KR102291477B1 - radical water generating apparatus - Google Patents

Abstract

The present invention relates to a new radical water generator capable of effectively generating radical water. In the radical water generator according to the present invention, an air supply pump (7) and an ozone generator (8) are provided inside a metal cabinet (10), so that it is possible to expose the air supply pump (7) and the ozone generator (8) to the outside and it is easy to move or maintain the device. The cabinet (10) includes a body (11) provided with a door on the front, and a diaphragm (12) provided to be spaced apart from each other in the vertical direction inside a body (11) and on which the ozone generator (8) is mounted on the upper surface. Therefore, a buffer pad (13) is provided on the upper surface of the diaphragm (12) to support the middle parts of the air supply pump (7), the ozone generator (8) and the air supply pipe (6), and as the air supply pump (7) operates, the cabinet (10) can prevent noise and vibration from occurring.

Description

Radical water generating apparatus

The present invention relates to a new radical water generator capable of effectively generating radical water.

In general, OH-radical water, called radical water, is generally used for sterilization and is used for various purposes such as odor removal, pesticide removal, and bleaching power improvement as an application method.

This radical water is generated by melting ozone in water. As shown in FIG. 1, the radical water generator used for generating such radical water is a water supply pipe (1) whose front end is connected to the water supply means (2). And, a water supply pump 3 provided in the middle of the water supply pipe 1, a radical water generating unit 4 provided at the rear end of the water supply pipe 1 and connected to a discharge pipe 5, and an air supply pipe 6 ), an ozone generator that generates ozone using the air supply pump 7 connected to the radical water generating unit 4 through It consists of (8).

The water supply means 2 uses a water supply tank in which water is stored.

Therefore, the water supplied by the water supply means (2) is pressurized with the water supply pump (3) and supplied to the radical water generating unit (4) through the water supply pipe (1), and the air supply pump (7) and the ozone generator ( When 8) is driven, the air supplied through the air supply pipe 6 is converted into ozone and supplied to the radical water generating unit 4 through the air supply pipe 6, and the Inside, ozone is melted in water to generate radical water, and the radical water thus generated is discharged through the discharge pipe 5 .

However, in the case of such a radical water generating device, particularly, an industrial radical water generating device used in agriculture or other factories, the supply pump 7 and the ozone generator 8 are provided in multiple numbers to determine the amount of ozone that can be generated at the same time It is configured to ensure a sufficient amount of radical water, and since the air supply pump 7 and the ozone generator 8 are disposed in a state exposed to the outside, it is not only bad in appearance, but it is very difficult to move or maintain the device. There was a cumbersome problem.

And, in this radical water generator, only about 20 to 30% of the ozone generated by the ozone generator 8 is melted in water.

That is, about 70% of ozone in the ozone generated by the ozone generator 8 and supplied to the inside of the radical water generating unit 4 cannot be melted in water and is discharged to the outside through the discharge pipe 5, By scattering inside, there was a problem that the worker could be exposed to air with high ozone concentration.

Therefore, there is a need for a new method to solve these problems.

Registered Utility Model No. 20-0197672,

The present invention is to solve the above problems, and an object of the present invention is to provide a new radical water generator capable of effectively generating radical water.

The present invention for achieving the above object, the front end of the water supply pipe (1) connected to the water supply means (2), the water supply pump (3) provided in the middle of the water supply pipe (1), and the water supply pipe (1) A radical water generating unit (4) provided at the rear end and connected to the discharge pipe (5), an air supply pump (7) connected to the radical water generating unit (4) through an air supply pipe (6), and the air supply pipe (6) In the radical water generating device including an ozone generator (8) connected to the middle of It is provided inside the metal cabinet 10, and the cabinet 10 is provided to be spaced apart from each other in the vertical direction in the main body 11 and the main body 11 provided with a door on the front side, the ozone generator on the upper surface. (8) includes a diaphragm 12 on which the diaphragm 12 is mounted, and on the upper surface of the diaphragm 12, a buffer pad 13 for supporting the intermediate portion of the air supply pump 7, the ozone generator 8, and the air supply pipe 6 There is provided a radical water generator, characterized in that it is provided.

According to another feature of the present invention, an ozone concentration measuring sensor 21 provided on one side of the inside of the cabinet 10 to measure the ozone concentration of the air inside the cabinet 10, and the ozone concentration measuring sensor 21 An exhaust pipe 22 extending from one side to the outside, an exhaust pump 23 provided in the exhaust pipe 22, and ozone provided at an outer end of the exhaust pipe 22 and discharged through the exhaust pipe 22 are heated It further includes a heating means 24 for decomposing, and a control means 25 for receiving a signal from the ozone concentration measurement sensor 21 and controlling the operation of the exhaust pump 23 and the heating means 24, The heating means 24 is formed in a cylindrical shape extending in the vertical direction and having an inner diameter narrowing toward the lower side, extending in the circumferential direction on one upper side, and having a supply hole 24b to which the end of the exhaust pipe 22 is connected. It consists of a case 24a made of a material, and a cylindrical tube extending in the vertical direction, and the lower end penetrates the center of the upper surface of the case 24a and extends to the lower inside of the case 24a. A heating tube 24c is provided, and the inner circumferential surface of the case 24a and the inner circumferential surface of the heating tube 24c have an inner circumferential surface of the case 24a and an inner circumferential surface of the heating tube 24c for promoting the decomposition of ozone. A catalyst 24e is applied, and the catalyst 24e is any one of manganese dioxide (MnO2), ferrous oxide (Fe2O2), and nickel oxide (NiO).

According to another feature of the present invention, the air supply pipe (6) connects the first air supply part (6a) connected to the ozone generator (8) and the ozone generator (8) to the radical water generating unit (4). It is divided into a second air supply unit (6b) and is connected to a fractionation tank (31) provided in the middle of the discharge pipe (5) and extended to the upper surface of the fractionation tank (31) and connected to the second air supply part (6b). An ozone discharge pipe (32), a supply pump (33) provided in the middle of the ozone discharge pipe (32), a first control valve (34) provided in the ozone discharge pipe (32), and the second air supply unit ( In 6b), a second control valve (35) provided between the connection part of the ozone generator (8) and the ozone discharge pipe (32), and the discharge pipe (5) are provided to be located at the rear of the fractionation tank (31) a discharge pump 36, first to third water level sensors 37, 38 and 39 provided inside the fractionation tank 31 to measure the water level inside the fractionation tank 31, and the control means Further comprising an alarm means 41 connected to (25), the discharge pump (36) is configured to adjust the flow rate per unit time according to the control of the control means (25), the control means (25) is When the water level inside the fractionation tank 31 rises to the height of the first water level sensor 37 located at the uppermost side, the second control valve 35 is opened to release the ozone generated by the ozone generator 8 . supply to the radical water generating unit 4, and the level of the radical water inside the fractionation tank 31 is determined by the atmospheric pressure of ozone discharged from the radical water introduced into the fractionation tank 31, the first water level When the water level of the second water level sensor 38 positioned lower than the detection sensor 37 is lowered, the second control valve 35 is closed, the ozone generator 8 is turned off, and the first control valve 34 is ) is opened and the supply pump 33 is driven to supply the ozone stored in the fractionation tank 31 to the radical water generating unit 4 through the ozone discharge pipe 32 and the second air supply unit 6b. and a third water level in which the level of the radical water inside the fractionation tank 31 is the lowest. When the level of the ground sensor 39 is lowered, the discharge pump 36 is stopped, and even if a preset time has elapsed, the water level inside the fractionation tank 31 is the height of the second water level sensor 38 . There is provided a radical water generating device, characterized in that the alarm means (41) is turned on to give a warning to the manager if it does not rise to

In the radical water generator according to the present invention, since the air supply pump 7 and the ozone generator 8 are provided inside the metal cabinet 10, the air supply pump 7 and the ozone generator 8 are exposed to the outside. There is an advantage in that it is prevented, and it is easy to move or maintain the device.

In particular, the cabinet 10 includes a main body 11 having a door on the front side, and a partition plate 12 on which the ozone generator 8 is mounted on the upper surface by being provided to be spaced apart from each other in the vertical direction inside the main body 11 . ), and the upper surface of the diaphragm 12 is provided with a buffer pad 13 for supporting the middle portion of the air supply pump 7, the ozone generator 8, and the air supply pipe 6, so that the air supply pump (7) There is an advantage that can prevent noise and vibration from being generated in the cabinet 10 as the is operated.

1 is a block diagram showing a conventional radical water generator;
2 is a block diagram showing a radical water generator according to the present invention;
3 is a block diagram showing a cabinet of a radical water generator according to the present invention;
4 is a front cross-sectional view showing a heating means provided in the cabinet of the radical water generator according to the present invention;
5 is a plan sectional view showing a heating means provided in a cabinet of the radical water generator according to the present invention;
6 is a circuit configuration diagram of a radical water generator according to the present invention;
7 to 9 are reference views showing the operation of the radical water generator according to the present invention.

Hereinafter, the present invention will be described in detail based on the accompanying illustrative drawings.

2 to 9 show a radical water generator according to the present invention, a water supply pipe 1 having a front end connected to a water supply means 2, and a water supply pump 3 provided in the middle of the water supply pipe 1 and a radical water generating unit 4 provided at the rear end of the water supply pipe 1 and connected to the discharge pipe 5, and an air supply pump 7 connected to the radical water generating unit 4 through the air supply pipe 6 And, the ozone generator 8 connected to the middle part of the air supply pipe 6 to generate ozone using the air passing through the air supply pipe 6 is provided as in the prior art.

At this time, the air supply pipe 6 includes a first air supply unit 6a connected to the ozone generator 8 and a second air supply unit 6b connecting the ozone generator 8 and the radical water generating unit 4 to each other. is partitioned into

In addition, the air supply pump 7 and the ozone generator 8 are provided inside the metal cabinet 10 .

As shown in FIG. 3 , the cabinet 10 includes a body 11 having a door on the front side, and the ozone generator 8 on the upper surface by being spaced apart from each other in the vertical direction inside the body 11 . It is composed of a diaphragm 12 on which the diaphragm 12 is mounted, and a buffer pad 13 for supporting the intermediate portion of the air supply pump 7, the ozone generator 8, and the air supply pipe 6 is provided on the upper surface of the diaphragm 12. .

Therefore, when the air supply pump 7 is operated, the vibration of the air supply pump 7 and the ozone generator 8 is transmitted to the diaphragm 12, or the air supply pipe 6 vibrates and collides with the diaphragm 12 This prevents vibration and noise from being generated in the diaphragm 12 .

That is, the air supply pump 7 is configured in the form of a general piston pump, and vibration is generated during operation, and air is intermittently delivered to the ozone generator 8 through the air supply pipe 6, so that it is supplied intermittently. The air supply pipe 6 and the ozone generator 8 also vibrate by the pressure of the air.

At this time, a buffer pad 13 is provided on the upper surface of the diaphragm 12 to prevent the vibration of the vacuum pump or the air supply pipe 6 and the ozone generator 8 from being transmitted to the diaphragm 12, and the diaphragm 12 ) to prevent vibration or noise from occurring.

In addition, an ozone concentration measuring sensor 21 provided on one side of the inside of the cabinet 10 to measure the ozone concentration of the air inside the cabinet 10, and one side of the ozone concentration measuring sensor 21 extending to the outside an exhaust pipe 22, an exhaust pump 23 provided in the exhaust pipe 22, and a heating means provided at the outer end of the exhaust pipe 22 to heat and decompose ozone discharged through the exhaust pipe 22 ( 24) and a control means 25 for receiving a signal from the ozone concentration measuring sensor 21 and controlling the operation of the exhaust pump 23 and the heating means 24 are further provided.

As shown in FIGS. 4 and 5, the heating means 24 has a cylindrical shape that extends in the vertical direction and has an inner diameter that becomes narrower toward the lower side, extends in the circumferential direction on one upper side, and ends of the exhaust pipe 22 A metal case 24a having a supply hole 24b connected thereto, and a cylindrical tube extending in the vertical direction, the lower end of which passes through the center of the upper surface of the case 24a to the inner lower side of the case 24a. It extends and consists of a heating tube (24c) provided with an electric heater (24d) on the periphery.

At this time, a catalyst 24e for promoting ozone decomposition is applied to the inner circumferential surface of the case 24a and the inner circumferential surface of the heating tube 24c.

The catalyst 24e uses any one of manganese dioxide (MnO2), ferrous oxide (Fe2O2), and nickel oxide (NiO), so that ozone is rapidly decomposed even at a low temperature.

The electric heater 24d is configured to surround the outer circumferential surface of the heating tube 24c, and when turned on, heats the air inside the case 24a and the heating tube 24c.

At this time, the electric heater 24d heats the heating tube 24c to 350 degrees or more.

Therefore, a problem occurs in the ozone generator 8 or the air supply pipe 6 connected to the ozone generator 8, and ozone generated from the ozone generator 8 flows out into the cabinet 10, and the cabinet ( 10) When the ozone concentration inside is increased, the control means 25 checks this through the ozone concentration measurement sensor 21 , and turns on the exhaust pump 23 and the heating means 24 .

When the exhaust pump 23 is driven in this way, air and ozone inside the cabinet 10 are supplied to the heating means 24 through the exhaust pipe 22 .

And, the ozone supplied to the heating means 24 is supplied to the inner peripheral surface of the case 24a through the supply hole 24b, and as shown by arrows in FIGS. 4 and 5, the inner peripheral surface of the case 24a is After being rotated and lowered, it is discharged to the outside through the heating tube 24c.

At this time, since the case 24a and the heating tube 24c are heated to a high temperature by the electric heater 24d, the ozone supplied to the inside of the case 24a is heated to a high temperature, and at the same time, the inner circumferential surface of the case 24a It is rapidly decomposed in contact with the catalyst 24e applied to the inner circumferential surface of the heating tube 24c.

In addition, a fractionation tank 31 provided in the middle of the discharge pipe 5, an ozone discharge pipe 32 extending on the upper surface of the fractionation tank 31 and connected to the second air supply part 6b, and the ozone The supply pump 33 provided in the middle part of the discharge pipe 32, the first control valve 34 provided in the ozone discharge pipe 32, and the ozone generator 8 in the second air supply part 6b and a second control valve 35 provided between the connection part of the ozone discharge pipe 32, and a discharge pump 36 provided in the discharge pipe 5 to be located at the rear of the fractionation tank 31; First to third water level sensors 37 , 38 , 39 provided inside the fractionation tank 31 to measure the water level inside the fractionation tank 31 , and an alarm means 41 connected to the control means 25 . ) is further provided.

At this time, the discharge pipe 5 includes a first discharge part 5a connecting the radical water generating unit 4 and the fractionation tank 31 , and a second discharge part 5b extending from the fractionation tank 31 . is partitioned into

In the sorting tank 31, the first discharge part 5a is connected to the lower side of the periphery, and the second discharge part 5b is connected to the lower side, and is supplied through the first discharge part 5a. After the radical water is once stored therein, it is configured to be discharged to the second discharge unit 5b.

The first control valve 34 and the second control valve 35 are operated according to the control signal of the control means 25 to control the flow of ozone passing through the ozone discharge pipe 32 and the second air supply unit 6b. A solenoid valve is used to control it.

The discharge pump 36 is connected to the middle portion of the second discharge unit 5b, and according to the control of the control means 25, the flow rate per unit time is slightly compared to the flow rate per unit time of the water supply pump 3 . It is configured to adjust the driving speed in two steps, small or slightly large.

The first water level sensor 37 is located on the inner upper side of the sorting tank 31 , and the second water level sensor 38 is provided to be sufficiently spaced downward compared to the first water level sensor 37 . and the third water level sensor 39 is provided to be slightly spaced downward compared to the second water level sensor 38 .

At this time, the third water level sensor 39 is positioned higher than the position where the first discharge part 5a is connected to the sorting tank 31 .

The control means 25 receives the signals of the first to third water level sensors 37, 38 and 39, and the first and second control valves 34 and 35, the supply pump 33, and the discharge. configured to control the operation of the pump 36 .

The alarm means 41 is configured to output an alarm sound when operated.

The operation of the radical water generator configured as described above will be described as follows.

First, as shown in FIG. 2 , when the level of the radical water stored in the fractionation tank 31 is lower than the height of the first water level sensor 37 , the first control valve 34 is closed and , the second control valve 35 is opened, and the ozone generator 8 is turned on so that ozone generated from the ozone generator 8 passes through the second air supply unit 6b to the radical water generating unit 4 It is supplied to the water so that the ozone melted radical water is generated.

At this time, the control means 25 controls the flow rate per unit time of the discharge pump 36 so that the level of the radical water stored in the fractionation tank 31 maintains the height of the first water level sensor 37 . .

On the other hand, the ozone supplied to the radical water generating unit 4 is partially melted in water and the unmelted ozone is maintained in the form of air bubbles. When supplied, the ozone contained in the radical water is discharged to the upper part of the radical water, and is stored inside the upper part of the fractionation tank 31 .

And, when the amount of ozone stored in the upper side of the fractionation tank 31 is increased, the pressure is increased while the ozone is compressed, and the radical water stored in the fractionation tank 31 is discharged the second time by the increased pressure of ozone. The level of the radical water stored in the fractionation tank 31 is lowered by being pushed toward the part 5b.

And, as shown in FIG. 7 , when the water level inside the fractionation tank 31 is lowered to the height of the second water level sensor 38 , the control means 25 closes the second control valve 35 . and at the same time stopping the ozone generator 8, opening the first valve and driving the supply pump 33, so that the ozone stored in the fractionation tank 31 is transferred to the ozone discharge pipe 32 and the second grade It is supplied to the radical water generating unit (4) through the base (6b).

In this way, ozone stored in the fractionation tank 31 is discharged, and as shown in FIG. 8 , the level of the radical water stored in the fractionation tank 31 is determined by the level of the first water level sensor 37 . When it rises to a height, the control means 25 closes the first control valve 34 , stops the supply pump 33 , and opens the second control valve 35 , so that the ozone generator 8 ) is turned on so that ozone generated by the ozone generator 8 is supplied to the radical water generating unit 4 through the second air supply unit 6b.

On the other hand, in a state in which the ozone stored in the fractionation tank 31 is discharged to the radical water generating unit 4, the level of the radical water stored in the fractionation tank 31 does not rise, and as shown in FIG. When it descends to the height of the third water level sensor 39, the control means 25 stops the operation of the discharge pump 36, and after being supplied through the water supply pump 3, the radical water generating unit ( 4) and the generated radical water is stored in the fractionation tank (31).

At this time, if the level of the radical water stored in the fractionation tank 31 does not rise to the height of the second water level sensor 38 even after a preset time has elapsed, the control means 25 controls the ozone generator 8 It is determined that an excessive amount of ozone is generated or that an abnormality has occurred in the water supply pump 3 , and the alarm means 41 is operated to warn the operator.

In the radical water generator configured as described above, the air supply pump 7 and the ozone generator 8 are provided inside the metal cabinet 10, so that the air supply pump 7 and the ozone generator 8 are exposed to the outside. It has the advantage of preventing and making it easy to move or maintain the device.

In particular, the cabinet 10 includes a main body 11 having a door on the front side, and a partition plate 12 on which the ozone generator 8 is mounted on the upper surface by being provided to be spaced apart from each other in the vertical direction inside the main body 11 . ), and the upper surface of the diaphragm 12 is provided with a buffer pad 13 for supporting the middle portion of the air supply pump 7, the ozone generator 8, and the air supply pipe 6, so that the air supply pump (7) There is an advantage that can prevent noise and vibration from being generated in the cabinet 10 as the is operated.

In addition, an ozone concentration measuring sensor 21 provided on one side of the inside of the cabinet 10 to measure the ozone concentration of the air inside the cabinet 10, and one side of the ozone concentration measuring sensor 21 extending to the outside an exhaust pipe 22, an exhaust pump 23 provided in the exhaust pipe 22, and a heating means provided at the outer end of the exhaust pipe 22 to heat and decompose ozone discharged through the exhaust pipe 22 ( 24) and a control means 25 for receiving a signal from the ozone concentration measuring sensor 21 and controlling the operation of the exhaust pump 23 and the heating means 24, the ozone generator 8 or When an abnormality occurs in the air supply pipe (6) and ozone is leaked into the cabinet (10), the air inside the cabinet (10) is automatically discharged to the outside and at the same time ozone is heated using the heating means (24). By decomposing, there is an advantage in that ozone can be effectively prevented from leaking to the outside and polluting the surrounding environment.

In addition, the air supply pipe 6 includes a first air supply unit 6a connected to the ozone generator 8 and a second air supply unit 6b connecting the ozone generator 8 and the radical water generating unit 4 to each other. a division tank 31 provided in the middle of the discharge pipe 5, an ozone discharge pipe 32 extending on the upper surface of the division tank 31 and connected to the second air supply unit 6b; A supply pump 33 provided in the middle of the ozone discharge pipe 32, a first control valve 34 provided in the ozone discharge pipe 32, and the ozone generator ( 8) and a second control valve (35) provided between the connection part of the ozone discharge pipe (32), and a discharge pump (36) provided in the discharge pipe (5) to be located at the rear of the fractionation tank (31); , first to third water level sensors 37 , 38 , 39 provided inside the fractionation tank 31 to measure the water level inside the fractionation tank 31 , and an alarm means connected to the control means 25 . Further including (41), ozone contained in the radical water generated in the radical water generating unit 4 is separately stored, and then returned to the radical water generating unit 4 and used to generate the radical water. .

Therefore, there is an advantage in that it is possible to prevent ozone contained in the radical water from being discharged to the outside through the discharge pipe 5 to contaminate the surrounding environment.

1. Water supply pipe 2. Water supply means
3. Feed water pump 4. Radical water generating unit
5. Discharge pipe 6. Air supply pipe
7. Air supply pump 8. Ozone generator
10. Cabinet

Claims (3)

The water supply pipe (1) connected to the front end of the water supply means (2),
A water pump (3) provided in the middle of the water supply pipe (1),
a radical water generating unit (4) provided at the rear end of the water supply pipe (1) and connected to the discharge pipe (5);
an air supply pump (7) connected to the radical water generating unit (4) through an air supply pipe (6);
In the radical water generator including an ozone generator (8) connected to the middle of the air supply pipe (6) and generating ozone using air passing through the air supply pipe (6),
The air supply pump 7 and the ozone generator 8 are provided inside the metal cabinet 10,
The cabinet 10 is
A body 11 provided with a door on the front, and
It includes a diaphragm 12 provided to be spaced apart from each other in the vertical direction inside the main body 11 and on which the ozone generator 8 is mounted on the upper surface,
A buffer pad 13 is provided on the upper surface of the diaphragm 12 to support the middle portion of the air supply pump 7, the ozone generator 8, and the air supply pipe 6,
an ozone concentration measuring sensor 21 provided on one side of the inside of the cabinet 10 to measure the ozone concentration of the air inside the cabinet 10;
an exhaust pipe 22 extending from one side of the ozone concentration measuring sensor 21 to the outside;
an exhaust pump 23 provided in the exhaust pipe 22;
A heating means 24 provided at the outer end of the exhaust pipe 22 and heating and decomposing ozone discharged through the exhaust pipe 22;
Further comprising a control means (25) for receiving the signal of the ozone concentration measurement sensor (21) and controlling the operation of the exhaust pump (23) and the heating means (24),
The heating means 24 is
A metal case 24a extending in the vertical direction and having a cylindrical shape with an inner diameter narrowing downward, extending in the circumferential direction on one upper side and having a supply hole 24b to which the end of the exhaust pipe 22 is connected, and ,
A heating tube 24c having a circular tube shape extending in the vertical direction, the lower end passing through the central portion of the upper surface of the case 24a, extending to the lower inside of the case 24a, and having an electric heater 24d on the periphery. including,
A catalyst 24e for promoting ozone decomposition is applied to the inner circumferential surface of the case 24a and the inner circumferential surface of the heating tube 24c, the inner circumferential surface of the case 24a and the inner circumferential surface of the heating tube 24c,
The catalyst (24e) is a radical number generator, characterized in that any one of manganese dioxide (MnO2), ferrous oxide (Fe2O2), or nickel oxide (NiO).
delete The method of claim 1,
The air supply pipe (6) is divided into a first air supply unit (6a) connected to the ozone generator (8) and a second air supply unit (6b) connecting the ozone generator (8) and the radical water generating unit (4). becomes,
a fractionation tank 31 provided in the middle of the discharge pipe 5, an ozone discharge pipe 32 extending on the upper surface of the fractionation tank 31 and connected to the second air supply part 6b;
a supply pump 33 provided in the middle of the ozone discharge pipe 32;
a first control valve 34 provided in the ozone discharge pipe 32;
a second control valve (35) provided between the connection part of the ozone generator (8) and the ozone discharge pipe (32) in the second air supply part (6b);
a discharge pump (36) provided in the discharge pipe (5) to be located at the rear of the fractionation tank (31);
first to third water level sensors 37, 38 and 39 provided inside the fractionation tank 31 to measure the water level inside the fractionation tank 31;
Further comprising an alarm means (41) connected to the control means (25),
The discharge pump 36 is configured to adjust the flow rate per unit time according to the control of the control means 25,
The control means 25 opens the second control valve 35 to open the ozone generator when the water level inside the fractionation tank 31 rises to the height of the first water level sensor 37 located at the uppermost side. The ozone generated in (8) is supplied to the radical water generating unit (4), and radicals inside the fractionation tank (31) are caused by the atmospheric pressure of ozone discharged from the radical water introduced into the fractionation tank (31). When the water level is lowered to the water level of the second water level sensor 38 positioned lower than the first water level sensor 37, the second control valve 35 is closed and the ozone generator 8 is turned off. The first control valve 34 is opened and the supply pump 33 is driven so that the ozone stored in the fractionation tank 31 is converted into radicals through the ozone discharge pipe 32 and the second air supply unit 6b. It is supplied to the water generating unit 4, and when the level of the radical water inside the fractionation tank 31 is lowered to the height of the third water level sensor 39 located the lowest, the discharge pump 36 is stopped. If the water level inside the sorting tank 31 does not rise to the height of the second water level sensor 38, even if a preset time has elapsed, the alarm means 41 is turned on to warn the manager Radical water generator, characterized in that

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