KR20180120452A - Plasma ozone sterilizer - Google Patents

Abstract

The present invention relates to a plasma ozone sterilizer, which comprises the following: an ozone generator generating ozone gas from a plasma phenomenon; and a stirrer generating OH radial water by mixing the ozone gas with water, so as to provide the ozone gas and the OH radical water to an object to be sterilized. According to one embodiment, the stirrer includes first and second passages in a curved shape, so that the ozone gas and water flowing from one direction can pass through the first and second passages and be uniformly mixed. Also, according to another embodiment, the stirrer includes a second tank formed inside a first tank, wherein the water and ozone gas flow into the second tank from different directions so that the ozone gas and water can be uniformly mixed using the vortex phenomenon inside the second tank. Accordingly, by discharging ozone generated through a plasma phenomenon in a gas form or after melting the same to discharge in an OH radical water form, the ozone can be properly supplied to an object to be sterilized.

Description

[0001] PLASMA OZONE STERILIZER [0002]

The present invention relates to a plasma ozone sterilizer, and more particularly, to a plasma ozone sterilizer for sterilizing an object by generating ozone gas and OH radical water using a plasma ozonizer.

OH Radical (OH radical: hydroxyl group) is a kind of oxygen anion-based natural substance which is produced in the 'plasma' state of the fourth substance when a high and strong energy is applied, and is harmless to the human body and has excellent oxidizing power. OH Radical's oxidative power is stronger than fluorine (F), stronger than ozone (O ₃ ) and chlorine (Cl ₂ ) but toxic or harmful to human body like fluorine, chlorine and ozone Is not. It has strong sterilizing power and is harmless to the human body after being reduced to oxygen (O ₂ ) and water (H ₂ 0) after reaction with pollutants. It sterilizes and disinfects contaminants, has a sterilization speed that is 2,000 times faster than ozone and 180 times faster than sun's ultraviolet rays. It acts directly on pollutants in air and water to sterilize, deodorize and decompose.

Patent No. 10-1036954 discloses a low-voltage ozone generator and an ozone sterilizing apparatus using the same.

Disclosure of Invention Technical Problem [8] The present invention is directed to an ozone gas capable of sterilizing by using a plasma ozonizer and OH radical water using ozone gas to efficiently sterilize a subject to be sterilized.

An apparatus for sterilizing a plasma ozone according to an embodiment of the present invention includes: an ozone gas discharge pipe for discharging gas generated from an ozone generator that generates ozone by using a plasma phenomenon; An agitator for taking water from the water inlet pipe and receiving the ozone gas generated from the ozone gas and the ozone generator, and stirring the ozone gas and water using a vortex phenomenon to generate OH radical water; And an OH radical water discharge pipe for discharging the OH radical water generated in the stirrer, wherein the object to be sterilized is sterilized with ozone gas and OH radical water.

And a three-way valve formed between the ozone generator and the agitator for controlling an amount of the ozone gas introduced into the agitator and regulating the amount of the ozone gas discharged through the ozone gas discharge pipe .

And a pipe connected to the water inlet pipe for flowing water into the stirrer and having a valve that is opened and closed in accordance with a control signal transmitted from the outside, and controls the amount of water flowing into the stirrer .

The stirrer may include: a first housing that receives the ozone gas and the water and is connected to the OH radical water discharge pipe; The OH radical water discharging pipe extends from the inside of the first housing and is connected to one side of the inside of the first housing, which is connected to the OH radical water discharging pipe, and has a plurality of holes at the outer circumference, And a second housing for receiving the ozone gas and the water, wherein the ozone gas introduced into the first housing and the water are introduced into the second housing through the plurality of holes formed in the second housing, And is stirred to flow into the OH radical water discharge pipe to generate OH radical water.

And the plurality of through holes are formed in the second housing at an oblique angle.

The agitator includes a first cylindrical housing connected to the OH radical water discharge pipe and transferring the fluid discharged from the second cylindrical housing to the OH radical water discharge pipe; The ozone gas and the water are flowed through different pipes to generate OH radical water and a plurality of holes are formed in the outer periphery to discharge the OH radical water to the first cylindrical housing through the plurality of holes And a second cylindrical housing.

The second cylindrical housing has a structure in which a pipe for receiving the ozone gas is connected to one side of the cylindrical housing and a pipe for receiving the water is connected to the other side of the cylindrical housing.

And the diameter of the pipe through which the ozone gas flows and the pipe through which the ozone gas flows is smaller than the diameter of the second cylindrical housing.

The ozone gas and the water flowing into the second cylindrical housing are controlled in accordance with an open / close control signal transmitted from the outside, And the inflow amount and the inflow timing are controlled.

The stirrer may further include an ultrasonic generator to improve the efficiency of generating OH radicals through agitation through vortexing in the agitator.

And an OH radical water storage tank formed between the stirrer and the OH radical water discharge pipe to store the OH radical water and including an exhaust pipe, wherein the OH radical water storage tank includes a timer, And the OH radical water stored in the OH radical storage tank is discharged to the discharge pipe when the timer reaches the set time.

The discharge pipe formed in the OH radical water storage tank is connected to the water inflow pipe or the water tank so that the reduced water discharged by the time set in the OH radical water storage tank is recycled.

According to this aspect, the plasma ozone sterilizing apparatus according to an embodiment of the present invention can generate an ozone gas using a plasma ozone generator and supply the generated ozone gas to a sterilizing target, dissolve the generated ozone gas in water, sterilize it as OH radical water So that it is possible to efficiently sterilize the object to be sterilized.

At this time, in the mixing of ozone gas and water in the stirrer to produce OH radical water, ozone gas and water are uniformly mixed from the vortex phenomenon, so that OH radical water can be generated without requiring a separate power source .

FIG. 1 is a schematic view of a plasma ozone sterilizing apparatus according to an embodiment of the present invention. Referring to FIG.
2 is a view showing an example of a stirrer of a plasma ozone sterilizing apparatus according to an embodiment of the present invention.
3 is a view showing another example of the agitator of the plasma ozone sterilizing apparatus according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

1, a plasma ozone sterilizer according to an embodiment of the present invention will be described in detail. The plasma ozone sterilizer according to an embodiment of the present invention includes a plasma ozonizer 10, an ozone storage tank 20, a three-way valve 30, an ozone gas discharge pipe 40, a water inflow pipe 50, a venturi pipe 43, an inflow water replenishment pipe 42, an agitator 60, an OH radical water storage tank (70), and an OH radical water discharge pipe (80).

The plasma ozone generator 10 generates an ozone gas using a plasma phenomenon, and the ozone storage tank 20 stores ozone gas generated by the plasma ozone generator 10.

The plasma ozone generator 10 is an apparatus for generating ozone gas using a plasma phenomenon and is a well-known technology, and therefore, it should be understood by those skilled in the art even if not described in detail herein.

Way valve 30 moves the ozone gas discharged from the ozone storage tank 20 to the ozone gas discharge pipe 40 or the ozone gas transfer pipe 41 in accordance with an external application signal.

At this time, the 3-way valve 30 is a valve that receives an external application signal electrically and controls the opening / closing operation.

In one example, the three-way valve 30 opens or closes a valve directed to the ozone gas discharge pipe 40 or opens or closes a valve directed to the ozone gas delivery pipe 41 according to an external application signal.

Alternatively, in one example, the three-way valve 30 controls the opening / closing time of the valve toward the ozone gas discharge pipe 40 or the opening / closing time of the valve toward the ozone gas transfer pipe 41 in accordance with an external application signal .

The ozone gas discharge pipe 40 is stored in the ozone storage tank 20 according to opening and closing of the three-way valve 30 and discharges the ozone gas O ₃ flowing into the ozone gas discharge pipe 40.

In one example, it is preferable that the ozone gas discharge pipe 40 has a structure in which the end faces toward the object of sterilization so as to discharge the ozone gas to the object to be sterilized.

At this time, the ozone gas discharged through the ozone gas discharge pipe 40 is discharged at a specific discharge amount at a specific discharge time according to the opening and closing operation and the opening and closing time of the three-way valve 30, thereby sterilizing the sterilizing object.

The ozone gas transfer pipe 41 transfers the ozone gas stored in the ozone storage tank 20 toward the venturi pipe 43 according to the opening and closing operations of the three-way valve 30.

Like the ozone gas discharge pipe 40, the ozone gas transfer pipe 41 transfers ozone gas having a specific discharge amount at a specific discharge time according to the opening / closing operation and opening / closing time of the 3-way valve 30.

The water inflow pipe 50 is a pipe for supplying water and is joined to the venturi pipe 43 and the inflow water supplement pipe 42.

The venturi pipe 43 is formed at a portion where the ozone gas transfer pipe 41 and the water inflow pipe 50 are connected to each other and has a structure in which the interior thereof is narrowed and widened. The transfer speed of the ozone gas delivered in the direction of the agitator 60 is increased by the venturi effect.

The venturi pipe 43 is provided with an inlet water replenishment pipe 42 to receive a portion of the water flowing through the water inlet pipe 50 and to transfer the water to the stirrer 60. The venturi pipe 43 is filled with water The sterilization concentration of the OH radical water stored in the OH radical water storage tank 70 can be adjusted by providing the pipe 42 to transmit water flowing in the water inflow pipe 50 toward the agitator 60.

The venturi pipe 43 may further include an ozone reducing device for completely diluting the ozone gas and the water in mixing the ozone gas and the water to generate the OH radical water.

At this time, the valve 421 is further provided in the inlet water replenishing pipe 42 of the venturi pipe 43. The valve 421 is controlled to be opened and closed in accordance with the opening / closing control signal transmitted from the outside and is transmitted to the stirrer 60 The amount of water to be dispensed can be adjusted.

The ozone gas delivery pipe 41 and the venturi pipe 43 are connected to each other. The check valve may further include a check valve to prevent backflow of water flowing through the water inlet pipe 50, (50).

1 and 2, the stirrer 60 according to an embodiment of the present invention will be described in detail with reference to FIG. 2. The stirrer 60 includes a stirrer 60, 1 housing 610 and a second housing 620 inside the housing 610.

More specifically, the ozone gas delivered through the ozone gas delivery pipe 41 and the water delivered through the water inlet pipe 50 and the venturi pipe 43 and the inlet water replenishment pipe 42 are supplied to the agitator 60 Mixed in the agitator 60, and discharged as OH radical water uniformly mixed.

At this time, as ozone gas and water flow into the stirrer 60 through the first inlet pipe 61 connected to one side of the stirrer 60, uneven OH radicals flow into the first inlet pipe 61, 60 are stirred in the agitator 60 through the first discharge pipe 62 connected to the other side of the agitator 60 to discharge the uniformly mixed OH radical water.

The structure of the first housing 610 and the second housing 620 of the agitator 60 will be described in more detail. The first housing 610 is directly connected to the first inflow pipe 61 and is connected to the first inflow pipe 61, The ozone gas and the water are introduced into the ozone generator.

The first housing 610 is formed in a closed structure connected to the first inlet pipe 61 and the first outlet pipe 62 only.

The second housing 620 is attached to one side of the first housing 610.

One side of the first housing 610 to which the second housing 620 is attached is one side connected to the first discharge pipe 62 and the second housing 620 has a plurality of through holes 65 ).

In one example, when the second housing 620 has a cylindrical shape, the plurality of through holes 65 may be formed along the outer periphery of the cylindrical second housing 620, and as another example, The plurality of through holes 65 may be formed on the side surfaces of the second housing 620 formed as a hexahedron.

The plurality of through holes 65 formed in the side surface of the second housing 620 are formed to penetrate the side surface of the second housing 620. The diameter of each through hole 65 is formed in the first housing 610 And may be formed to have a length enough to allow the inflow fluid to flow into the second housing 620.

The plurality of through holes 65 are through holes for receiving the fluid flowing in the direction of the arrow in the first housing 610 into the inside of the second housing 620. When the fluid flows into the second housing 620 As shown in FIG.

The second housing 620 is hermetically sealed inside the first housing 610 except for a portion where a plurality of through holes 65 are formed. At this time, the second housing 620 is inserted into the first housing 610 The second housing 620 is spaced apart from the inner wall of the first housing 610 at the first inflow pipe 61 side.

At this time, the outer wall of the second housing 620 having the plurality of through holes 65 is also spaced apart from the inner wall of the first housing 610.

The second housing 620 is attached to one side of the first housing 610 and the rest of the second housing 620 is located inside the first housing 610 so as to be separated from the first housing 610 Accordingly, the fluid moves in the direction indicated by the arrow in a portion formed between the first housing 610 and the second housing 620.

The first exhaust pipe 62 connected to the first housing 610 may extend to the interior of the second housing 620. The first exhaust pipe 62 may be connected to the second housing 620, The second housing 620 and the first discharge pipe 62 formed in the second housing 620 form a flow path through which fluid can flow.

Thus, according to the structure of the first housing 610 and the second housing 620, in one embodiment of the stirrer 60 having the structure referring to Fig. 2, the ozone gas transfer piping 41 The ozone gas and the water transferred through the water inlet pipe 50 are transferred to the agitator 60 through the first inlet pipe 61 to be introduced into the first housing 610 and the second housing 620 in the agitator 60. [ And then discharged through the first discharge pipe 62.

The flow of the fluid flowing into the stirrer 60 through the first inlet pipe 61 and passing through the inside of the stirrer 60 and discharged to the first outlet pipe 62 will be described in more detail. The ozone gas and water (hereinafter, referred to as 'fluid') introduced into the first housing 620 move along the arrow direction into the first housing 610, 2 housing 620. In this way,

The fluid introduced into the interior of the second housing 620 flows through the flow path formed between the outer surface of the first discharge pipe 62 extending into the interior of the second housing 620 and the side surface of the second housing 620 That is, in the direction of the first inflow pipe 61.

At this time, the fluid flowing in the direction of the first inflow pipe (61) from the second housing (620) flows in the direction of the first discharge pipe (62) by turning the side wall of the second housing (620).

The fluid introduced into the first housing 610 flows into the second housing 620 through the through hole 65 and is discharged through the first discharge pipe 62 located inside the second housing 620. [ So that the ozone gas and the water are uniformly mixed as the fluid repeatedly circulates through the inside of the agitator 60.

Since the agitator 60 has such a structure, the ozone gas and the water are efficiently stirred to generate OH radical water and can be discharged through the first discharge pipe 62 without any separate structure for stirring operation .

In one example, the second housing 620 is coupled to the inside of the first housing 610 of the stirrer 60 and is detachably attached thereto. The first housing 610 and the second housing 620 are coupled to each other The agitator 60 is formed in a coupling structure detachably attached to the first discharge pipe 61 and the second discharge pipe 62 so that the agitator 60 is connected to the first discharge pipe 61 and the second discharge pipe 62, It is possible to separate the housings from each other and to easily clean the interior.

3, the stirrer 60a is provided with a second inflow pipe 61a and a third inflow pipe 61b, as shown in FIG. 3, And a second discharge pipe 63 at one side.

At this time, the second inlet pipe 61a and the third inlet pipe 61b receive ozone gas, which is transferred through the ozone gas transfer pipe 41, or water flowing through the water inlet pipe 50, .

For example, when the second inflow pipe 61a receives ozone gas and the third inflow pipe 61b receives water, the ozone gas introduced through the second inflow pipe 61a And the ozone gas delivered through the ozone gas transfer pipe 41 is transferred to the second cylindrical housing 620a of the agitator 60a.

At this time, the second inlet pipe 61a has a first valve 601. The first valve 601 is connected to the ozone gas flowing along the second inlet pipe 61a in response to an opening / To the agitator 60a or not to the agitator 60a.

The water flowing through the third inflow pipe 61b flows through the water inflow pipe 50 and the water bypassed through the inlet water replenishing pipe 42 through the venturi pipe 43 is supplied to the agitator 60a To the second cylindrical housing 620a.

Similarly to the second inflow pipe 61a, the third inflow pipe 61b is provided with a second valve 602 that is opened and closed in accordance with a signal applied from the outside, so that the water flowing along the third inflow pipe 61b To the agitator 60a or not to the agitator 60a.

As described above, the ozone gas or water flows into the agitator 60a through the second and third inflow pipes 61a and 61b, and the ozone gas or water flows into the agitator 60a through the second and third inflow pipes 61a and 61b. By providing a valve that controls delivery, the amount of the transfer material to be transferred into the stirrer 60a can be controlled.

The stirrer 60a includes a first cylindrical housing 610a and a second cylindrical housing 620a formed therein. The first cylindrical housing 610a and the second cylindrical housing 620a are provided in the agitator 60a. The diameter of the second cylindrical housing 620a is larger than the diameter of the second cylindrical housing 620a so that the second cylindrical housing 620a is located inside the first cylindrical housing 610a.

The length of the first cylindrical housing 610a is longer than the length of the second cylindrical housing 620a so that the second cylindrical housing 620a is completely positioned inside the first cylindrical housing 610a . ≪ / RTI >

The outer circumferential surface of the second cylindrical housing 620a is located on the inner surface of the first cylindrical housing 610a so that the second cylindrical housing 620a is completely positioned within the first cylindrical housing 610a, And is located inside the first cylindrical housing 610a.

At this time, the diameter of the second cylindrical housing 620a is formed to be larger than the diameter of the second inlet pipe 61a and the third inlet pipe 61b, and the diameter of the second cylindrical housing 620a from the second and third inlet pipes 61a, When the ozone gas or water (hereinafter referred to as "fluid") flowing into the housing 620a flows into the second cylindrical housing 620a, it can be efficiently stirred inside the second cylindrical housing 620a .

As shown in FIG. 3, the second cylindrical housing 620a forms a plurality of through holes 65a along the outer periphery, and the fluid that flows into the second cylindrical housing 620a and is stirred, Is discharged to the outside of the second cylindrical housing 620a along the first cylindrical housing 620a and discharged to the second discharge pipe 62a through the space between the first cylindrical housing 610a and the second cylindrical housing 620a.

The through hole 65a is a through hole through which the liquid stirred inside the second cylindrical housing 620a is discharged to the outside of the second cylindrical housing 620a and a plurality of through holes 65b are formed in the outer circumference of the second cylindrical housing 620a And the diameter of the through hole 65a may be formed to be sufficient to discharge the fluid located inside the second cylindrical housing 620a, but is not limited thereto.

The operation of stirring the fluid introduced into the second cylindrical housing 620a will be described in more detail. The ozone gas is introduced into the second cylindrical housing (not shown) through the second inlet pipe 61a in a state where the first valve 601 is opened 620a and the water flows into the second cylindrical housing 620a through the third inflow pipe 61b in a state where the second valve 602 is opened.

At this time, in order to control the amount of ozone gas to be introduced into the second cylindrical housing 620a, opening and closing of the first valve 601 can be controlled according to an external signal, and similarly, The opening and closing of the second valve 602 can be controlled according to an external signal to adjust the amount of water to be introduced.

In one example, opening and closing of the first or second valve 601, 602 is controlled to control the amount of OH radical water to be formed in the agitator 60a or the OH radical concentration (pH acidity) .

As the opening and closing of the first and second valves 601 and 602 are controlled, the fluid flows into the second cylindrical housing 620a and the second cylindrical housing 620a And the water flowing into the second cylindrical housing 620a through the third inlet pipe 61b are respectively moved into the second cylindrical housing 620a in the direction of the arrows so that the second cylindrical housing 620a So that the fluids are rapidly introduced into the center of the inside of the chamber.

At this time, since the diameter of the second and third inflow pipes 61a and 61b is smaller than the diameter of the second cylindrical housing 620a, the fluid introduced into the second cylindrical housing 620a flows into the second cylindrical housing 620a ) In the direction of the arrow, and is stirred by the swirling phenomenon.

As the fluid is stirred in the second cylindrical housing 620a, OH radicals are formed in the second cylindrical housing 620a, and the formed OH radicals flow through the plurality of through holes 65a formed in the outer circumference of the second cylindrical housing 620a in the respective arrow directions And moves to the outside of the second cylindrical housing 620a.

The OH radical water discharged to the outside of the second cylindrical housing 620a moves along the flow path formed between the inside of the first cylindrical housing 610a and the second cylindrical housing 620a and flows through the second discharge pipe 62a And is discharged along the arrow direction.

As described above, the stirrer 60, 60a formed with the structure described with reference to FIGS. 2 and 3 and performing the stirring operation stirs the ozone gas and water to generate OH radical water.

In one example, the stirrers 60 and 60a are formed to further include an ultrasonic generator, so that the stirring efficiency can be improved by applying vibration to the fluid.

Referring to FIG. 1 again, the structure of the plasma ozone sterilizing apparatus according to an embodiment of the present invention will be described. The OH radical water storage tank 70 is connected to the stirrer 60 through a pipe, OH radicals are received and stored.

As an example, the OH radical water storage tank 70 may be configured to include an exhaust line to discharge the stored OH radical water when the set time is reached.

More specifically, since the OH radical water stored in the OH radical water storage tank 70 is reduced to water over time, the time that can be used as a sanitizer is limited. Therefore, the time can be set in the timer and the liquid stored in the OH radical storage tank 70 can be discharged when the predetermined time is reached.

At this time, the time set in the timer may be 30 minutes, and the discharge pipe may be positioned so as to discharge the discharge pipe to the outside. In a preferred example, the discharge pipe is connected to the water inlet pipe 50 or the water tank Water in the form of OH radical water can be introduced into the water inlet pipe 50 or the water tank to be recycled.

The OH radical water discharge pipe 80 has a structure in which its end portion is directed to discharge OH radical water to the object to be sterilized. Although not shown, the OH radical water discharge pipe 80 is provided with a valve on the OH radical water discharge pipe 80, The OH radical water can be discharged in such a manner as to control the OH radical supply timing and the supply amount by opening and closing in accordance with the applied control signal.

As described with reference to FIGS. 1 to 3, since the plasma ozone sterilizing apparatus according to an embodiment of the present invention is formed into a structure that generates ozone gas or OH radical water as a sterilizing agent, the sterilizing object can be effectively sterilized , It is possible to efficiently produce OH radical water as a disinfectant.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

10: ozone generator 20: ozone storage tank
30: 3-way valve 40: Ozone gas discharge pipe
41: ozone gas transfer pipe 42: incoming water replenishment pipe
43: Venturi pipe 50: Water inlet pipe
60, 60a: stirrer 61, 61a, 61b: inlet pipe
62, 62a: exhaust pipe 65: through hole
70: OH radical water storage tank 80: OH radical water discharge pipe
601: first valve 602: second valve
610: first housing 620: second housing

Claims (12)

An ozone gas discharge pipe for discharging gas generated from an ozone generator that generates ozone by using a plasma phenomenon;
An agitator for taking water from the water inlet pipe and receiving the ozone gas generated from the ozone gas and the ozone generator, and stirring the ozone gas and water using a vortex phenomenon to generate OH radical water; And,
An OH radical water discharge pipe for discharging the OH radical water generated in the stirrer;
And sterilizing the object to be sterilized with ozone gas and OH radical water. The method according to claim 1,
And a three-way valve formed between the ozone generator and the agitator for controlling an amount of the ozone gas introduced into the agitator and regulating the amount of the ozone gas discharged through the ozone gas discharge pipe Wherein the plasma ozone sterilizer is a plasma ozone sterilizer. The method according to claim 1,
And a pipe connected to the water inlet pipe for flowing water into the stirrer and having a valve that is opened and closed in accordance with a control signal transmitted from the outside, thereby controlling the amount of water flowing into the stirrer Plasma ozone sterilizer. The method according to claim 1,
The stirrer may include:
A first housing which receives the ozone gas and the water and is connected to the OH radical water discharge pipe; And
Wherein the OH radical water discharge pipe is extended to the inside of the first housing and connected to the OH radical water discharge pipe of the inside of the first housing and has a plurality of holes at an outer periphery thereof, A second housing for receiving the ozone gas and the water therein;
The ozone gas introduced into the first housing and the water are introduced into the second housing through the plurality of through holes formed in the second housing and are stirred while flowing to the OH radical water discharge pipe, Thereby generating radical water. 5. The method of claim 4,
Wherein the plurality of through holes are formed in the second housing at an oblique angle. The method according to claim 1,
The stirrer may include:
A first cylindrical housing connected to the OH radical water discharge pipe and transferring the fluid discharged from the second cylindrical housing to the OH radical water discharge pipe; And
Wherein the ozone gas and the water are flowed through different pipes to generate OH radical water and a plurality of holes are formed in the outer periphery to discharge the OH radical water to the first cylindrical housing through the plurality of holes, 2 cylindrical housing;
Wherein the plasma ozone sterilizer comprises: The method according to claim 6,
Wherein the second cylindrical housing has a structure in which a pipe for receiving the ozone gas is connected to one side of the cylindrical housing and a pipe for flowing the water is connected to the other side of the cylindrical housing. . 8. The method of claim 7,
Wherein the diameter of the pipe for flowing the ozone gas and the pipe for flowing the water is smaller than the diameter of the second cylindrical housing. 8. The method of claim 7,
The ozone gas and the water flowing into the second cylindrical housing are controlled in accordance with an open / close control signal transmitted from the outside, And the inflow amount and the inflow timing of the ozone are controlled. The method according to claim 1,
Wherein the stirrer further includes an ultrasonic generator to improve the efficiency of generating OH radicals through agitation through vortexing in the agitator. The method according to claim 1,
And an OH radical water storage tank formed between the stirrer and the OH radical water discharge pipe for storing the OH radical water and including an exhaust pipe,
Wherein the OH radical water storage tank includes a timer and discharges the OH radical water stored in the OH radical water storage tank to the discharge pipe when a time set in the timer is reached. 12. The method of claim 11,
Wherein the discharge pipe formed in the OH radical water storage tank is connected to the water inlet pipe or the water tank to recycle the reduced water discharged at a predetermined time in the OH radical water storage tank, Device.

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