KR101301413B1 - Apparatus for controlling of ozonizer - Google Patents

Abstract

PURPOSE: An ozonated water outflow control device in an ozonizer is adapted to use ozonated water which always exceeds the standard of ozone concentration. CONSTITUTION: An ozonated water outflow control device in an ozonizer includes an ozonizer (100) delivering ozonated water (110) generated by supplying water transmitted from an inlet port (121) to an outlet port (122), a first sensing unit (230) sensing the flow rate of the water introduced into a main inlet tube (311), a second control valve (220) controlling the water sensed in the first sensing unit to be flowed and cut off in the ozonizer, a first control valve (210) controlling the water sensed in the first sensing unit to be flowed and cut off in a main outlet (312) and a control unit (400) outputting a signal controlling opening and cutting motion of the first and the second control valves by sensing an inflow detection signal (S1) sensed in the first sensing unit. [Reference numerals] (100) Ozonizer; (400) Control unit; (500) Switching unit; (600) Power supply unit; (700) Power; (AA) Water; (BB) Ozone water

Description

Ozone water leakage control device of ozone generator {APPARATUS FOR CONTROLLING OF OZONIZER}

The present invention relates to a device for controlling the outflow of ozone (Ozone) water generated in the ozone generator, more specifically, the ozone generator is stopped again for a certain time and restarted every time after the stop time exceeded again The present invention relates to a technology for controlling warning display until ozone water generated at an ozone concentration above a reference level is released.

In general, ozone generators oxidize or neutralize pesticides or heavy metals that are harmful to the human body by generating ozone (O ₃ ), which has sterilization, disinfection, discoloration, deodorization, and bleaching due to strong oxidizing power. In addition, it is usefully used for water purification, sterilization and washing of waste water.

In particular, the ozone has a solubility in water of 0.105 g / 100ml at 0 ℃ it is possible to decompose toxic substances, such as phenol, cyan.

In addition, since the ozone is finally reduced to oxygen together with the purification ability, the ozone does not cause secondary pollution, and thus, ozone is widely used as an environmental improvement or pollution treatment means in response to harmful gases that generate tobacco smoke or odor.

Such an ozone generator mainly generates ozone by a silent discharge method which applies energy to air or oxygen by physical and chemical stimulation and a photochemical reaction method which irradiates ultraviolet rays.

In the ozone generator using the silent discharge method, an insulator such as glass or ceramics is sandwiched between driving electrodes for generating ozone facing each other, and a voltage is applied to the driving electrodes in a state in which they are exposed to the air, To generate ozone in the air passing through the ozone generator.

However, since the ozone generator using the silent discharge method described above requires only pure oxygen to be separated from the air containing a large amount of nitrogen, the amount of generated ozone is small and the operation of dissolving the generated ozone in water is troublesome There is a disadvantage in that the production cost is high because the structure is complicated.

In addition, the 'underwater ozone generator (this is referred to as' Document 1'), which is applied as a utility model registration application No. 20-2000-0019427 (July 06, 2000 filed) by the prior art is widely known.

(Hereinafter, referred to as "driving electrode") 53 is connected in series, and the current applied to the metal electrode 53 is applied to the constant current power source device 2, , And an ozone generator 5 in which a plurality of ozone generating tanks 5 for generating ozone by disposing an impeller 55 near an inlet of water are arranged in parallel.

However, such a conventional ozone generator causes a problem in that the ozone water below the reference value may be leaked out and used again when the driving is stopped and then restarted in a state in which the stop time is exceeded.

In addition, since the conventional ozonizer is configured such that the constant current is continuously supplied to the metal electrode only in one direction from the constant current power source 2, the metal electrode is ionized and dissolved in water, It gradually wears and becomes thinner.

Therefore, the distance between the metal electrodes is widened to increase the resistance value of the water, which results in a problem of reducing the generation of the ozone amount.

The present invention for solving the conventional problems as described above, the ozone water remaining in the main outlet pipe whenever the ozone generator is stopped for a predetermined time or restarted again in excess of the stop time, the ozone water below the reference value The purpose of this is to control the alarm display until the outflow and then use it again by releasing the ozone water generated with ozone concentration above the standard value.

In addition, the present invention supplies an alternating voltage of which polarity is changed at regular intervals to the ozone generating electrode provided in the ozone generator, thereby reducing wear of the driving electrode and maximizing ozone generation through two-way ozone generation. Another purpose is to make it possible.

As a constitutional means for solving the problems of the present invention as described above is installed in the main inlet pipe connected to the inlet side of the ozone generator and the ozone generator to discharge the ozone water generated by receiving the water introduced through the inlet to the outlet And a first control means for sensing the flow rate of the water flowing into the main inlet pipe and a second control valve for controlling the inflow and blocking of the ozone generator with respect to the water that has passed through the first detection means. .

In addition, one side is connected to the main inlet pipe between the second control valve and the first sensing means and is installed in the branch pipe connected to the other side of the main outlet pipe of the outlet side of the ozone generator, the first sensing means Characterized in that the first control valve for controlling the outflow and blocking of the main outlet pipe for coarse water.

And a control unit for outputting a control signal for controlling the blocking and opening operations of the first control valve and the second control valve by the determination of the flow rate detection signal sensed by the first sensing means. .

 On the other hand, another constituent means for solving the problem of the present invention comprises a switching unit for generating and supplying alternating voltage to the drive electrode of the ozone generator and a control unit for controlling the polarity holding time of the alternating voltage generated by the switching unit It is characterized by that.

In addition, the first inlet and connected to the main inlet pipe connected to the inlet side of the ozone generator, the first sensing means for sensing the flow rate of water flowing into the main inlet pipe and the water passing through the first sensing means to enter and block the ozone generator It characterized in that the second control valve configured to control the.

In addition, one side is connected to the main inlet pipe between the second control valve and the first sensing means, and another branch is connected to the main outlet pipe on the outlet side of the ozone generator, and the first sensing means is provided. It characterized in that it comprises a first control valve for controlling the outflow and shutoff to the main outlet pipe for coarse water.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

As described above, the present invention controls the alarm display until the ozone concentration remaining in the main outflow pipe is discharged below the reference value whenever the ozone generator is stopped for a predetermined time and restarted again after exceeding the stop time. By doing so, it provides a useful effect that can always use ozone water generated at ozone concentrations above the reference value.

In addition, the present invention by supplying the alternating voltage of the polarity change with a constant polarity maintenance time to the ozone generating drive electrode provided in the ozone generator, reducing the wear of the driving electrode for ozone generation and ozone through two-way ozone generation It provides another effect that makes the creation much smoother.

1 is a block diagram of a first exemplary embodiment schematically showing a device for controlling the outflow of ozone water generated in the ozone generator according to the present invention.
2 is a block diagram of a second exemplary embodiment schematically showing an apparatus for controlling the outflow of ozone water generated in the ozone generator according to the present invention.
3 is a view schematically showing the principle that ozone is generated through the drive electrode provided in the water tank of the ozone generator according to the present invention.
4 is a waveform diagram illustrating a generation period of an alternating voltage supplied to a driving electrode of an ozone generator according to the present invention.
5 is a diagram illustrating an operation state of the first control valve and the second control valve according to the flow rate detection signal detected by the first detection means according to the present invention.

In describing a specific embodiment of the present invention, it is illustrated by the drawings of the present invention, the configuration and operation thereof will be described as at least one embodiment, whereby the technical spirit of the present invention and its core Configurations and operations should not be limited.

For reference, in designating reference numerals in the drawings described in the present invention, it should be noted that the same components are given the same reference numerals as much as possible even though they are shown in other drawings. With reference to the configuration means or operation of the present invention will be described in detail.

The ozone generator 100 according to the present invention mainly produces ozone in water, which is a predetermined installation interval D1 so that the ozone generating drive electrodes P1 and P2 are opposed to each other. It is spaced apart and installed in a separate fixing means (not shown) in the water tank 101 of the ozone generator 100, by applying a constant current DC power to the drive electrodes (P1, P2) with alternating voltage to drive electrodes (P1, The water in the water tank 101 passing through P2) is electrolyzed to generate ozone (O ₃ ).

For example, a chemical reaction formula in which the ozonated water 110 is produced by the above-mentioned electrolysis will be described as follows.

First, when water in the water tank 101 is dissociated by electrolysis, oxygen and hydrogen generating reaction are performed as shown in equation (1).

???????? 2H ₂ O? O ₂ + 4H ⁺ + 4e ^- ????? (1)

Then, the ozone generating reaction as shown in the formulas (2) and (3) is carried out.

Equation (2): H ₂ O + O ₂ → O ₃ + 2H ⁺ + 2e ^-

Equation _{(3): 3H 2 O →} O 3 + 6H & lt ^; + & gt ^; + 6e ^-

Here, H represents hydrogen, O represents oxygen, H ₂ O represents water, and O ₃ represents ozone.

In addition, in the present invention, the ozone generator 100 is supplied with water such as ground water or tap water (also referred to as "raw water") introduced through the inlet 121 to generate the ozone water 110 after Ozone remaining in the main outlet pipe 312, which is a path through which the ozone water 110 flows out every time the ozone generator 100 is restarted in a state in which it is stopped for a predetermined time and exceeds the stop time H1. Alarm display control is performed until the concentration of the ozone water 110 below the reference value is pre-flowed, and the ozone water 110 generated at an ozone concentration above the reference value (for example, 0.1 ppm) is always discharged through the cock 240. It is characterized by that it can be used to spill.

Of course, the above-mentioned reference value of the ozone concentration is an example, which may vary depending on the purpose and purpose of using the ozone water (110).

1 is a block diagram illustrating a configuration of a mobile communication terminal according to an embodiment of the present invention;

The ozone generator 100 according to the present invention is a direct water through the water pipe or a storage tank installed separately through the main inlet pipe 311 is a water having a predetermined water pressure as shown in Figure 1 and 2 attached It is characterized in that the flow in the direction of the arrow (b) to the water tank 101 of the furnace ozone generator (100).

The water tank 101 may have various shapes and sizes such as a circular shape, a circular column shape, a rectangular shape, and the like. The water tank 101 may be formed using one ozone water 110 depending on the place, amount, purpose, Or parallel, serial, parallel, or the like.

When the cock 240 is open, the ozone generator 100 is main in the state in which the first control valve 210 made of a solenoid controlled valve of a normal-open type is open controlled. Water flowing in the direction of the arrow (A) through the inlet pipe 311 flows to the outlet cock 240 through the first sensing means 230, the first control valve 210 and the main outlet pipe 312. Will be done.

Subsequently, the ozone generator 100 of the present invention receives water introduced through the inlet 121 as shown in FIG. 3 and is generated by an alternating voltage supplied to the ozone generating drive electrodes P1 and P2. The ozone water 110 is discharged to the outlet cock 240 through the main outlet pipe 312 through the outlet 122.

In addition, the first detection installed in the main inlet pipe 311 connected to the inlet 121 side of the ozone generator 100 is provided with a flow sensor for sensing the flow rate of water flowing into the main inlet pipe 311 Normally-closed type solenoid valve (Solenoid Controlled Valve) to control the inflow and blocking of the ozone generator 100 with respect to the water passed through the means 230 and the first sensing means 230 The second control valve 220 is composed of.

In addition, one side is connected to the main inlet pipe 311 between the second control valve 220 and the first sensing means 230 and the main outlet pipe 312 on the outlet 122 side of the ozone generator 100. The other side is formed in the branch pipe 313 is connected to made of the above-mentioned solenoid valve to control the outflow and blocking to the main outflow pipe 312 for the water passed through the first sensing means 230 The first control valve 210 is configured.

In addition, a closed and open operation of the first control valve 210 and the second control valve 220 is performed by the determination of the flow rate detection signal S1 detected by the first detection means 230. It characterized in that it comprises a control unit 400 for outputting a control signal for controlling the.

FIG. 1 is a block diagram illustrating a configuration of an image forming apparatus according to an embodiment of the present invention; FIG.

The present invention by supplying an alternating voltage to the needle-shaped pointed ozone generating electrode (P1, P2) of the needle type provided with at least one in the ozone generator 100, as shown in FIG. The water passing through the driving electrodes P1 and P2 is electrolyzed to generate ozone (O ₃ ).

Here, the driving electrodes (P1, P2) may be provided in a variety of circular, flat plate, saw blade shape, mesh type, in addition to the needle shape mentioned above, furthermore, the main inlet pipe ( 311) is provided with a plurality of drive electrodes (P1, P2) according to the type, temperature, hardness, flow rate, etc. of water introduced into the water tank 101 of the ozone generator 100, or connected in series or in parallel It may be desirable to prevent the ozone concentration of ozone water 110 from being lowered by the configuration.

In other words, the kind of water flowing in the direction of the arrow (b) into the water tank 101 of the ozone generator 100 through the main inlet pipe 311. For example, in the case of ground water, iron containing minerals or tap water. Including the contained water, since the electrical resistance value is not constant according to the flow rate of the water flowing into the water tank 101, it is difficult to generate the ozone concentration of the ozone water 110 above the above-mentioned reference value.

To this end, the present invention changes the resistance value according to the type of water introduced into the water tank 101 of the ozone generator 100 through the main inlet pipe 311 as mentioned above, or through the main inlet pipe 311. The power supply unit 600 for supplying a constant current power to the drive electrodes (P1, P2) of the ozone generator 100 to generate the ozone water 110 according to the flow rate of the water flowing into the water tank 101 of the ozone generator 100 is configured Will let you.

For example, the power supply unit 600 is configured to output a suitable voltage in the range of 20 to 120 volts (V), which is the resistance value of water flowing between the ozone generating driving electrodes (P1, P2) by the control unit 400. When the voltage is high, the voltage is changed high. On the contrary, when the resistance value of the water is low, the voltage is decreased. The power 700 is supplied from the outside through the switch SW1 to the power supply unit 600. It becomes the structure that becomes.

On the other hand, the alternating voltage is generated by the constant current power output from the power supply unit 600 to supply to the drive electrodes (P1, P2) provided in the tank 101 of the ozone generator 100, in particular the drive electrodes (P1, P2) is characterized in that the switching unit 500 is configured to reduce the wear of the surface and to maximize the generation of ozone water 110 through the generation of two-way ozone at the alternating voltage.

In other words, when the current generated by the power supply unit 600 is supplied to the driving electrodes P1 and P2, the resistance value increases because an electric double layer is formed near the driving electrodes P1 and P2. It acts as a factor, resulting in a decrease in current, which in turn has an effect of reducing the amount of ozone.

In addition, since impurities such as iron are adsorbed on the surfaces of the driving electrodes P1 and P2, the volume of the driving electrodes P1 and P2 increases, which also acts as a factor of increasing the resistance value. As a result, the current decreases, which in turn affects the amount of ozone.

On the other hand, since the driving electrodes P1 and P2 are ionized and dissolved in water, the surface of the driving electrodes P1 and P2 made of a metal material is worn down and thinned, which causes the driving electrodes P1 and P2 to be thinned. The installation interval D1 between P2) becomes wider than the initial stage, so that the resistance value of water proportional to the installation interval D1 increases, which also acts as a factor for reducing the amount of ozone.

In order to prevent this, the present invention, when the material of the driving electrodes (P1, P2) is provided with platinum or platinum plating, the driving electrodes (P1) according to the prevention of ionization due to the generation of scale of the driving electrodes (P1, P2) , P2) It can reduce the wear of the surface, and when the surface of the drive electrodes (P1, P2) is worn out by adjusting or replacing the installation interval (D1) as narrow as the initial state, thereby smoothly improving ozone production It would be desirable to give.

Furthermore, the present invention generates a constant current power output from the power supply unit 600 through the switching unit 500 as an alternating voltage as shown in the accompanying Figure 3, and then supply it to the driving electrodes (P1, P2), A useful function of preventing surface wear of the driving electrodes P1 and P2 is provided.

At this time, the polarity holding time (T1) for the alternating voltage of the +,-polarity generated by the switching unit 500 and supplied to the driving electrodes (P1, P2) in the control unit 400 as shown in FIG. While controlling for 15 seconds is advantageous for preventing abrasion on the surfaces of the driving electrodes P1 and P2, the installation intervals D1 of the driving electrodes P1 and P2 provided in the water tank 101 and the kind of water, flow rate, temperature and hardness In consideration of various environmental factors such as water pressure, it is characterized in that the control is made in the controller 400 in a range of 10 to 20 seconds.

At this time, the polarity switching waiting time T2 between the polarity holding time T1 is controlled to 0.5 seconds to improve the generation of the ozone water 110 including the driving electrodes P1 and P2 and the circuit of the switching unit 500. Advantageous protection, but in view of this, it will be preferable to control in the control unit 400 in the range of 0.1 to 2 seconds.

In other words, if the polarity switching wait time T2 is too short, the amount of generated ozone water 110 increases, but the load on the circuit of the switching unit 500 may be burdensome. On the other hand, The amount of the generated ozone water 110 may be reduced, which is advantageous for circuit protection of the switching unit 500.

On the other hand, the control unit 400 detects (or "detects") the current i1 output from the switching unit 500 in response to the change in the flow rate detected by the first sensing unit 230. And a voltage variable control signal to supply the constant current power to the switching unit 500 by comparing the current i1 sensed by the second sensing unit 510 with a reference current io. ) Will be outputted.

In addition, the main inlet pipe 311 is connected to the inlet 121 side of the ozone generator 100, is installed for detecting the flow rate of water flowing into the main inlet pipe 311 in the direction of the arrow (a) The solenoid valve of the above-mentioned Normal-Closed Type to control the inflow and blocking of the ozone generator 100 with respect to the water passing through the first sensing means 230 and the first sensing means 230. The second control valve 220 is composed of a (Solenoid Controlled Valve).

In addition, one side is connected to the main inlet pipe 311 between the second control valve 220 and the first sensing means 230 and the main outlet pipe 312 on the outlet 122 side of the ozone generator 100. Another side is installed in the branch pipe 313 is connected to, through the first sensing means 230 to control the outflow and blocking to the main outflow pipe 312 for the water flowing in the direction of the arrow (a) It characterized in that it comprises a first control valve 210 consisting of the above-mentioned solenoid valve to give.

Next will be described in more detail with respect to the configuration means and operation included in the above-mentioned embodiments of the present invention.

First, in the present invention, the above-mentioned control unit 400 is connected to the first control valve 210 and the second control valve 220 according to the determination of the flow rate detection signal S1 detected by the first detecting means 230. It is characterized in that for outputting a control signal for controlling to close relative to (Closed) and Open (Open) operation.

When the flow rate detection signal S1 detected by the first sensing unit 230 is determined (Yes), the controller 400 generates a constant current power and drives the power supply unit 600 to supply the switching unit 500. Subsequently, an operation of outputting a control signal to drive (On) the switching unit 500 which generates and supplies an alternating voltage to the ozone generator 100 is performed.

In addition, if the flow rate detection signal S1 detected by the first sensing unit 230 is not determined (No), the controller 400 generates a constant current power and supplies the power supply unit 600 to the switching unit 500. In order to turn off the switching unit 500 that generates and supplies an alternating voltage to the ozone generator 100, an operation of outputting a control signal is performed.

In addition, the controller 400 opens the second control valve 220 when the flow rate detection signal S1 detected by the first sensing unit 230 is determined (Yes), as shown in FIG. 5. The control signal is output and the control signal is output in order to close the first control valve 210 which performs the relative operation.

In addition, the controller 400 opens the first control valve 210 when the flow rate detection signal S1 detected by the first sensing unit 230 is not determined (No), as shown in FIG. 5. Open) control and outputs a control signal in order to close the second control valve 220 that operates relatively in correspondence thereto.

On the other hand, in the present invention, the ozone generator 100 is stopped for a predetermined time (for example, 5 minutes or more depending on the use environment) and then generated each time the ozone water is generated again when exceeding the stop time (H1) ( The display unit 410 is provided in the display unit 410 during the elapsed time (H2) until the 110 is discharged through the passage (L1) to the outlet cock 240 through the main outlet pipe 312 through the outlet (122). 1 display means 411 to give a warning display.

In addition, when the elapsed time (H2) has passed, for example, the first display means 411, for example, the red warning display is off (Off) and at the same time provided in the display unit 410, for example, the green second display means 412 Control On to give warning display.

At this time, the first display means 411 and the second display means 412 provided in the display unit 410 using a display lamp such as an LED (LED), or variously displayed to the user by voice, melody, etc. Giving will also be possible.

Here, the display control for the stop time (H1) and the elapsed time (H2) is set in the setting unit 800, which is controlled through the control unit 400.

As described above, in the present invention, the ozone generator 100 receives the water introduced through the inlet 121 to generate the ozone water 110, and then stops for more than a predetermined time and then restarts again in a state exceeding the stop time (H1). Each time it is driven through the first display means 411 until the ozone concentration 110 in the main outflow pipe 312, which is the path through which the ozone water 110 flows out, is mostly pre-flowed. By performing the alarm display control, the user always generated ozone water 110 with an ozone concentration above the reference value (for example, usually 0.1 ppm or more, which may vary depending on the purpose or purpose of using the ozone water 110). It is to be used.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention.

Accordingly, the technical scope of the present invention should be defined by the claims of the present invention, rather than being limited to those described in various embodiments as mentioned above.

100: ozone generator
101: aquarium
110: ozonated water
121: inlet
122: Outlet
210: first control valve
220: second control balance
230: first detection means
240: Cock
311: Main inlet pipe
312: main outlet pipe
313: Branch organization
400:
410: display unit
411: first display means
412: second display means
500: switching part
510: second sensing means
600:
700: Power supply
800: Setting unit

Claims (14)

An ozone generator (100) for allowing the ozone water (110) generated by receiving the water introduced through the inlet (121) to the outlet (122);
The first sensing means 230 and the first sensing means installed in the main inlet pipe 311 connected to the inlet 121 side of the ozone generator 100 to detect the flow rate of water flowing into the main inlet pipe 311 A second control valve 220 for controlling the inflow and blocking of the ozone generator 100 with respect to the water having passed through the means 230;
One side is connected to the main inlet pipe 311 between the second control valve 220 and the first sensing means 230 and is further connected to the main outlet pipe 312 on the outlet 122 side of the ozone generator 100. It is installed in the branch pipe 313 connected to the other side, the first control valve 210 for controlling the outflow and blocking the main outflow pipe 312 for the water passed through the first sensing means 230 is provided Become,
The control signal for controlling the blocking and opening of the first control valve 210 and the second control valve 220 by the determination of the flow rate detection signal (S1) detected by the first detecting means 230 Ozone water outflow control device of the ozone generator, characterized in that it comprises a control unit for outputting. According to claim 1, When the flow rate detection signal (S1) detected by the first detecting means 230 is determined, the alternating voltage is generated in the ozone generator 100 following the driving of the power supply unit 600 for generating a constant current power The ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal from the control unit 400 to drive the switching unit 500 to supply. According to claim 1, If the flow rate detection signal (S1) detected by the first detecting means 230 is not determined, by supplying alternating voltage to the power supply unit 600 and the ozone generator 100 for generating a constant current power supply The ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal from the control unit 400 to turn off the switching unit 500. According to claim 1, When the flow rate detection signal (S1) detected by the first detecting means 230 is determined, by opening the second control valve 220 and by blocking the first control valve 210 Ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal from the control unit 400. According to claim 1, If the flow rate detection signal (S1) detected by the first detecting means 230 is not determined, the first control valve 210 is opened and the second control valve 220 is blocked. The ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal from the control unit 400. Control unit for controlling the polarity holding time (T1) of the alternating voltage generated by the switching unit 500 and the switching unit 500 to generate and supply the alternating voltage to the driving electrodes (P1, P2) of the ozone generator ( 400),
The first sensing means 230 and the first sensing means installed in the main inlet pipe 311 connected to the inlet 121 side of the ozone generator 100 to detect the flow rate of water flowing into the main inlet pipe 311 A second control valve 220 for controlling the inflow and blocking of the ozone generator 100 with respect to the water having passed through the means 230;
One side is connected to the main inlet pipe 311 between the second control valve 220 and the first sensing means 230 and is further connected to the main outlet pipe 312 on the outlet 122 side of the ozone generator 100. It is installed in the branch pipe 313 connected to the other side, and includes a first control valve 210 for controlling the outflow and blocking to the main outflow pipe 312 for the water passed through the first sensing means 230 Ozone water outflow control device of the ozone generator, characterized in that. The first control valve 210 and the second control valve 220 according to claim 1 or 6, wherein the controller 400 determines the flow rate detection signal S1 detected by the first sensing means 230. The ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal for relatively corresponding control of the blocking and open operation. The flow control apparatus of claim 6, wherein the controller 400 determines the flow rate detection signal S1 detected by the first sensing means 230 to drive the switching unit 500 following the driving of the power supply unit 600. Ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal. The control signal of claim 6, wherein the control unit 400 turns off the power supply unit 600 and the switching unit 500 when the flow rate detection signal S1 detected by the first detection unit 230 is not determined. Ozone water outflow control device of the ozone generator, characterized in that for outputting. The method of claim 6, wherein the controller 400, when the flow rate detection signal S1 detected by the first sensing means 230 is determined, opens the second control valve 220 and opens the first control valve ( The ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal for blocking 210. The second control valve of claim 6, wherein if the flow rate detection signal S1 detected by the first detection unit 230 is not determined, the control unit 400 opens the first control valve 210 and opens the second control valve. Ozone water outflow control device of the ozone generator, characterized in that for outputting a control signal for blocking (220). The polarity holding time (T1) according to any one of claims 2, 3, and 6, wherein the polarity holding time (T1) is generated by the switching unit (500) and supplied to the driving electrodes (P1, P2). To 20 seconds, and the polarity switching waiting time (T2) between the polarity holding time (T1) is 0.1 to 2 seconds range ozone water outflow control device. The ozone generator (110) according to claim 1 or 6, wherein the ozone generator (110) is generated whenever the ozone generator (100) is restarted in a state exceeding the stop time (H1), and the main outlet pipe (312) through the outlet (122). The first display means 411 displays a warning for the elapsed time (H2) until the outflow through the section (L1) leading to the outflow cock 240 through), the stop time (H1) and the elapsed time ( Display control for the H2) ozone water outflow control device of the ozone generator, characterized in that set through the setting unit (800). According to claim 1 or claim 6, wherein the control unit 400 is the second sensing means (510) the current (i1) output from the switching unit 500 in accordance with the change in the flow rate detected by the first sensing means (230) And a voltage variable control signal to the power supply unit 600 to supply a constant current power to the switching unit 500 by comparing the current i1 detected by the second sensing unit 510 with the reference current io. Ozone water outflow control device of the ozone generator, characterized in that output.

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