electrolytic chamber, pH concentration is difficult to be generated by strong acidic and strong alkaline water, and strong acidic and strong alkaline water It takes a long time because the electrolysis must be performed for a long time to produce.

The present invention has been made to solve the above problems, it is to provide a high efficiency electrolytic water production apparatus for producing a high efficiency strong acidic water and strong alkaline water in a short time when water passes through the electrolytic chamber.

The present invention is to provide a high efficiency electrolytic water production apparatus that can easily remove impurities generated in the electrolytic chamber as the water is electrolyzed.

High efficiency electrolytic water production apparatus according to the present invention for achieving this purpose, the electrolytic chamber is formed while extending in a zigzag staggered with each other in a semicircular shape on the top, the upper part of the lower plate is formed in the bending portion of the electrolytic chamber is formed in a zigzag An electrolytic chamber corresponding to the electrolytic chamber formed on the upper portion of the lower plate is formed in the upper and lower portions, a hole is formed in a portion where the electrolytic chamber is bent, and an intermediate plate to which the ion permeable membrane is fixed is fixed. A main body including a top plate having a corresponding electrolytic chamber and an electrode fixing tool formed on a lower side thereof;

A positive electrode fixed to an electrode fixture formed on the upper plate in an electrolytic chamber formed circularly by the upper plate and the intermediate plate;

A negative electrode fixed to an electrode fixture formed on the lower plate in an electrolytic chamber formed circularly by the lower plate and the intermediate plate;

Upper and middle plates and lower plates formed in a semicircular shape and washing means respectively inserted into the electrolytic chambers formed in a circular shape;

A driving gear which is formed at the center of the bending portion of the electrolytic chamber and rotates the cleaning means respectively inserted into the electrolytic chamber;

A motor fixed to one side of the main body to rotate any one of the plurality of motive gears for rotating the washing means;

It characterized in that it comprises a metal piece that is filled in the electrolytic chamber is inserted into the cleaning means is rotated by the motor gear of the motor.

1 is an exploded perspective view schematically showing a main body in which an electrolytic chamber is applied to the present invention.

Figure 2 is a shear cross-sectional view schematically showing a preferred embodiment of the high efficiency electrolytic water production apparatus according to the present invention.

Figure 3 is a plan view schematically showing a preferred embodiment of the high efficiency electrolytic water production apparatus according to the present invention.

Figure 4 is a side cross-sectional view schematically showing a preferred embodiment of the high efficiency electrolytic water production apparatus according to the present invention.

Figure 5 is a perspective view schematically showing the cleaning means for removing impurities generated in the metal piece is fixed in the electrolytic chamber of the main body applied to the present invention stored in the electrolytic chamber.

Figure 6 is a cross-sectional view schematically showing a washing hole of the washing means applied to the present invention.

Figure 7 is an enlarged perspective view schematically showing a preferred embodiment of a metal piece filled in the electrolytic chamber formed in the main body of the present invention.

Hereinafter, a preferred embodiment of a high efficiency electrolytic water production apparatus according to the present invention will be described in detail with reference to the drawings.

First, a preferred embodiment of the high-efficiency electrolytic water production apparatus according to the present invention is the body 100 of the electrolytic water production apparatus as shown in Figure 1 is formed of a lower plate 130 and the intermediate plate 120 and the upper plate 110, the The lower plate 130, the intermediate plate 120, and the upper plate 110 are combined to form the main body 100.

In the upper side of the lower plate 130 coupled to the intermediate plate 120, a semicircular electrolytic chamber 150 is staggered as shown in FIGS. 1 and 2, and both ends of the electrolytic chamber 150 are main body. It is connected to the inlet 160 and the outlet 170 formed on one side of the lower plate 130 of the (100).

The electrode fixing tool 140 is formed to protrude in the bending portion of the electrolytic chamber 150 which is formed in a semicircle staggered shape in the upper portion of the lower plate 130.

The negative electrode 600 is fixed to the electrode fixing tool 140 which is formed to protrude in a bending portion of the electrolytic chamber 150.

The upper part of the lower plate 130 on which the negative electrode 600 is fixed to the electrode fixing tool 140 protruding from the electrolytic chamber 150 formed on the upper side, the electrolytic chamber 150 and the inlet formed on the upper side of the lower plate 130 ( The electrolytic chamber 150 corresponding to the 160 and the outlet 170 forms an intermediate plate 120 formed at an upper portion and a lower portion thereof.

The electrolytic chamber 150 penetrates the portion where the electrolytic chamber 150 of the intermediate plate 120 is formed in the upper and lower portions of the intermediate plate 120 having the electrolytic chamber 150 formed in a shape corresponding to the electrolytic chamber 150 of the lower plate 130. A hole 121 is formed.

In the upper portion of the intermediate plate 120 in which the hole 121 is formed at the bending portion of the electrolytic chamber 150, the electrolytic chamber 150 and the electrode fixing tool 140 formed at the upper portion of the lower plate 130 correspond to the lower portion. The upper plate 110 is formed to combine the upper plate 110 with the intermediate plate 120 and the lower plate 130 to form the main body 100, and protrude downward from the electrolytic chamber 150 of the upper plate 110. The positive electrode 500 is fixed to the electrode fixing tool 140.

Since the lower part of the upper plate 110 and the upper and lower portions of the intermediate plate 120 and the lower plate 130 formed in a semi-circular shape are formed to correspond to each other, the main body 100 is coupled to each other. When the electrolytic chamber 150 is formed in a circular shape, the electrolytic chamber 150 is formed in the upper and lower portions of the main body 100.

As the upper plate 110 and the intermediate plate 120 and the lower plate 130 are combined, the upper plate 110 and the lower plate are inside the electrolytic chamber 150 of the main body 100 in which the circular electrolytic chamber 150 is formed at the upper and lower portions thereof. The positive electrode 500 and the negative electrode 600 are fixed to the electrode fixing tool 140 protruding from the electrolytic chamber 150 of 130 so that one side is used as the negative electrode chamber and the other side is used as the positive electrode chamber.

In the electrolytic chamber 150 formed by the upper plate 110, the intermediate plate 120, and the lower plate 130, the negative electrode 600 and the positive electrode 500 are electrolytic chamber 150 of the upper plate 110 and the lower plate 130. In the electrolytic chamber 150 of the main body 100, which is fixed to the electrode fixing tool 140 formed in the negative electrode chamber and the positive electrode chamber, as shown in FIGS. 2 and 3, the electrolytic chamber 150 is staggered in a staggered manner. The rotatable gears 210 are rotatably fixed to each other.

The motor 200 for rotating any one of the motive gears 210 is fixed to one side of the main body 100 in which the motive gears 210 are formed in the middle of the bending portions of both electrolytic chambers 150. .

The cleaning means 300 is fixed to both electrolytic chambers 150 of the main body 100 in which the motive gear 210 is rotated by the motor 200 formed on one side of the main body 100.

The cleaning means 300 fixed inside the electrolytic chamber 150 of the main body 100 forms gears 310 at both ends as shown in FIG. 5 so that the cleaning means 300 is fixed to the electrolytic chamber 150. When the gear 310 is formed at both ends of the cleaning means 300 is engaged with the motive gear 210, the motor 200 rotates the motive gear 210, the cleaning means 300 by the gear 310 Form to rotate together.

As shown in FIGS. 5 and 6 between the gear 310 and the gear 310, the washing means 300 having the gear 310 rotating therein with the motive gear 210 rotating by the motor 200 is formed. It forms a washing hole 320 having a different height, the electrode through the groove 330 so that the negative electrode 600 or the positive electrode 500 penetrates in the center of the gear 310 and the washing hole 320 of the washing means 300 To form.

As shown in FIG. 7 in the circular electrolytic chamber 150 in which the upper plate 110, the intermediate plate 120, and the lower plate 130 having the semi-circular electrolytic chamber 150 are combined, and the cleaning means 300 is fixed. The same metal piece 400 is filled.

The metal piece 400 filled in the electrolytic chamber 150 of the main body 100 is formed of nickel in the electrolytic chamber 150 to which the positive electrode 500 is fixed, and titanium in the electrolytic chamber 150 to which the negative electrode 600 is fixed. Most preferably.

The present invention made of the configuration as described above is a semi-circular electrolytic chamber 150 is formed with the upper plate 110 and the intermediate plate 120 and the lower plate 130 is coupled to the main body formed in the upper and lower circular electrolyte chamber 150 One of the positive electrode 500 is fixed to the inside of the electrolytic chamber 150 of 100 and the negative electrode 600 is fixed to the opposite side of the electrolytic chamber 150. The positive electrode 500 is fixed to the inside of the electrolytic chamber 150. Since the metal piece 400 is filled and the metal piece 400 formed of titanium is formed inside the electrolytic chamber 150 to which the negative electrode 600 is fixed, current of the electrode is transmitted to the metal piece 400.

As described above, since both the positive electrode 500 and the negative electrode 600 fixed to the electrode holder 140 in the both electrolytic chambers 150 of the main body 100 flow through the metal piece 400, water flows from both sides of the main body 100. When the negative electrode 600 and the positive electrode 500 are introduced into the inlet 160 of the electrolytic chamber 150 formed in the metal piece 400, the contact area is maximized to increase the efficiency of the electrolytic reaction.

The water moved along the electrolytic chamber 150 zigzagly and staggered while the contact area with the electrode is maximized by the metal piece 400 filled in the electrolytic chamber 150, as shown in FIG. 1. The electrolytic chamber 150 produces high quality electrolytic water while moving between the electrolytic chamber 150 through the hole 121 formed in the portion where the electrolytic chamber 150 is bent and the ion permeable membrane 122 formed in the hole 121. Is discharged to the outlet 170 formed on the opposite side of the inlet 160.

When the water is introduced into the inlet 160 of the electrolytic chamber 150 and the water is discharged to the outlet 170, the water is formed in a staggered staggered manner in the electrolytic chamber 150, and a metal piece 400 is formed inside the electrolytic chamber 150. Since it is formed to maximize the contact area with the electrode, and extends the length of the electrolytic chamber 150, it is possible to continuously produce high-efficiency strong alkali water and strong acidic water.

As described above, while the electrolytic water is produced while maximizing the contact area with the electrode by the metal piece 400 filled in the electrolytic chamber 150, impurities are generated in the metal piece 400.

When a large amount of impurities are generated in the metal piece 400 while producing the electrolytic water, power is applied to the motor 200 formed on one side of the main body 100 to operate.

When power is applied to the motor 200, the motive gear 210 connected to the motor 200 as shown in FIG. 2 rotates.

When the prime mover 210 is rotated by the motor 200, as shown in FIGS. 2 and 3, the gear 310 of the wash unit 300 connected to the prime mover 210 rotates, and the wash unit 300 is rotated. When the gear 310 is rotated by the motive gear 210, connecting the two gears 310, as shown in Figure 6 so that the washing holes 320 of different heights to rotate the metal pieces 400 to hit each other While washing off the impurities while cleaning to keep the interior of the electrolytic chamber 150 always clean.

As described above, when the cleaning means 300 is rotated by the motive gear 210 in the interior of the electrolytic chamber 150, the positive electrode 500 and the negative electrode fixed by the electrode holder 140 inside the electrolytic chamber 150 ( 600 is fixed to penetrate through the electrode through hole 330 formed in the center of the gear 310 and the cleaning hole 320 of the cleaning means 300, even if the cleaning means 300, the electrode is electrolytic chamber ( It does not deviate from the center of 150).

In the above description of the preferred embodiment of the high-efficiency electrolytic water production apparatus according to the present invention, the present invention is not limited to this, but the present invention is not limited to the claims and the detailed description of the invention and various modifications to be carried out within the scope of the accompanying drawings It is possible and this also belongs to the present invention.

The present invention is formed in a zigzag form in which the water passing through the zigzag form alternately to each other, the water passes through the electrolytic chamber as long as possible, inserting a metal piece to maximize the contact area of the water with the electrode inside the electrolytic chamber. By providing a high efficiency strong acidic water and strong alkaline water in a short time can be provided.

In the present invention, since water is electrolyzed in an electrolytic chamber into which metal pieces are inserted, impurities attached to the metal pieces are removed while the metal pieces collide with each other by the rotation of the cleaning means, so that the electrolytic chamber is decomposed to remove impurities generated in the electrolytic chamber. The effect of eliminating the hassle should be provided.

Claims (4)

The electrolytic chamber is formed while extending in a zig-zag alternately with each other in a semicircular shape on the top, and the electrolytic chamber corresponding to the electrolytic chamber formed on the upper part of the lower plate is formed on the upper part of the lower plate on which the electrode fixing tool is formed at the bending portion of the electrolytic chamber formed by the zigzag. A main plate formed at a lower portion of the lower plate and having a hole formed at a portion at which the electrolytic chamber is bent to fix an intermediate plate to which the ion permeable membrane is fixed, and an upper plate formed at an upper portion of the intermediate plate having an electrolytic chamber corresponding to the lower plate and an electrode fixing tool at the lower portion thereof; A positive electrode fixed to an electrode fixture formed on the upper plate in an electrolytic chamber formed circularly by the upper plate and the intermediate plate; A negative electrode fixed to an electrode fixture formed on the lower plate in an electrolytic chamber formed circularly by the lower plate and the intermediate plate; Upper and middle plates and lower plates formed in a semicircular shape and washing means respectively inserted into the electrolytic chambers formed in a circular shape; A driving gear which is formed at the center of the bending portion of the electrolytic chamber and rotates the cleaning means respectively inserted into the electrolytic chamber; A motor fixed to one side of the main body to rotate any one of the plurality of motive gears for rotating the washing means; A high efficiency electrolyzed water production apparatus comprising a metal piece filled in an electrolytic chamber into which a washing means rotated by a motor gear of a motor is inserted. The method of claim 1; The washing means includes a gear formed at both ends and rotated by the motive gear; A plurality of washing holes formed at different heights between the gears formed at both ends; High efficiency electrolyzed water production apparatus, characterized in that formed in the center of the cleaning port and the gear is made of an electrode through groove through which the electrode passes. The method of claim 1; The high-efficiency electrolyzed water production apparatus, characterized in that the metal piece is formed by the upper plate and the intermediate plate is filled in the electrolytic chamber in which the positive electrode is fixed. The method of claim 1; The metal piece is formed by the lower plate and the intermediate plate is filled in the electrolytic chamber in which the negative electrode is fixed, high efficiency electrolytic water production apparatus, characterized in that formed of titanium.