JPH07256277A - Ozone water generator - Google Patents

Abstract

(57) [Abstract] [Purpose] The present invention is directed to reducing the use of ozone water.
Alternatively, it is an object of the present invention to provide an ozone water generation device configured so that the concentration of ozone water reaches a target value when the ozone water decreases. [Structure] The ozone water generating apparatus 1 generally includes a concentration meter 19 for detecting the concentration of ozone water in a gas-liquid separator 18, and a flow meter 2 for measuring the flow rate of ozone water discharged from a pump 24.
6, a recirculation pipe line 33 for recirculating the ozone water discharged from the pump 24 to the ejector 13, a recirculation on-off valve 34 arranged in the recirculation pipe line 33, and a flow meter 26 to keep the ozone water below a predetermined flow rate. When it is detected that the concentration has decreased and the concentration meter 19 has detected that the concentration of the ozone water in the gas-liquid separation device 18 has dropped below a predetermined lower limit value, the pump 2
4 and a control circuit 29 for opening the recirculation on-off valve 34.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ozone water producing apparatus, and more particularly to an ozone water producing apparatus configured to adjust the concentration of ozone water so that the concentration of the ozone water becomes a certain value or more.

[0002]

2. Description of the Related Art For example, in an ozone water generator for generating ozone water used in an ozone contact tank of a purification facility, a fish culture tank, a hydroponic dissolution tank, etc., an ozone gas generated by an ozone generator is used as an ejector. Mixing gas and liquid by mixing pump to produce higher concentration ozone water.

A conventional ozone water generator uses high-concentration oxygen supplied from an air or oxygen cylinder or an oxygen generator of PSA (Pressure Swing Adsorption) separation method as a raw material, and discharges or electrolyzes in an ozone gas generator. After generating ozone gas by ultraviolet rays, the ejector mixes the ozone gas and the liquid to generate high-concentration ozone water. Furthermore, the ozone water generator supplies a water flow mixed with ozone gas into the gas-liquid separation tank through a pipe inserted into the gas-liquid separation tank, and extra undissolved ozone gas is supplied to the upper space of the gas-liquid separation tank. It is designed to be guided to and collected.

[0004]

In the ozone water producing apparatus having the above-mentioned structure, in order to produce ozone water having a desired concentration, the amount of ozone water supplied into the gas-liquid separation tank and the ozone gas from the ozone gas generator are generated. The amount generated was adjusted. However, because the ozone water concentration was not stabilized by external factors (temperature and flow rate), it was difficult to obtain ozone water of any desired concentration, and it took a considerable amount of time to reach the prescribed concentration, so handling was difficult. was difficult.

When the use of ozone water on the downstream side is reduced or stopped, the supply of ozone water to the gas-liquid separation tank is stopped, so that the ozone gas contained in the ozone water in the gas-liquid separation tank is removed. By gradually separating, the ozone concentration will considerably decrease by the time when the use of ozone water increases or resumes to be used on the downstream side, and it is necessary to wait until the ozone concentration reaches a desired concentration.

As described above, in order to generate high-concentration ozone water by the above-mentioned method, when the use of ozone water is reduced or stopped, the standby time is long when the use of ozone water is increased or restarted. There is a problem such as.

As a method of solving this, it is considered that ozone water taken out from the gas-liquid separation tank is pumped by a pump and half of the discharged amount is returned to the ejector. However, since ozone water is sent to the downstream side and the ejector, it is necessary to increase the pump capacity with respect to the amount used on the downstream side, resulting in an increase in the size of the entire apparatus.

[0008] Therefore, an object of the present invention is to provide an ozone water producing apparatus that solves the above problems.

[0009]

The invention according to claim 1 is
Ozone gas generating means for generating ozone gas having a concentration according to the supplied voltage value, gas-liquid mixing means for mixing the ozone gas generated by the ozone gas generating means with a liquid, and the ozone generated by the gas-liquid mixing means A gas-liquid separation tank for separating excess ozone gas contained in water, a concentration detecting means for detecting the concentration of ozone water in the gas-liquid separation tank, and ozone water taken out from the gas-liquid separation tank to the downstream side. A liquid sending conduit for sending a liquid, a pump disposed in the liquid sending conduit for sending the ozone water generated by the gas-liquid mixing means to a downstream side, and a pump branched from the liquid sending conduit, A reflux pipe for returning a part of the ozone water discharged from the gas-liquid mixing means to the gas-liquid mixing means, an opening / closing valve arranged in the reflux conduit, and ozone water in the gas-liquid separation tank by the concentration detecting means. Concentration is below the specified lower limit When the beat has is detected,
And a control means for opening the on-off valve.

Further, the invention of claim 2 includes an ozone gas generating means for generating ozone gas having a concentration according to the supplied voltage value, and a gas-liquid mixing means for mixing the ozone gas generated by the ozone gas generating means with a liquid. A gas-liquid separation tank for separating excess ozone gas contained in the ozone water generated by the gas-liquid mixing means, a concentration detection means for detecting the concentration of ozone water in the gas-liquid separation tank, and the gas-liquid A liquid feed conduit for feeding the ozone water taken out from the separation tank to the downstream side, and a pump arranged in the liquid feed conduit for feeding the ozone water generated by the gas-liquid mixing means to the downstream side. A flow meter disposed downstream of the pump in the liquid supply conduit and configured to measure a flow rate discharged from the pump; and a branch from the liquid supply conduit between the flow meter and the pump, The discharged ozone water A reflux pipe for returning a part of the ozone gas to the gas-liquid mixing means, an on-off valve arranged in the reflux pipe, and the flow meter for reducing the ozone water flowing in the liquid sending pipe to a predetermined flow rate or less. When it is detected that the concentration of ozone water in the gas-liquid separation tank is lower than a predetermined lower limit value by the concentration detecting unit, the control unit opens the on-off valve. Characterize.

[0011]

According to the first aspect of the invention, when the concentration detecting means detects that the concentration of the ozone water in the gas-liquid separation tank has fallen below the predetermined lower limit value, the on-off valve provided in the branch pipeline is opened. By opening the valve, it is possible to take out a desired high-concentration ozone water at any time, and the standby time at the start of using ozone water can be shortened.

According to the second aspect of the present invention, it is detected by the flow meter that the ozone water flowing through the liquid feed pipe has decreased to a predetermined flow rate or less, and the concentration detecting means determines the concentration of the ozone water in the gas-liquid separation tank. When it is detected that the water content has dropped below the lower limit, the open / close valve provided in the branch pipe is opened to extract the desired high-concentration ozone water according to the amount of ozone water used on the downstream side. This makes it possible to shorten the waiting time at the start of using ozone water.

[0013]

1 and 2 show one embodiment of the ozone water producing apparatus according to the present invention.

In both figures, the ozone water generating apparatus 1 is generally composed of an oxygen gas generating section 2, an ozone gas generator (ozone gas generating means) 3 and an ozone water generating section 4. The oxygen gas generation unit 2 is, for example, a PSA (Pressure Swing Adsorpti).
on) Oxygen with a higher concentration than in the atmosphere is separated and produced by the separation method. An oxygen supply means other than the PSA separation method may be used as the oxygen gas generation unit 2.

Here, the structure of the oxygen gas generator 2 when the PSA separation method is used will be described.

The oxygen gas generating section 2 uses an air compressor 5 for compressing air in the atmosphere, an air dryer 6 for dehumidifying the compressed air supplied from the air compressor 5, and a compressed air supplied from the air dryer 6 as a raw material. Gas (air has 78 nitrogen
%, Oxygen is 18%, and the rest is other components), a pair of adsorption tanks 7 for separately generating oxygen molecules contained in the air,
8 and an oxygen gas tank 9 for storing the oxygen gas taken out from the pair of adsorption tanks 7, 8.

The pipes connecting the air dryer 6 and the pair of adsorption tanks 7 and 8 and the pipes connecting the pair of adsorption tanks 7 and 8 to the gas tank 9 have valves V _{1 to} V _{8 formed of} solenoid valves. Is provided. The adsorption tanks 7 and 8 are filled with an adsorbent (not shown) made of zeolite. This zeolite adsorbs nitrogen molecules contained in the compressed air when the compressed air compressed by the air compressor 5 is supplied into the adsorption tanks 7 and 8 and the pressure inside the adsorption tanks 7 and 8 is increased. Then, the remaining oxygen molecules in the adsorption tanks 7 and 8 which are not adsorbed by the zeolite are taken out.

Therefore, by controlling the opening and closing of each of the valves V _{1 to} V ₈ , the adsorption tanks 7 and 8 are alternately operated from the pressure increasing step (adsorption), the pressure reducing step (regeneration), the extraction step, the pressure equalizing step, and the reflux step. The high-concentration oxygen gas whose oxygen concentration is concentrated to about 90% by repeating the oxygen production cycle
Supply to.

In the adsorption tanks 7 and 8, a high-concentration oxygen gas is alternately taken out by shifting a series of oxygen generation cycles by 180 ° so that one of them is a pressure increasing step and the other is a depressurizing step. each valve V ₁ ~V ₈ is opened and closed controlled. Moreover, the opening and closing control of the valve V ₁ ~V ₈ per each step is performed as follows.

At the time of the pressure rising step, the valve V ₁ or V
Open only ₂ and keep the other valves closed. As a result, compressed air is supplied to the adsorption tank 7 or 8.

In the pressure reducing step, the valve V ₃ or V
Open only ₄ and keep other valves closed. As a result, the nitrogen gas in the adsorption tank 7 or 8 is exhausted to the atmosphere.

In the take-out step, the valve V ₅ or V
Open only ₆ and keep other valves closed. As a result, oxygen molecules other than nitrogen adsorbed by the zeolite in the adsorption tank 7 or 8 are taken out and supplied to the oxygen gas tank 9.

In the pressure equalizing step, the valves V ₇ and V ₈
Open only one valve and keep the other valves closed. As a result, the pressure in the adsorption tanks 7 _and 8 becomes uniform.

The oxygen gas tank 9 of the oxygen gas generating section 2 having the above-mentioned structure is connected to the ozone generator 3 through the take-out pipe line 10. A take-out valve 11 which is an electromagnetic valve is arranged in the take-out conduit 10. Therefore, when the extraction valve 11 is opened, the oxygen gas in the oxygen gas tank 9 is supplied to the ozone gas generator 3.

The ozone gas generator 3 is configured to generate ozone (O ₃ ) by a silent discharge method, for example, and applies a voltage between the electrodes to generate a silent discharge to generate ozone (O ₃ ). The high-concentration oxygen gas generated by the oxygen gas generator 2 is supplied to the ozone gas generator 3 from the oxygen gas tank 9, so that the ozone gas can be continuously generated.

The ozone water generator 4 includes an ejector (gas-liquid mixing means) 13 for mixing the ozone gas generated by the ozone gas generator 3 into the water flow, and the ozone gas generator 3.
Ozone gas supply conduit 14 that connects the ejector 13 with the ejector 13.
Ozone gas supply valve 15 and ejector 13
And a water storage tank (not shown), the water supply valve 17 arranged in a water supply pipe 16 and a gas-liquid separation device 18 for separating undissolved ozone gas contained in ozone water supplied from the ejector 13. And a densitometer (concentration detecting means) 19 for measuring the concentration of ozone water generated by the gas-liquid separator 18.
And consists.

Further, the internal flow path of the ejector 13 is tapered so that the water supplied from the water supply pipe 16 is accelerated in the ejector 13. Ozone gas supply line 14
The ozone gas supplied from the ozone generator 3 via
The water flow accelerated in the ejector 13 is sucked and mixed to form high-concentration ozone water.

Therefore, the ozone gas supplied from the ozone generator 3 is sucked by the suction force of the water flow accelerated in the ejector 13, and becomes dissolved ozone gas to be mixed into the water flow. The ozone water mixed with the ozone gas in this way is passed through the ozone water supply pipe 20 and the gas-liquid separation device 18
Is supplied to.

The gas-liquid separation device 18 includes a first gas-liquid separation tank 21 to which the ozone water mixed by the ejector 13 is supplied via an ozone water supply pipe 20, and a first gas-liquid separation tank 21.
And a second gas-liquid separation tank 22 for separating undissolved ozone gas that could not be separated in step 2. The first gas-liquid separation tank 21 formed in a cylindrical shape is provided inside the gas-liquid separation device 18, and the second gas-liquid separation tank 22 is provided around the first gas-liquid separation tank 21. .

Therefore, the ozone water overflowing in the first gas-liquid separation tank 21 flows into the second gas-liquid separation tank 22 and is connected to the bottom of the second gas-liquid separation tank 22. It is fed to the downstream side via 23. Thus, the ozone water flows upward from the bottom of the first gas-liquid separation tank 21, and further, while flowing to the bottom of the second gas-liquid separation tank 22, excess undissolved ozone gas is separated.

Therefore, in the ozone water taken out from the second gas-liquid separation tank 22, unnecessary undissolved ozone gas is separated and only dissolved ozone gas is dissolved. Therefore, the ozone concentration of the ozone water becomes uniform, and the undissolved ozone gas will not be discharged as large bubbles when the ozone water is used on the downstream side.

Further, a pump 24 for pressure-fed ozone water, an opening / closing valve 25 composed of a solenoid valve, and a flow meter 26 for measuring the supply amount of ozone water are provided in the ozone water supply conduit (liquid supply conduit) 23.
And are provided. The pump 24 need not have a large size because it is sufficient that the pump 24 has a capacity capable of supplying ozone water only to one of the ozone water supply pipe 23 and a return pipe 33 described later.

Reference numeral 33 is a reflux pipe, one end of which is connected to the ozone water supply pipe 23 between the pump 24 and the on-off valve 25, and the other end of which is connected to the water supply pipe 16. This return line 33
A recirculation on-off valve 34, which is an electromagnetic valve, is provided in the.

This recirculation on-off valve 34 is normally closed, but as will be described later, it is detected by the flow meter 26 that the ozone water flowing through the ozone water supply conduit 23 has decreased below a predetermined flow rate, and When it is detected by the densitometer 19 that the concentration of ozone water in the gas-liquid separation tank 22 has fallen below a predetermined lower limit value, the valve is opened. In addition, the return on-off valve 34 is
Regardless of the flow rate, the valve may be opened when the concentration meter 19 detects that the concentration of ozone water in the gas-liquid separation tank 22 has dropped below a predetermined lower limit value.

When the recirculation on-off valve 34 is opened, the ozone water pumped by the pump 24 passes through the branch pipe 33, is fed to the water feed pipe 16, and is further fed to the ejector 13.

Further, the undissolved ozone gas separated by the gas-liquid separation device 18 accumulates in the upper space of the gas-liquid separation device 18,
It is supplied to the ozone decomposer 28 via the ozone gas recovery pipe 27. The ozone decomposer 28 is provided therein with activated carbon or a catalyst for decomposing ozone gas into oxygen gas, and detoxifies the undissolved ozone gas supplied via the ozone gas recovery pipe 27 into the atmosphere. To do.

The control circuit 29 controls the ozone gas generator 3 described above.
When the ozone water concentration drops below a desired concentration due to a data table of the relationship between the voltage value applied to and the concentration of ozone water, or the detection signals from the densitometer 19 and the flow meter 26,
Or if the use of ozone water is stopped for more than a predetermined time,
It has a memory (ROM) 30 in which a program for driving and controlling the pump 24 and the return valve 34 is stored. When the detection signals from the densitometer 19 and the flow meter 26 are input to the memory 30, the concentration for adjusting the voltage value applied to the ozone gas generator 3 so that the ozone water concentration becomes the concentration target value. Stores the adjustment program.

Reference numeral 31 is a concentration setting device for setting the concentration of ozone water, which is capable of inputting numerical values like a ten-key pad. That is, when the concentration setter 31 is operated, the ozone water concentration target value is registered in the memory 30 via the control circuit 29.

A voltage regulator 32 adjusts the voltage value applied to the ozone gas generator 3 according to a command from the control circuit 29 and supplies the commanded voltage to the ozone gas generator 3.

In the ozone water producing apparatus 1 having the above structure, when the use of ozone water decreases, the ozone water in the gas-liquid separator 18 becomes stagnant, and the ozone gas dissolved in the ozone water is correspondingly stagnated. When separated, the ozone water concentration gradually decreases.

Therefore, the control circuit 29 performs interrupt processing for detecting the flow rate and concentration of ozone water at predetermined time intervals, as will be described later, so that the amount of ozone water used on the downstream side is reduced or ozone water is used. Is stopped and the ozone water concentration decreases, or such ozone water recirculation processing is executed.

When it is detected by the concentration meter 19 that the concentration of ozone water in the gas-liquid separator 18 has fallen below a predetermined lower limit value, the recirculation on-off valve 34 provided in the recirculation conduit 33 is opened. As a result, the ozone water of the gas-liquid separator 18 is returned to the ejector 13 to accelerate the rise of the ozone water concentration of the gas-liquid separator 18.

According to the second aspect, it is detected by the flow meter 26 that the ozone water flowing through the ozone water supply pipeline 23 has decreased to a predetermined flow rate or less, and the concentration meter 19 detects the ozone water of the gas-liquid separation device 18. When it is detected that the concentration has dropped below the predetermined lower limit value, the on-off valve 34 for recirculation provided in the recirculation conduit 33 is opened to recirculate the ozone water of the gas-liquid separation device 18 to the ejector 13. Then, the rise of the ozone water concentration of the gas-liquid separation device 18 is accelerated.

Here, the ozone water concentration adjusting process executed by the control circuit 29 will be described, and then the ozone water recirculating process will be described.

In FIG. 2, the control circuit 29 executes the following processing based on the density adjusting program.

First, in step S1 (hereinafter "step" is omitted), the ozone water concentration A input by the concentration setter 31 is set. The target value of the ozone water concentration A has an allowable range of about ± a.

Next, in S2, it is confirmed whether or not the ozone water concentration A input by the concentration setter 31 has been set. When it is not confirmed in S2 that the setting of the ozone water concentration A is confirmed, the process returns to S1 and the ozone water concentration A input by the concentration setting device 31 is set again.

At the next step S3, the voltage supplied to the ozone gas generator 3 is calculated from the data table stored in the memory 30, and the voltage value is output to the voltage regulator 32.
Therefore, the voltage adjuster 32 adjusts the supply voltage to the voltage value instructed by the control circuit 29.

As a result, the ozone gas generator 3 generates ozone gas by the voltage applied from the voltage regulator 32. Furthermore, the ozone gas supplied from the ozone generator 3 is sucked by the suction force of the water flow accelerated in the ejector 13, becomes dissolved ozone gas, and is mixed into the water flow. Then, the ozone water mixed with the ozone gas is supplied to the gas-liquid separation device 18 to separate unnecessary undissolved ozone gas, and only dissolved ozone gas is dissolved.

The concentration of the ozone water from which the undissolved ozone gas has been separated by the gas-liquid separation device 18 is constantly measured by the densitometer 19, and the supply amount from the gas-liquid separation device 18 is measured by the flow meter 26. ing.

Further, when the processing is the second and subsequent processing in S1, the density has already been set, and therefore the processing in S2 and S3 is omitted.

In the next step S4, the density detection value C detected by the densitometer 19 is read and set and registered in the memory 30. Then, the process proceeds to S5, and it is checked whether or not | C−A | <a. That is, in S5, it is checked whether the difference between the current ozone water concentration measured by the densitometer 19 and the target value A set by the concentration setter 31 is within the allowable range ± a.

If │C-A│ <a in S5, it is determined that the current density detection value C is substantially equal to the target value A, and the process returns to S4.

However, if | CA | ≧ a in S5, the process proceeds to S6, and it is checked whether | CA |> + a. Then, in S6, when C−A> + a,
In step S7, the voltage regulator 32 is instructed to lower the set voltage B by one step. As a result, the voltage adjuster 32 adjusts the voltage value to decrease by one step and supplies the commanded one step lower voltage to the ozone gas generator 3.

When the voltage applied to the ozone gas generator 3 is adjusted, it takes a predetermined time (for example, 5 to 6 minutes) until the concentration of ozone water from which the undissolved ozone gas is separated by the gas-liquid separator 18 becomes stable. Therefore, in S9, it is checked whether a predetermined time has elapsed. Then, when a predetermined time has elapsed after adjusting the voltage applied to the ozone gas generator 3, the concentration of ozone water in the gas-liquid separation device 18 becomes stable.

At the next step S10, it is confirmed whether or not the density setting is changed. If there is a density setting change, S
Returning to step 2, the ozone water concentration A input by the concentration setter 31 is set. However, if the concentration setting is not changed in S10, the process proceeds to S11 to check whether the operation is stopped.

When the operation stop button (not shown) is not turned on in S11, the process returns to S4 and the ozone gas generator 3
After adjusting the applied voltage of, the density detection value C detected by the densitometer 19 is read. Then, the processes of S4 to S11 are repeated. However, when the operation stop button (not shown) is turned on in S11, the series of processes is ended and the ozone water generator 1 is stopped.

If C-A> + a is not satisfied in S6, the process proceeds to S8, and the voltage regulator 32 is instructed to increase the set voltage B by one step. As a result, the voltage regulator 3
2 is commanded by adjusting the voltage value by one step
A stepwise higher voltage is supplied to the ozone gas generator 3. After that, the processes of S9 to S11 are executed.

As described above, by monitoring the difference between the concentration detection value C detected by the densitometer 19 and the ozone water concentration A set by the concentration setter 31, the gas-liquid separation device 1
The voltage applied to the ozone gas generator 3 is automatically fine-tuned so that the ozone water discharged from 8 has a concentration A of the target value. Therefore, the ozone water generating apparatus 1 has the concentration setting device 31.
It becomes possible to stably supply the ozone water having the concentration set by.

Next, when the use of ozone water on the downstream side is stopped and the ozone water concentration decreases, or when the amount of ozone water used decreases and the ozone water concentration decreases, the control circuit 29 executes. The ozone water recirculation process will be described.

As an example thereof, the control circuit 29 executes the interrupt processing shown in FIGS.

The flow chart of FIG. 3 shows the processing when the use of ozone water on the downstream side is stopped and the flow rate becomes zero. The flow chart of FIG. 4 shows the amount of ozone water used on the downstream side. Is an interrupt process when the flow rate decreases and the flow rate becomes less than or equal to a predetermined value (lower limit value or less).

In FIG. 3, the control circuit 29 reads the flow rate measurement value measured by the flow meter 26 in S21, and determines in S22 whether or not the use of ozone water on the downstream side is stopped and the flow rate becomes zero. To check. When it is determined in S22 that the flow rate in the ozone water supply pipeline 23 is zero, the process proceeds to S23, and it is checked whether or not a preset time t has elapsed.

When the use of ozone water is started before the time t elapses, the process of FIG. 3 is ended. However, if ozone water is not used even after the lapse of time t, the process proceeds to S24, and the concentration detection value C of ozone water detected by the densitometer 19 is read. Then, densitometer 1
It is checked whether the difference between the current ozone water concentration detection value C measured by 9 and the target value A set by the concentration setter 31 is within the allowable range ± a (S).
25).

If | CA | <a in S25, it is judged that the current ozone water concentration detection value C is substantially equal to the target value A, and the processing of FIG. 3 is terminated.

However, if | CA | ≧ a in S25, the process proceeds to S26, and the pump 24 is started. Further, in S27, the return opening / closing valve 3 disposed in the return conduit 33
4 is opened, and the opening / closing valve 25 of the ozone water supply conduit 23 is closed.

As a result, the ozone water pressure-fed by the pump 24 from the second gas-liquid separation tank 22 of the gas separation device 18 has the open / close valve 25 of the ozone water supply conduit 23 closed, so The water passes through the passage 33 and the recirculation on-off valve 34, reaches the water supply pipe 16, and is supplied from the water supply pipe 16 to the ejector 13.

Therefore, in the ejector 13, the ozone water recirculated from the gas separation device 18 is mixed with the ozone gas from the ozone gas generator 3, and the thus-mixed high-concentration ozone water is supplied to the first part of the gas separation device 18. Gas-liquid separation tank 2
Discharge to 1. Therefore, the high-concentration ozone water is supplied to the first gas-liquid separation tank 21 of the gas separation device 18, and the high-concentration ozone water overflowing the first gas-liquid separation tank 21 is It flows into the second gas-liquid separation tank 22 and is fed again to the ozone water supply pipe line 23 connected to the bottom of the second gas-liquid separation tank 22.

The high-concentration ozone water thus recirculated flows upward from the bottom of the first gas-liquid separation tank 21 and further to the bottom of the second gas-liquid separation tank 22. Dissolved ozone gas is separated.

Further, the ozone water taken out through the ozone water supply conduit 23 is pumped by the pump 24, passes through the reflux conduit 33 and the reflux on-off valve 34, and reaches the ejector 13. The high-concentration ozone water mixed with the ozone gas by the ejector 13 is the first gas of the gas separation device 18.
Is discharged to the gas-liquid separation tank 21 of.

As described above, since the high-concentration ozone water circulates through the reflux conduit 33 and the reflux opening / closing valve 34,
The ozone concentration in the first gas-liquid separation tank 21 of the gas separation device 18 will rise in a short time.

At the next step S28, the concentration detection value C of the ozone water detected by the densitometer 19 is read. Next, the current ozone water concentration detection value C measured by the densitometer 19
Check whether the difference is within the allowable range ± a with respect to the target value A set by the density setting device 31 (S29).

If | CA | <a is not satisfied in S29, it is determined that the concentration of ozone water has not reached the target value A yet, and the processes of S26 to S29 are repeated. However, when | CA- <a in S29, it is determined that the current ozone water concentration detection value C is substantially equal to the target value A, the process proceeds to S30, the pump 24 is stopped, and the S31 is performed.
At this time, the recirculation on-off valve 34 is closed and the on-off valve 25 of the ozone water supply conduit 23 is opened.

As described above, when the use of the ozone water on the downstream side is stopped, the ozone water of the gas separation device 18 is circulated so as to be supplied to the ejector 13, so that the concentration of the ozone water is set to a predetermined value in a short time. Can maintain high concentration.
Therefore, the concentration of ozone water in the gas separation device 18 is
By the processing of S21 to S31 as described above, the graph shown in FIG. 5 is obtained.

That is, when the concentration of ozone water in the gas separator 18 decreases to Aa with respect to the target value A, the pump 24 is started and the on-off valve 34 is opened as in S26 and S27 described above. . Then, during the time T ₁ , the concentration of ozone water rises to the target value A, and the above S3
The pump 24 is stopped and the on-off valve 34 is closed as in S31.

When the circulation of the ozone water through the branch pipe 33 is stopped, the ozone gas contained in the ozone water in the gas separating device 18 is separated, so that the concentration of the ozone water gradually decreases. Therefore, when the time T ₂ elapses, the concentration of ozone water in the gas separation device 18 becomes Aa with respect to the target value A.
Therefore, the pump 24 is started and the opening / closing valve 34 is opened.

Therefore, the concentration of ozone water is always maintained within the range from the target value A to the allowable value Aa. Therefore, when the ozone water generator 1 is in a stopped state, usable high-concentration ozone water is stored in the gas separator 18, and the ozone water concentration is the target value A at the start of use of the ozone water.
There is no need to wait until, and the actual waiting time can be reduced to zero.

As described above, the pump 24 is not always operated, but is intermittently operated as shown in FIG.
It is possible to save the power consumption by operating the pump 24.

Further, when the use of ozone water on the downstream side is restarted and the flow rate measured value of the flow meter 26 becomes a predetermined value or more,
The process of FIG. 3 is ended, and the control circuit 29 shifts to a normal process (process of the flowchart shown in FIG. 2) to restart the operation of the ozone water producing apparatus 1.

Next, when the amount of ozone water used on the downstream side decreases and the flow rate measurement value of the flow meter 26 becomes less than or equal to a predetermined value, the control circuit 29 executes the interrupt processing shown in FIG.

In FIG. 4, in S21a, the flow rate measurement value measured by the flow meter 26 is read, and in S22a, the amount of ozone water used on the downstream side is reduced and the flow rate measurement value is equal to or lower than a preset predetermined flow rate ( Check if the flow rate has decreased to below the lower limit).

At S22a, the ozone water supply pipe 23
When it is determined that the flow rate in step S3 has decreased to the predetermined flow rate or less, the processing from S23a is executed. Incidentally, S23a-
Since the processing of S25a is the same as the processing of S23 to S25 of FIG. 3 described above, the description thereof will be omitted.

In this case, since the ozone water is used even though the flow rate is small, the operation of the pump 24 is continued,
The processes of starting the pump in S26 and stopping the pump in S30 described above are unnecessary.

Then, in S25a, | CA | <a
When, the current ozone water concentration detection value C is approximately the target value A
And the processing of FIG. 4 is terminated.

However, in S25a, | CA | ≧ a
In case of, the processing after S27a is executed. Incidentally, S27
The processing of a to S29a is the same as S27 to S29 of FIG.
Since it is the same as, the description thereof will be omitted.

By opening the recirculation on-off valve 34 in S27a, the second gas-liquid separation tank 22 of the gas separation device 18 is opened.
The ozone water sent by the pump 24 from the pump 24 is supplied to the downstream side through the ozone water supply pipeline 23, and a part of the ozone water passes through the reflux pipeline 33 and the reflux on-off valve 34 to supply water. It reaches the pipe line 16 and is supplied to the ejector 13 from the water supply pipe line 16.

Therefore, in the ejector 13, the ozone water recirculated from the gas separation device 18 is mixed with the ozone gas from the ozone gas generator 3, and the thus-mixed high-concentration ozone water is supplied to the first part of the gas separation device 18. Gas-liquid separation tank 2
Discharge to 1. Therefore, the high-concentration ozone water is supplied to the first gas-liquid separation tank 21 of the gas separation device 18, and the high-concentration ozone water overflowing the first gas-liquid separation tank 21 is It flows into the second gas-liquid separation tank 22 and is fed again to the ozone water supply pipe line 23 connected to the bottom of the second gas-liquid separation tank 22.

Thus, part of the high-concentration ozone water is
The ozone concentration in the first gas-liquid separation tank 21 of the gas separation device 18 rises in a short time because it circulates through the reflux conduit 33 and the reflux on-off valve 34.

As described above, when the amount of ozone water used on the downstream side is reduced to a predetermined value or less, a part of the ozone water discharged from the gas separation device 18 is supplied to the ejector 13 and circulated, whereby The concentration of ozone water can be maintained at a predetermined high concentration in a short time.

The reflux on-off valve 34 is used for the concentration meter 19
The valve may be opened or closed only based on the concentration detection value detected in (3).

[0091]

As described above, according to the first aspect of the present invention, when the concentration detecting means detects that the concentration of ozone water in the gas-liquid separation tank has dropped below a predetermined lower limit value, the pump is turned on. Since the on-off valve provided in the branch pipe is opened at the same time as starting, the concentration of ozone water in the gas-liquid separation tank can always be maintained at the desired high concentration, and the desired concentration of ozone water can be maintained at any time. I can take it out. Therefore, the standby time at the start of use of ozone water can be shortened, the pump does not have to be upsized, and the pump can be operated intermittently, so that the power consumption of the pump can be saved.

According to the second aspect of the present invention, it is detected by the flow meter that the ozone water flowing through the liquid feeding conduit has decreased to a predetermined flow rate or less, and the concentration detecting means detects the concentration of the ozone water in the gas-liquid separation tank. When it is detected that the temperature has dropped below a predetermined lower limit value, the pump is started and the on-off valve provided in the branch pipe is opened. It is possible to take out a desired high-concentration ozone water according to the amount, and it is possible to shorten the waiting time at the start of using ozone water.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a configuration of an embodiment of an ozone water generator according to the present invention.

FIG. 2 is a flowchart for explaining a process executed by a control circuit when ozone water is used.

FIG. 3 is a flowchart illustrating an interrupt process executed by a control circuit when the use of ozone water is stopped.

FIG. 4 is a flowchart for explaining an interrupt process executed by a control circuit when the usage amount of ozone water decreases below a predetermined level.

FIG. 5 is a graph showing changes in ozone water concentration.

[Explanation of symbols]

 1 Ozone Water Generation Device 2 Oxygen Gas Generation Unit 3 Ozone Gas Generator 4 Ozone Water Generation Unit 9 Oxygen Gas Tank 13 Ejector 18 Gas Separation Device 19 Concentration Meter 21 First Gas-Liquid Separation Tank 22 Second Gas-Liquid Separation Tank 26 Flow Rate Total 28 Ozone decomposer 29 Control circuit 30 Memory 31 Voltage regulator 33 Reflux line 34 Reflux opening / closing valve

Claims (2)

[Claims] 1. An ozone gas generating means for generating an ozone gas having a concentration according to a supplied voltage value, a gas-liquid mixing means for mixing the ozone gas generated by the ozone gas generating means with a liquid, and the gas-liquid mixing means. A gas-liquid separation tank that separates excess ozone gas contained in the generated ozone water, a concentration detection unit that detects the concentration of ozone water in the gas-liquid separation tank, and ozone extracted from the gas-liquid separation tank. A liquid sending conduit for sending water to the downstream side; a pump provided in the liquid sending conduit for sending the ozone water generated by the gas-liquid mixing means to the downstream side; A reflux pipe for branching a part of the ozone water discharged from the pump to the gas-liquid mixing means, an on-off valve arranged in the reflux pipe, and the gas-liquid separation by the concentration detecting means. The concentration of ozone water in the tank When it is detected that falls below the lower limit value of the constant, and a control means for opening the closing valve, the ozone water generation apparatus characterized by comprising more. 2. An ozone gas generating means for generating an ozone gas having a concentration corresponding to a supplied voltage value, a gas-liquid mixing means for mixing the ozone gas generated by the ozone gas generating means with a liquid, and the gas-liquid mixing means. A gas-liquid separation tank that separates excess ozone gas contained in the generated ozone water, a concentration detection unit that detects the concentration of ozone water in the gas-liquid separation tank, and ozone extracted from the gas-liquid separation tank. A liquid sending conduit for sending water to the downstream side; a pump provided in the liquid sending conduit for sending the ozone water generated by the gas-liquid mixing means to the downstream side; A flow meter disposed downstream of the pump for measuring the flow rate discharged from the pump, and the ozone water discharged from the pump branching from a liquid-feeding conduit between the flow meter and the pump. Gas-liquid mixture A reflux pipe for returning to the stage, an on-off valve arranged in the reflux pipe, and the flow meter detecting that the ozone water flowing through the liquid sending pipe has decreased to a predetermined flow rate or less, and the concentration When the detection means detects that the concentration of ozone water in the gas-liquid separation tank falls below a predetermined lower limit value, the control means opens the on-off valve, and ozone water generation is provided. apparatus.