KR20050100092A - Ozone apparatus to connect electrolysis-core in parallel - Google Patents

Abstract

In the present invention, in generating ozone by electrolysis in water, a plurality of electrolysis generating cores are connected in parallel to generate an amount of ozone maintained at an appropriate concentration in any characteristic of water.

The present invention provides an ozone generator for generating ozone by electrolysis in water, comprising: an inlet for introducing external raw water into the ozone generator; An electrolysis generating core wound around the frame in parallel with spaced apart at regular intervals in the same direction with platinum wires consisting of anode and cathode wires; Barrier ribs having a plurality of through holes formed densely between electrolysis generating cores connected in plural in parallel; A cover for forming a (+) and (-) electrode to supply power to a plurality of electrolysis generating cores connected in parallel in the ozone generator; It relates to an ozone generator in which the electrolysis generating core consisting of a discharge port formed in a predetermined position to cover the ozone water and the hydrogen gas generated by the electrolysis reaction by the electrolysis generating core to the outside.

Description

Ozone apparatus to connect electrolysis-core in parallel}

The present invention relates to an ozone generator in which the electrolysis generating cores are connected in parallel. More specifically, the electrolysis generating cores which generate ozone by generating electrolysis in water in the ozone generator are connected in parallel to a certain number and contained in water. It is possible to maintain a constant concentration of ozone without being limited by the amount of electrolyte or the amount of outflow per minute, and the platinum wire is wound on the frame of the electrolysis generating core, with the anode and cathode wires spaced at a constant interval in the same direction. The present invention relates to an ozone generator in which an electrolysis generating core is connected in parallel so as to maximize the generation of ozone by maximizing a counter contact area with water during the electrolysis reaction between the pole and the pole.

In general, ozone is a colorless gas with a characteristic smell as an isotope of oxygen. It is blackish blue in liquid and dark purple in solid. It has strong sterilizing and disinfecting properties. It is used to oxidize residual pesticides, especially for disinfecting kitchen and baby products, and plays an important role in filtering out harmful substances and substances in the air in nature. This ozone is charged from around 1900 to the present. There is a lot of devices that artificially generate ozone by various pulse waves applied to the concentrated portion.

Ozone tends to disintegrate strongly during the release of thermal energy, although at lower temperatures of -120 ° C it is explosive and disintegrates, but at lower concentrations, for example, decomposition at room temperature is much slower. At the rate, the most important property of ozone is its strong oxidizing power, which can oxidize many chemical mixtures that do not react to oxygen, and these properties can be produced through numerous practical applications, especially water treatment. The oxidative power is used in drinking water, general water, swimming pool water and waste water.

Unlike chlorine, ozone does not leave any harmful residue when used as an oxidant, and it has strong sterilizing power to remove bacteria and virus bacteria, and also has strong bleaching power, tobacco smoke, other odorous gases, and various harmful organic substances. It has an excellent effect of making it harmless by reacting with organic substances.

There are two methods for preparing ozone water. The first method is to generate ozone by corona discharge using air as a raw material, and to mix the ozone-containing air in water so that ozone is dissolved in water. Since a blower that can be supplied and a microbubble generator that can dissolve ozonized air in water must be installed, ozone is generated well, but ozone is a gas, and when mixed with water to generate ozone water, it is not in contact with water. In addition, since ozone flows out of the water in a state of air bubbles, the concentration of ozone in the water is relatively low, and when the inhaled ozone gas is inhaled into the human body, the airway mucosa is damaged.

The second method is a method of directly generating ozone of molecular size in water, which can overcome the disadvantages of the ozone manufacturing technique by the corona discharge type, and the diaphragm using a solid polymer electrolyte according to the method of installing the counter electrode in water. There is a method and a membrane-free method without a solid polymer electrolyte.

In the case of the diaphragm method, there is a known technique for an electrode assembly in which a lead electrode is used as an anode, a platinum black electrode is used as a cathode, and a diaphragm made of a solid polymer electrolyte is inserted between the anode and the cathode. It is technically difficult to uniformly position the polymer electrolyte, and if a non-uniform phenomenon such as local overpressing occurs, the solid polymer electrolyte causes a rapid deterioration of life due to local degradation during electrolysis.

In the production of ozone by electrolysis, scale components are inevitably induced. To prevent this, the use of very pure water without divalent cation components, which can cause scales such as calcium and magnesium, is used. There is a problem of deterioration.

In the case of the non-diaphragm method, ozone is directly generated in water by installing one or more sets of counter electrodes using white metal metal in water and inducing a strong electric field by applying DC power to the counter electrodes. There is a problem that it is difficult to use practically to increase the power consumption and shorten the life of the electrode due to the high water electrolysis voltage for tap water and similar levels of water lacking the electrolyte required to flow the current.

Looking at the technical configuration of the underwater discharge generating core that generates ozone through electrolysis in the "Underwater discharge generating core and the underwater discharge generating device and the water treatment system using the same" of the patent application 2002-12527, which is solved the above problems A frame having a size larger than the body by the right and left supports in the X-axis direction and the left and right supports in the upper and lower portions in the Z-axis direction, respectively; A first conductive wire wound between the front part and the rear part in the Y-axis direction of the body; A second lead wound between the right support and the left support of the frame; First equipotential means for bringing the first conductor into the same potential state; A second equipotential means for bringing the second conductor into the same potential state, and positioned between the first conductor and the second conductor wound on the frame, between the body front portion and the back portion; It is configured to further comprise an insulated wire wound between the right support and the left support of the frame.

The above-described invention uses a platinum wire as an anode and a cathode by using water properties and uses water as a switching medium, and implements virtual mesh electrode points by winding platinum wires in a cross shape on a frame to realize self-destruction and self-healing of water. It is possible to generate free radicals and ozone through this continuously repeated underwater discharge, but due to the winding of the platinum wire in the cross shape on the frame, the adverse effect of increasing resistance is caused by the electrode points crossing the platinum wire. In case of electrolysis, the contact area with water is limited to the electrode points, and the efficiency of ozone generation is lowered. Also, the ozone concentration in the water during electrolysis is different according to the amount of electrolyte contained in the water or the quantity of outflow per minute. In the case of the above-listed invention, it depends on the amount of electrolyte in water or the amount of outflow per minute. There is a problem in that the concentration of the zone appears to reduce the utility of the product.

The present invention has been made to solve the above-mentioned conventional problems, by connecting a plurality of electrolysis generating cores in parallel in the ozone generator to maintain an appropriate concentration of ozone in any change of water, the frame of the electrolysis generating core The purpose is to maintain the positive and negative wires, which are the platinum wires wound in the phase, in parallel in a state spaced apart at regular intervals in the same direction to maximize the contact area with water during electrolysis and to minimize the resistance to improve the ozone generation efficiency. There is this.

In addition, it is an object of the present invention to freely control the interval between the platinum wire consisting of a cathode wire and a cathode wire wound on the frame, and to freely control the number of electrode wires wound on the frame to generate ozone The auxiliary support is formed in the middle part of the frame to prevent the platinum wire from being loosely stretched or pulled due to water pressure or the flow rate of water, and a plurality of holes are provided between the electrolysis generating cores connected in parallel. The purpose is to improve the generation efficiency of ozone during electrolysis by forming the formed partition wall so that the water pressure does not directly reach the electrode.

In the ozone generator for generating ozone by electrolysis in water to achieve the above object, an inlet for introducing external raw water into the ozone generator; An electrolysis generating core wound around the frame in parallel with spaced apart at regular intervals in the same direction with platinum wires consisting of anode and cathode wires; Barrier ribs having a plurality of through holes formed densely between electrolysis generating cores connected in plural in parallel; A cover for forming a (+) and (-) electrode to supply power to a plurality of electrolysis generating cores connected in parallel in the ozone generator; An ozone generator in which an electrolysis generating core consisting of a discharge port formed at a predetermined position on a cover to discharge ozone water and hydrogen gas generated by the electrolysis reaction by the electrolysis generating core to the outside is connected in parallel. will be.

Hereinafter, with reference to the drawings will be described in detail with respect to the ozone generator 40 in which the electrolysis generating core 43 is connected in parallel.

1 is an exploded perspective view of an ozone generator 40 applied to the present invention, FIG. 2 is a side view of the ozone generator 43 applied to the present invention, and FIG. 3 is an electrolysis generating core 43 applied to the present invention. 4 is an exploded perspective view of the frame 10 of FIG. 4, and FIG. 4 is a perspective view showing a state in which the first pole wire 11 is wound around the frame 10 of the electrolysis generating core 43 according to the present invention. Fig. 6 is a perspective view showing a state in which the first pole wire 11 and the second pole wire 12 are wound on the frame 10 of the electrolysis generating core 43 applied to the present invention. It is a side view which shows the state in which the 1st pole line 11 and the 2nd pole line 12 were wound in the frame 10 of the decomposition | disassembly generating core 43. As shown in FIG.

1 is an exploded perspective view of an ozone generator 40 applied to the present invention, and FIG. 2 is a side view of the ozone generator 43 applied to the present invention.

As shown in the present invention, a plurality of electrolysis generating cores 43 are formed in a parallel manner therein, and the partition 44 having a plurality of through holes 44a formed densely between the electrolysis generating cores 43 is formed. Formed to allow the raw water introduced through the inlet 41 to be discharged to the ozone water through the outlet 45, the cover 42 is formed by forming (+), (-) electrodes (42a, 42b) ozone generator Power is supplied to the electrolysis generating core 43 connected in parallel in 40 so that an electrolysis action can take place.

The electrolysis generating core 43 is parallel to the first pole 11, which is the anode line, and the second pole, 12, which is the cathode line, spaced apart at regular intervals in the same direction. It is designed to maximize the contact area with the electrode.In case of using electrolytically charged water or the amount of electrolyte contained in the water column, the ozone concentration can be maintained even under different conditions according to the quantity of outflow per minute. The same poles are connected in parallel to improve the lifespan, so that a plurality of the same poles are formed. A detailed description of the configuration of the electrolysis generating core 43 will be described below.

The partition wall 44 is formed between the electrolysis generating cores 43 connected in parallel, and the partition wall 44 is formed so that a plurality of through holes 44a are densely formed in the electrolysis generating core 43. The ozone water generated by the water can be easily penetrated, but the water is cooled from the bottom up to minimize the influence of the water pressure or the flow rate of the water directly on the electrode, thereby improving the ozone generating efficiency.

The inlet 41 is formed at a predetermined position of the ozone generator 40 so that raw water supplied from the outside is introduced into the ozone generator, and the outlet 45 is the upper portion of the ozone generator 40, that is, the lid 42. Formed at a predetermined position, when the raw water introduced through the inlet 41 is generated with ozone water maintained at a constant concentration by electrolysis by the electrolysis generating core 43 connected in parallel, outside the ozone generator 40 To be discharged.

In addition, the outlet 45 is the H ⁺ gas separated from the water molecules by the electrolysis generating core (43) in the hand, as well as to make the ozone water is ejected produced by the electrolysis generating core 43, the H ₂ gas When combined with the top of the ozone generator 40, the H ₂ gas is discharged through the outlet 45 to prevent the recombination of H ₂ gas into OH ^- gas to improve the efficiency of the ozone generator, H ₂ gas is It is also possible to prevent safety accidents such as explosions that may occur when the ozone generator 40 is full.

The cover 42 forms positive and negative electrodes 42a and 42b to supply external power to the plurality of electrolysis generating cores 43 connected in parallel in the ozone generator 40.

FIG. 3 is an exploded perspective view of the frame 10 of the electrolysis generating core 43 applied to the present invention, and FIG. 4 is a first polar line (C) in the frame 10 of the electrolysis generating core 43 applied to the present invention. 11 is a perspective view showing a wound state, and FIG. 5 is a state in which the first pole wire 11 and the second pole wire 12 are wound on the frame 10 of the electrolysis generating core 43 according to the present invention. 6 is a side view showing a state in which the first pole wire 11 and the second pole wire 12 are wound around the frame 10 of the electrolysis generating core 43 according to the present invention.

As shown, in order to be able to generate ozone in the water through electrolysis in the ozone generator 40, a plurality of electrolysis generating cores 43 are connected in parallel, but separated by a partition 44 The electrolysis-generating core 43 has a first pole line 11, which is an anode, and a cathode, which is a cathode, in winding the platinum wires 11 and 12 on the frame 10. The two poles 12 are formed to be parallel to each other in the same direction in a predetermined interval, so that the contact area with the water between the first pole 11 and the second pole 12 is wide to maximize the amount of ozone generated. Configure it to be possible.

The frame 10 forms winding supports on both left and right sides, and forms winding auxiliary supports at regular intervals between the winding supports on both sides, and the second polar winding support 30 is formed on the first polar winding support 20. , The second pole winding auxiliary support 32 is coupled to the first pole winding auxiliary support 22 so that the first pole 11, which is an anode made of platinum wire, and the second pole 12, which is a cathode, may be wound. Consists of

The thinner the thickness of the platinum wire, which is the positive electrode wire wound on the frame 10, the narrower the gap between the electrode and the electrode, the better the efficiency of ozone generation. Adjusting the width of the winding support so as to maintain it, and the amount of ozone is different depending on the number of platinum wire that is the positive electrode wire wound on the frame 10 is configured to adjust the length of the winding support to adjust the number of platinum wire To form the frame 10.

The first pole winding support 20 is a support for winding the first pole 11 on both sides of the frame 10, the sawtooth winding groove (20a) is formed on the upper and lower sides at a predetermined interval to the platinum line The first pole wire 11 is formed so as to be fitted so as to wrap the body of the frame 10 from one side of the first pole winding support 20 to the other side, and the first pole wire 11 flows during hydraulic pressure or electrolysis. In order to prevent it from being loosely stretched or pulled to one side due to the flow rate of water, a first pole winding auxiliary support 22 is formed at regular intervals between the first pole winding support 20, but the upper and lower teeth have the same tooth-shaped winding groove ( 22a) is formed at regular intervals so that the first pole 11 is easily wound on the frame 10 body, and the recesses 23 are formed on both sides to fix the second pole winding auxiliary support 32. ) Can be inserted and combined.

First pole parallel connection lines 24 are formed on both sides of the first pole winding support 20, and the first pole lines are connected to cross the first pole wire 11 wound on the first pole winding support 20. Even when a short occurs in a predetermined portion of 11), the electrolysis is continuously performed even in a state in which the shorted first pole 11 is excluded due to the first pole parallel connection line 24.

The second pole winding support 30 has a shape that is coupled to the side of the first pole winding support 20, so as to be spaced apart at a predetermined interval between the first pole 11 and the second pole (12). Although the width is formed to be larger than the first pole winding support 20 by a predetermined width, the amount of ozone may vary depending on the gap between the two poles so that an appropriate interval can be maintained, and the first pole winding support is supported. The fixing projection 31 formed in the second pole winding support 30 is inserted into the fixing groove 21 formed in the 20 so as to be recessed and coupled, and a winding guide groove 30a is formed on the outer surface to form the second pole wire. (12) is to be easily wound up.

The second pole winding auxiliary support 32 has a predetermined interval between the second pole winding support 30 to prevent the second pole 12 from being loosely stretched or pulled to one side due to the water pressure or the flow rate of water flowing during electrolysis. It is formed in, but to form a fixing stand 33 on both sides so that it can be coupled to the recessed groove 23 formed in the first pole winding auxiliary support 22, the sawtooth-shaped winding groove (32a) formed on the upper and lower surfaces The second pole wire 12 is spaced apart from the first pole wire 11 at a predetermined interval by being easily coupled to the saw tooth-shaped winding groove 22a of the first pole winding auxiliary support 22. The dipole 12 is wound to enclose the body of the frame 10.

On both sides of the second pole winding support 30, a second pole parallel connecting line 34 is formed, but is connected to cross the second pole 12 wound on the second pole winding support 30 due to the scale, etc. Even when a short occurs in a predetermined portion of the second pole 12, the electrolysis is continuously performed even when the second pole 12 shorted due to the second pole parallel connection line 34 is excluded.

As described above, the operation of the ozone generator 40 in which the electrolysis generating core 43 constructed in accordance with one embodiment of the present invention is connected in parallel will be described in detail.

The electrolysis generating core 43 is wound around the platinum wire on the frame 10 so as to generate ozone water in the water through the electrolysis action, the first pole 11 of the anode and the second cathode of the platinum wire In winding the pole line 12 on the frame 10, the poles 12 are paralleled in the same direction, and the first pole line 11 and the second pole line 12 are formed on the cover 42 (+) and (-). It is connected to the electrodes 42a and 42b to receive external power.

The first pole line 11 is connected to the (+) electrode 42a to be supplied with (+) power, but is formed on the upper surface of the first pole winding support 20 formed on one side of the frame 10. The first pole winding support formed on the other side of the frame 10 via the sawtooth winding groove 22a formed on the upper surface of the first pole winding auxiliary support 22 after being seated in the saw tooth winding groove 20a ( It is seated on the serrated winding groove 20a formed on the lower surface of the first pole winding support 20 formed on one side of the frame 10 again through the serrated winding groove 20a formed on the upper and lower surfaces of 20). Winding the first pole 11 to surround the frame 10 in a manner, and the first pole parallel connecting line 24 to intersect the first pole 11 in the longitudinal direction of the first pole winding support 20. It is formed so that the first pole line 11 is connected in parallel.

When the first pole line 11 is wound on the frame 10 in the above manner, the second pole line 12 is connected to the (-) electrode 42b so as to be able to wind the second pole line 12 supplied with (-) power. The fixing protrusions 31 formed on the second pole winding support 30 are inserted into the fixing grooves 21 formed on the first pole winding support 20 so as to be coupled to each other, and the yaw formed on the first pole winding auxiliary support 22. After the holder 33 formed in the second pole winding auxiliary support 32 is recessed and coupled to the mouth groove 23, the second pole 12 is wound in the same manner as the first pole 11 is wound. However, the first pole line 11 and the second pole line 12 are wound in the frame 10 in parallel in a state spaced apart at regular intervals in the same direction.

After winding the first pole line 11 and the second pole line 12 on the frame 10 of the electrolysis generating core 43 in parallel with a predetermined interval spaced in the same direction, the ozone generator 40 A plurality of electrolysis generating cores 43 are installed therein, but the electrolysis generating cores 43 are connected to the same poles in parallel to maintain an efficient ozone concentration at any change in water, and the electrolysis occurs. The partition wall 44 in which the through hole 44a is densely formed is formed between the cores 43.

As described above, when a plurality of electrolysis generating cores 43 are connected in parallel in the ozone generator 40, raw water is introduced through the inlet 41 to supply a predetermined amount of raw water to the ozone generator 40, and a cover. When external power is supplied through the (+) and (-) electrodes 42a and 42b formed on the 42, spaced apart at regular intervals in the same direction on the frame 10 of the electrolysis generating core 43. The platinum wire wound in parallel in the state continues electrolysis to generate ozone water at an appropriate concentration.

As described above, various embodiments of the antibacterial test of ozone water generated by the ozone generator 40 in which the electrolysis generating core 43 constructed in accordance with one embodiment of the present invention are connected in parallel will be described in detail.

As shown in Table 1 below, the test bacteria were diluted with 10 ² , 10 ³ , 10 ⁴ using ozone water and distilled water (sterilized water) having a concentration of 0.5 ppm generated in the ozone generator according to the present invention (about 30 60 seconds treatment effect), 100 μl each immediately to confirm the growth.

Strain condition Pseudomonas aeruginosa KCTC 2004 X (non-growth) Salmonella typhimurium KCTC 2514 ○ Staphylococcus aureus KCTC 1916 ○ Escherichia coli KCTC 1682 X (non-growth) Bacillus subtilis KCTC 1021 ○ Streptococcu mutans KCTC 3065 ○ Candid albicans KCTC 7675 ○ Aspertillus niger X (non-growth) Aspergillus fumigatus X (non-growth)

Aspertillus niger, Aspergillus fumigatus among the test bacteria are tested in Salmonella typhimurium KCTC 2514, Staphylococcus aureus KCTC 1916, Bacillus subtilis KCTC 1021, Streptococcu mutans KCTC 3065, Candid albicans KCTC 7675.

Table 2 below shows the test bacteria classified into ozone water and distilled water produced in the ozone generator according to the present invention, and shows the bactericidal effect of the test strain.

Treatment solution × 10 ² × 10 ³ × 10 ⁴ Salmonella typhimurium KCTC 2514 Ozone distilled water ∞∞ 0 ¹⁾ ∞ 02,258 (2.2 × 10 ⁸ / mL) Staphylococcus aureus KCTC 1916 Ozone distilled water ∞∞ 0∞ 01,316 (1.3 × 10 ⁸ / mL) Bacillus subtilis KCTC 1021 Ozone distilled water 121217 914 2 (2.0 × 10 ⁵ / mL) 11 (1.1 × 10 ⁶ / mL) Streptococcu mutans KCTC 3065 Ozone distilled water ∞∞ ∞∞ 2 (2.0 × 10 ⁵ / mL) 1,025 (1.0 × 10 ⁸ / mL) Candid albicans KCTC 7675 Ozone distilled water ∞∞ 0727 0157 (1.5 × 10 ⁷ / ml)

0 ¹⁾ refers to the state in which the test bacteria are not grown, and Table 2 shows the number of colonies, and as shown in Table 2, when diluted with ozone water, diluted with distilled water. It can be seen that the sterilization effect of the test strain is superior to the case.

Tables 4 and 5 below are the results of testing the antibacterial activity of ozone water generated in the ozone generator according to the present invention according to the concentration and time of ozone.

Strain Distilled water Ozone water (0.5ppm) 10 minutes 30 minutes 60 minutes Escherichia coli 25 Staphylococcus aureus 262 One Bacillus subtilis 285 Pseudomonas aeruginosa 36 17 15 40 Aspergillus fumigatus 1068.3 1043.3 282 One

Strain Distilled water Ozone water (0.3ppm) 10 minutes 30 minutes 60 minutes Escherichia coli 25 Staphylococcus aureus 262 5 Bacillus subtilis 285 211 56 13 Pseudomonas aeruginosa 36 25 19 11 Aspergillus fumigatus 1068.3 1112.6 643.3 8.5

As can be seen in Tables 4 and 5, it can be seen that the higher the concentration of ozone, the better the bactericidal effect on the test strain as time passes.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited to the drawings.

The present invention is connected to a plurality of electrolysis generating cores to generate ozone water through the electrolysis in the water in the ozone generator in parallel to generate ozone water maintaining the proper ozone concentration even under various conditions of water, The first pole wire and the second pole wire made of platinum wires are wound in parallel on the frame of the decomposition generating core in the same direction and spaced apart at a predetermined interval, thereby improving the efficiency of electrolysis due to the large contact area with water during electrolysis. It works.

In addition, by forming a parallel connection line that crosses parallel to the first pole and the second pole so that even if a short circuit occurs in the platinum wire, the electrolysis can be continuously generated to maximize the amount of ozone generated by the ozone generator. It is not necessary to form a separate insulating film between the manufacturing cost is reduced and excellent in economic efficiency, the ozone water produced by the present invention has the effect of expanding the range of use not only for home use, but also for medical use to improve the utility of the product.

1 is an exploded perspective view of an ozone generator applied to the present invention

Figure 2 is a side view of the ozone generator applied to the present invention

Figure 3 is an exploded perspective view of the frame of the electrolysis generating core applied to the present invention

4 is a perspective view showing a state in which a first pole wire is wound around a frame of an electrolysis generating core applied to the present invention;

5 is a perspective view showing a state in which a first pole wire and a second pole wire are wound around a frame of an electrolysis generating core applied to the present invention;

6 is a side view showing a state in which a first pole and a second pole are wound on a frame of an electrolysis generating core applied to the present invention;

* Description of Signs of Main Parts of Drawings *

10.Frame 11.First Polar Wire

12. Second pole 20. First pole winding support

20a. Winding groove 21.

22. First polar winding auxiliary support 22a. Winding

23. Grooving groove 24. Parallel cable for the first pole

30. Second pole winding support 30a. Winding

31. Fixing protrusion 32. Second pole winding auxiliary support

32a. Winding guide groove 33.

34. Second pole parallel connection line 40. Ozone generator

41. Inlet 42. Cover

42a. (+) Electrode 42b. (-)electrode

43. Core for electrolysis 44. Bulkhead

44a. Via 45. Outlet

Claims (3)

In ozone generator that generates ozone by electrolysis in water, An inlet for introducing external raw water into the ozone generator; An electrolysis generating core wound around the frame in parallel with spaced apart at regular intervals in the same direction with platinum wires consisting of anode and cathode wires; Barrier ribs having a plurality of through holes formed densely between electrolysis generating cores connected in plural in parallel; A cover for forming a (+) and (-) electrode to supply power to a plurality of electrolysis generating cores connected in parallel in the ozone generator; An ozone generator in which an electrolysis generating core is connected in parallel, the outlet being formed at a predetermined position on a cover to discharge ozone water and hydrogen gas generated by the electrolysis reaction by the electrolysis generating core to the outside; . The method of claim 1, The electrolysis generating core forms a winding support so that the first pole wire and the second pole wire made of platinum wires can be wound in parallel in a state spaced apart at regular intervals in the same direction while supporting the body on both sides of the frame, and between the winding supports. To form a winding auxiliary support, the winding support is formed so that the second pole winding support is coupled to the first pole winding support, the winding support is formed so that the second pole winding auxiliary support is coupled to the first pole winding support In a state in which the first pole wound on the first pole winding support and the first pole winding auxiliary support and the second pole wound on the second pole winding support and the second pole winding auxiliary support are spaced apart at regular intervals in the same direction. An ozone generator in which an electrolysis generating core is connected in parallel, characterized by winding in parallel. The method of claim 1, Ozone having an electrolysis generating core connected in parallel to the first pole winding support and the second pole winding support, further comprising a parallel connection line formed to be connected in parallel with the first pole and the second pole wound in parallel; generator.