JP2004188246A - System for manufacturing ozonized water - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To drastically reduce the running cost of an ozonized water manufacturing system by reusing the ozone gas generated by an ozone generating means without disposing of ozone gas uselessly when the ozonized water is manufactured. <P>SOLUTION: This system for manufacturing ozonized water is provided with ozone dissolving means 2, 2a and a gas-liquid separating means 7 and constituted so that a ozone gas-containing gas from the ozone generating means 1 is blown into the water from a water system 4 by the means 2 to dissolve the ozone gas in the water, the gaseous component containing the undissolved ozone gas is separated by the means 7 from the ozone-dissolved water obtained by the means 2 and the gaseous component separated in the means 7 is supplied to the means 2a and is blown into the water from the system 4 to dissolve the ozone gas contained in the gaseous component. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ozone water production system, and more particularly to an ozone water production system that can efficiently use ozone gas generated by an ozone generation unit.
[0002]
[Prior art]
Conventionally, ozone water has been used for sterilizing water in sewerage treatment facilities, water supply treatment facilities, hydroponic cultivation facilities, and the like. In addition, an oxide film adhered to or formed on the surface of a primary system pipe or a structural component in a nuclear power plant, for example, a hardly soluble chromium-based oxide can be dissolved and removed by the oxidizing action of ozone water. Such an oxidation treatment technique is described in Patent Document 1.
[0003]
Ozone water can be easily produced by blowing and dissolving ozone gas into water supplied from a water system. Ozone gas as a raw material can be easily generated by an ozone generating means, and such an ozone generating means includes a discharge method, a water electrolysis method, an ultraviolet irradiation method and the like.
[0004]
As the ozone dissolving means for dissolving the ozone gas, a mixing pump, an air diffuser, a hollow fiber ozone mixer as described in Patent Document 1, and a honeycomb type mixer or hollow fiber as described in Patent Document 2 are used. There is a diffusion film type mixer used.
[0005]
[Patent Document 1]
JP 2002-228796 A
[Patent Document 2]
JP-A-9-38660
[0006]
FIG. 7 is a process flow diagram showing a conventional ozone water production system. Raw material air is supplied from an air pipe a to an ozone generating means 1 comprising an ozone generator of a discharge system or the like, where oxygen in the air is converted into ozone gas, and a gas containing the ozone gas is supplied to an ozone dissolving means 2 through a pipe b. I do. In the ozone dissolving means 2, the gas is blown into water supplied from the raw water supply device 3 in the water system 4 to produce ozone water, and the ozone water is discharged from the downstream side of the ozone dissolving means 2.
[0007]
In the ozone dissolving means 2, a part of the ozone gas contained in the gas is dissolved in water, and the remaining gas components including the ozone gas are mixed with the generated ozone water in the form of fine bubbles, and the ozone gas is connected to the downstream side. It is supplied to utilization equipment 5, where sterilization treatment and oxidation treatment with ozone water are performed. The treated wastewater is supplied from a pipe c to a wastewater treatment facility (not shown), where the remaining ozone and a substance mixed in by the treatment are purified.
[0008]
Generally, the ozone utilization equipment 5 stirs the gas-liquid mixture during the treatment, so that the gas component of the gas-liquid mixture flows out from the pipe d as exhaust gas. Since the exhaust gas contains ozone harmful to the environment, the exhaust gas is treated by the exhaust gas treatment device 6 to be rendered harmless and then discharged to the outside from the pipe e.
[0009]
[Problems to be solved by the invention]
It is also described in Patent Literature 1 and the like that the amount of ozone gas that can be dissolved by the ozone dissolving means 2 varies depending on the pH value of system water, and the like. However, the amount of ozone that can be dissolved in water at 20 ° C. is only 350 mg / liter at maximum, and dissolution further decreases as the water temperature rises. For example, even when a large-sized ozone dissolving unit using a hollow fiber mixer system described in Patent Document 1 is used, for example, 20 Nm at 80 ° C. ³ In the case of this system, the concentration of dissolved ozone when circulating at a flow rate of 15 m / hour is only about 2.5 ppm.
[0010]
However, in order to obtain this concentration, the amount of ozone to be injected into water is actually required to be a gas containing a large amount of ozone of about 1 kg / hour. Actually, only 0.05 kg of ozone is used, and a large amount of the remaining 0.95 kg / hour of ozone gas is discharged to the exhaust gas treatment device 6 for treatment. In order to further increase the dissolution rate, it is necessary to increase the dissolving capacity per unit time by increasing the size of the ozone dissolving means. However, if the size is increased, there is a problem that the installation cost and the operating cost increase.
[0011]
As described above, in the conventional system, most of the ozone gas generated by the ozone generating means 1 is wasted, and this is one of the causes of an increase in operation cost. Also, since the utilization rate of ozone is extremely low, the capacity of the ozone dissolving means 2 needs to be increased more than necessary. Furthermore, when the supply system of the ozone water is long or after a certain time has passed since the generation of the ozone water, the ozone water supplied to the ozone utilization equipment 5 may have a reduced ozone concentration or may have a non-uniform temporal concentration caused by a self-collapse reaction of ozone. May occur.
[0012]
Further, even when high-concentration ozone water is required, it is necessary to increase the capacity of the ozone generating means 1 or to operate a plurality of ozone generating means 1 in parallel.
Then, this invention makes it a subject to solve these problems of the conventional ozone water production system, and aims at providing the new ozone water production system for that purpose.
[0013]
[Means for Solving the Problems]
The present invention for solving the above-mentioned problems includes an ozone generating means for generating ozone gas from oxygen in the air, and an ozone for dissolving ozone gas by blowing gas containing ozone gas flowing out of the ozone generating means into water supplied from a water system. This is an ozone water production system provided with a dissolving means. The present apparatus is provided with a plurality of ozone dissolving means and a gas-liquid separating means, and one of the ozone dissolving means blows a gas containing ozone gas flowing out of the ozone generating means into water supplied from a water system to discharge ozone gas. Dissolved, gas components containing undissolved ozone gas from the obtained ozone-containing water are separated by the gas-liquid separation means, and the separated gas components are supplied to other ozone dissolution means, where the water supplied from the water system is supplied. The ozone gas is dissolved by injecting the ozone gas into the gas (claim 1).
[0014]
In the above-mentioned ozone water production system, another ozone generation means may be provided, and ozone gas may be further generated from the gas component separated by the gas-liquid separation means and supplied to the other ozone dissolution means. 2).
[0015]
In any of the above ozone water production systems, the other ozone dissolving means can be provided in another water system (claim 3).
[0016]
Further, in any of the above ozone water production systems, at least one of the water system and the other water system can constitute a circulating water system (claim 4).
[0017]
Further, in any of the above-described ozone water production systems, the gas-liquid separation means includes a gas-liquid separation chamber, an inlet portion of a gas-liquid mixture provided at a lower portion of the gas-liquid separation chamber, and an outlet portion of degassed ozone water, A gas outlet provided at the upper part of the gas-liquid separation chamber, a regulating valve provided in communication with the gas outlet, and a liquid level control device, wherein the liquid level of the gas-liquid separation chamber is within a predetermined range. Thus, the regulating valve can be controlled by the liquid level control device (claim 5).
[0018]
Further, in any of the above ozone water production systems, the gas component from the gas-liquid separation unit may be configured to be pressurized by the pressurizing unit and supplied to another ozone dissolving unit (claim 6).
[0019]
Furthermore, in any of the above-mentioned ozone water production systems, the gas component from the gas-liquid separation means can be configured to be supplied to another ozone dissolving means by a Venturi action by a water flow in a water system or another water system (claim 7). .
[0020]
According to another aspect of the present invention, there is provided an ozone generating unit configured to generate ozone gas from oxygen in air, and an ozone gas generated by blowing gas containing ozone gas flowing out of the ozone generating unit into water supplied from a water system. This is an ozone water production system provided with an ozone dissolving means for dissolving ozone. The system further includes gas-liquid separation means for separating a gas component containing undissolved ozone gas from the ozone-containing water obtained by the ozone dissolution means. (Claim 8).
[0021]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a process flow diagram of the ozone water production system according to the present invention. An ozone dissolving unit 2, a gas-liquid separating unit 7, another ozone dissolving unit 2a, and an ozone utilization facility 5 are sequentially connected to a water system 4 that supplies water from the raw water supply device 3.
[0022]
A pipe a for introducing air and a pipe b for supplying a gas containing ozone gas to the ozone dissolving means 2 are connected to the ozone generating means 1. This ozone generating means 1 converts at least a part of the oxygen in the raw material air into ozone gas, and can use a general ozone generator of a discharge system or the like as in the conventional system of FIG.
[0023]
The gas supply section of the ozone dissolving means 2 is connected to the pipe b from the ozone generating means 1, and the water supply section is connected to the water system 4. This ozone dissolving means 2 generates ozone water by blowing gas containing ozone gas supplied from a pipe b into water introduced from a water system 4, and similarly to a conventional system, a mixing pump, an air diffuser, and other components. Devices utilizing various methods can be used.
[0024]
As the ozone dissolving means 2 and other ozone dissolving means 2a to be described later, devices utilizing various methods as described above can be used. However, the concentration and dew point of the supplied ozone, the properties of the system water (for example, the ozone concentration and the temperature) ), It is desirable to select the most suitable one according to the pressure difference between the gas containing ozone gas and the system water. In particular, the pressure difference between the gas containing the ozone gas and the system water greatly affects the choice of the method of the ozone dissolving means 2 (2a).
[0025]
FIG. 2 is a schematic explanatory view of the ozone dissolving means 2 using a water sprinkling pipe. The left side of the tubular main body 8 constitutes a water supply unit and is connected to the upstream side of the water system 4, and the right side constitutes a water discharge unit and is connected to the downstream side of the water system. Inside the main body 8, there is disposed a long and thin air diffuser 9 provided with a number of minute nozzle holes constituting a gas supply unit. The gas containing the ozone gas from the ozone generating means 1 is supplied from the pipe b to the air diffuser 9 and is blown into water as fine bubbles from a number of minute nozzle holes.
[0026]
Part of the ozone gas contained in the injected gas is dissolved in water, and the undissolved gas component is contained in the water in a bubble state to form a gas-liquid mixture with the ozone water and flows downstream from the water discharge part. leak. When the pressure of the gas containing ozone gas is higher than the water pressure of the water system, this type of ozone dissolving means 2 can be suitably applied to, for example, the ozone dissolving means 2a connected to a relatively low pressure position on the downstream side of the water system.
[0027]
FIG. 3 is a schematic explanatory view of the ozone dissolving means 2 utilizing the venturi action. The ozone dissolving means 2 has a main body 8 formed in a tubular shape, a constricted portion 10 provided inside the main body 8, and a nozzle tube 11 having an open end at the constricted portion 10 portion. And the right side constitutes the water discharge part. The pipe b from the ozone generator 1 is connected to the nozzle pipe 11 constituting the gas supply unit.
[0028]
In this ozone dissolving means 2, the flow rate of the water supplied from the water system 4 is increased at the throttle unit 10, and the ozone-containing gas supplied from the pipe b is sucked by the depressurized water flow generated at that time, A large number of fine bubbles are ejected from the tip. A part of the ozone gas contained in the injected gas is dissolved in water, and the undissolved gas component is contained in the water in a bubble state to form a gas-liquid mixture with the ozone water. Spills downstream. This type of ozone dissolving means 2 can be suitably applied to, for example, the ozone dissolving means 2 connected to a relatively high pressure position on the upstream side of a water system, but when the gas pressure is substantially equal to or lower than the water pressure. But it is applicable.
[0029]
In FIG. 1, a gas-liquid separation unit 7 introduces a gas-liquid mixture of ozone water and a gas component obtained by the ozone dissolving unit 2, and separates a gas component containing a high concentration of undissolved ozone gas there. . Then, the separated gas component is supplied from a pipe f to a gas supply unit of another ozone dissolving means 2a, and the remaining degassed ozone water flows downstream of the water system and is discharged from another ozone dissolving means 2a. It is supplied to the supply unit.
[0030]
The ozone water flowing out of the other ozone dissolving means 2a is supplied to the ozone utilization facility 5, and the ozone water containing low-concentration ozone flowing out of the ozone utilization facility 5 is discharged from the pipe c to a wastewater treatment device (not shown). And perform detoxification processing. The gas component containing ozone discharged from the ozone utilization facility 5 is discharged from the pipe d to the exhaust gas treatment device 6, where it is purified and discharged to the outside from the pipe e.
[0031]
The other ozone dissolving means 2a is provided for effectively utilizing the ozone gas which could not be dissolved by the ozone dissolving means 2 without wasting. By providing the other ozone dissolving means 2a in this manner, ozone can be further dissolved in ozone water flowing out of the ozone dissolving means 2 to the water system 4 to increase the ozone concentration. That is, when the ozone dissolving means 2 and another ozone dissolving means 2a are connected in series and configured to perform ozone dissolution in two stages, the ozone dissolving time is doubled, thereby increasing the size of the ozone dissolving means 2. The same effect as described above can be exhibited. Therefore, high-concentration ozone water can be easily produced at low cost.
[0032]
A part of the gas containing ozone at a high concentration separated by the gas-liquid separation means 7 may be supplied to the ozone generation means 1 as a part of the raw air through a dotted pipe fa. Further, all of the gas can be supplied to the ozone generating means 1 as a part of the raw air (see claim 8). In this case, since the ozone generating means 1 can be configured to be smaller and more efficient, the installation cost and operating cost of the entire system can be reduced.
[0033]
Further, a gas containing ozone separated by the gas-liquid separation unit 7 at a high concentration may be supplied to another ozone generation unit 1a indicated by a dotted line, and supplied to another ozone dissolution unit 2a in a state where the ozone concentration is further increased. it can. By providing such another ozone generating means 1a, the ozone concentration of ozone water obtained by the other ozone dissolving means 2a can be further increased. Note that the other ozone generating means 1a is auxiliary and its capacity may be relatively small, so that the installation cost and the operating cost are not so high.
[0034]
Further, since the gas separated by the gas-liquid separation means 7 usually has a high humidity, the other ozone generation means 1a for supplying the gas is selected from a method relatively insensitive to humidity such as an electrolysis type. It is desirable. When the discharge method is selected as the other ozone generating means 1a, it is desirable to provide a drying means such as an air dryer for reducing the dew point at the preceding stage.
[0035]
Further, another ozone utilization equipment 5a indicated by a dotted line may be provided between the gas-liquid separation means 7 and the other ozone dissolving means 2a. When such another ozone utilization equipment 5a is provided, ozone is consumed there, but the low-concentration ozone water flowing out is converted into high-concentration ozone water again by another ozone dissolving means 2a provided on the downstream side. Then, the ozone water can be supplied to the ozone utilization facility 5 indicated by a solid line provided on the downstream side.
[0036]
Further, a water system 4 indicated by a dotted line is added to a pipe c for discharging relatively low-concentration ozone water from a downstream ozone utilization facility 5 indicated by a solid line, and a pump 12 and other gas-liquid are added to the added water system 4. The separation means 7a, the third ozone dissolving means 2b, and the third ozone utilization equipment 5b can be connected in this order.
[0037]
By thus substantially extending the water system 4 and providing the above-described units and the like therein, it becomes possible to supply ozone water to more ozone utilization facilities. However, it is necessary that the ozone utilization equipment 5 on the downstream side be equipment that uses ozone of a lower concentration. The pump 12 recovers the pressure drop in the water system 4, but may be omitted in some cases.
[0038]
FIG. 4 is a cross-sectional view showing one example of the gas-liquid separation means 7. The gas-liquid separation means 7 according to the present embodiment includes a closed gas-liquid separation chamber 13, an inlet 14 for a gas-liquid mixture provided below the gas-liquid separation chamber 13, and an outlet 15 for a degassed liquid. A gas outlet 16 provided in the upper part of the gas-liquid separation chamber 13, an adjusting valve 17 provided in communication with the gas outlet 16, and a liquid level controller 18. The upstream water system 4 communicates with the inlet 14 via the on-off valve 19 and the inclined riser 20, and the outlet 15 communicates with the downstream water system 4 via the inclined downcomer 21 and the on-off valve 22. Communicate.
[0039]
Further, inside the gas-liquid separation chamber 13, a plurality of partition plates 13a extending upward from the bottom thereof are arranged in parallel. These partition plates 13a are made of a flat plate material or a plate material having a large number of through holes such as a net plate or a punching metal, and more effectively decelerate the gas-liquid mixture flowing into the gas-liquid separation chamber 13, thereby reducing the gas-liquid mixture. The residence time of the body can be lengthened to further enhance the gas-liquid separation efficiency. In some cases, these partition plates 13a may be omitted.
[0040]
The gas-liquid separation chamber 13 can be made of a transparent or translucent reinforced plastic so that the liquid level inside can be monitored. When the gas-liquid separation chamber 13 is made of a metal plate, a glass level gauge (not shown) is attached to the side wall. A pressure measuring device 23 and a gas relief valve 24 are provided above the gas-liquid separation chamber 13. The pressure measuring device 23 monitors the internal pressure of the gas-liquid separation chamber 13, but is omitted in some cases. The gas relief valve 24 is provided for discharging the internal air when the operation of the gas-liquid separation means 7 is started.
[0041]
The liquid level control device 18 provided above the gas-liquid separation chamber 13 has a float 18a, a lever 18b, and a drive rod 18c connected to an intermediate portion of the lever 18b, and a tip of the drive rod 18c is connected to the adjustment valve 17. The liquid level controller 18 and the regulating valve 17 constitute a float type automatic liquid level controller 25. A pipe f is connected to the outlet side of the regulating valve 17, and its tip communicates with the gas supply section of another ozone dissolving means 2a as shown in FIG.
[0042]
The liquid level control is performed by another method usually used in this field, for example, a liquid level measuring device for detecting the liquid level in the gas-liquid separation chamber 13, and a liquid level measuring signal transmitted from the liquid level measuring device is preset. Liquid level control means constituted by a controller that outputs a control signal so that the flow rate becomes a constant value, and a flow rate adjusting valve that adjusts the flow rate by a control signal from the controller.
[0043]
An on-off valve 26 is provided in the pipe f. Further, the pipe f may be provided with at least one of a sealed buffer tank 27 and a pressurizing means 28 such as a pump, as indicated by dotted lines, as necessary. The buffer tank 27 is provided to alleviate the fluctuation of the gas pressure in the pipe f due to the opening / closing operation of the adjustment valve 17. The pressure means 28 is provided to increase the gas pressure when the pressure of the gas is lower than the water pressure supplied to the other ozone dissolving means 2a.
[0044]
Next, the operation of the gas-liquid separation means 7 will be described. First, when the on-off valves 22 and 26 are closed and the on-off valve 19 is opened with the gas release valve 24 opened, the gas-liquid mixture from the upstream water system 4 passes through the riser 20 into the gas-liquid separation chamber 13. Inflow. The gas-liquid mixture that has flowed up pushes up the air inside, and raises the liquid level while discharging the air from the gas release valve 24 to the outside. Next, after confirming that the liquid level in the gas-liquid separation chamber 13 has reached a predetermined level, the on-off valve 24 is closed and the on-off valves 22 and 26 are opened to enter a normal operation state.
[0045]
Since the cross-sectional area in the flow direction of the gas-liquid separation chamber 13 is much larger than the diameter of the water system 4, the gas-liquid mixture flowing from the upstream water system 4 is decelerated there, and a large number of contained bubbles are generated. It separates from water and rises in the gas-liquid separation chamber 13 to form a compression space for a gas component containing ozone at a high concentration in the upper part. The pressure in the compression space is substantially equal to the water pressure in the water system 4, but the separated gas flows out to the pipe f through the regulating valve 17 due to the pressure. On the other hand, the degassed ozone water flows to the downstream water system 4 through the on-off valve 22.
[0046]
When the separation amount of the gas component in the gas-liquid separation chamber 13 increases from a normal value, the pressure in the compression space rises and the liquid level in the gas-liquid separation chamber 13 gradually decreases. The surface control device 18 maintains the state where the adjustment valve 17 is opened. Conversely, when the separation amount of the gas component decreases below the normal value, the pressure in the compression space decreases, and the liquid level in the gas-liquid separation chamber 13 gradually increases. Then, the liquid level controller 18 controls the regulating valve 17 in the closing direction so that the liquid level returns to the normal level.
[0047]
Next, the pressure relationship of each part in the water system 4 of FIG. 1 will be described. The system water of the water system 4 has a lower water pressure as going from the upstream side to the downstream side. For the sake of explanation, as shown in FIG. ₀ , The water pressure upstream of the gas-liquid separation means 7 ₁ , The water pressure on the upstream side of the other ozone utilization equipment 5 indicated by the dotted line is P ₂ , The water pressure upstream of the other ozone dissolving means 2a is P ₃ , The water pressure at the upstream side of the ozone utilization facility 5 provided at the most downstream side is P ₄ And The pressure of the gas component at the portion flowing out of the gas-liquid separation means 7 to the pipe f is Pa, and the pressure of the gas component at the portion of the pipe f flowing into the other ozone dissolving means 2a is Pb.
[0048]
These water pressures or pressures decrease due to the pressure loss due to the fluid resistance of the water system 4 or the pipe f or the pressure loss due to the orifice effect of each means. ₀ > P ₁ = Pa = P ₂ > P ₃ = P ₄ It becomes. Note that P ₁ , Pa and P ₂ Or P ₃ And P ₄ In some cases, a slight pressure difference may occur. In this embodiment, Pa> P ₃ Therefore, the other ozone dissolving means 2a can easily blow the gas component from the gas-liquid separating means 7 into the system water by the pressure difference.
[0049]
FIG. 5 is another process flow chart of the ozone water production system according to the present invention. This embodiment is different from the example of FIG. 1 in that the water system 4 forms a circulation type, that is, a circulation water system, and a circulation pump 29 for circulating system water is provided in the circulation water system. Are configured substantially the same. Therefore, the same portions are denoted by the same reference numerals, and overlapping description will be omitted.
[0050]
By operating the circulation pump 29, the system water of the water system 4 flows into the ozone dissolving means 2, where the gas containing the ozone gas from the ozone generating means 1 is blown, and the ozone water and the gas are supplied to the downstream side of the water system 4. The gas-liquid mixture of the components flows out. The gas-liquid mixture then flows into the gas-liquid separation means 7, where gas components containing high concentrations of ozone gas are separated from the ozone water. The ozone water flows into the ozone utilization equipment 5 provided downstream therefrom, and the separated gas component flows from the pipe f into another ozone dissolving means 2a provided further downstream of the ozone utilization equipment 5.
[0051]
The relatively low-concentration ozone water discharged from the ozone utilization facility 5 flows into the other ozone dissolving means 2a, and a gas component containing a high concentration of ozone from the pipe f is blown into the ozone water, A gas-liquid mixture of ozone water and gaseous components containing high concentration of ozone is formed. The pipe f may be provided with another ozone generating means 1a as shown by a dotted line. When such another ozone generating means 1a is provided, as described in the example of FIG. 1, the ozone can be supplied to the other ozone dissolving means 2a in a state where the ozone concentration is further increased.
[0052]
The gas-liquid mixture flowing out of the other ozone dissolving means 2a flows into another ozone utilization facility 5a provided on the downstream side, and the ozone of a relatively low concentration flowing out from the other ozone utilization facility 5a to the downstream side. The water is circulated again to the ozone dissolving means 2 via the circulation pump 29. The water system 4 from the raw water supply device 3 joins the water system 4 on the inlet side of the circulation pump 29 so that the system water can be supplied at the initial stage of the system operation or the insufficient system water can be supplied at the time of the system operation. It has become.
[0053]
Exhaust gas containing ozone discharged from another ozone utilization facility 5a to the pipe d is purified by the exhaust gas treatment device 6 and detoxified, and discharged from the pipe e to the outside. When such a circulating water system is adopted, air may accumulate in the middle of the piping depending on the laying state of the piping constituting the water system 4. In that case, it is desirable to provide an air vent pipe having an air vent valve at a portion where an air pool occurs, and connect it to an exhaust gas treatment device (not shown).
[0054]
When a circulating water system is employed as in the present embodiment, the used ozone-containing wastewater from the ozone utilization facilities 5 and 5a is circulated and reused without being discharged to a wastewater treatment device provided outside the system. Therefore, the amount of wastewater treatment is significantly reduced, and the system efficiency is improved.
[0055]
FIG. 6 is still another process flow chart of the ozone water production system according to the present invention. This embodiment differs from the example of FIG. 4 in that another water system 4a is provided in addition to the original water system 4 and contains ozone separated by the gas-liquid separation means 2 provided in the water system 4 at a high concentration. This is a point where the gas component is supplied (blowed) to another ozone dissolving means 2a provided in another water system 4a, and the other components are substantially the same. Therefore, the same portions are denoted by the same reference numerals, and overlapping description will be omitted. However, in the present embodiment, the water system 4 is not provided with other ozone dissolving means 2a and other ozone utilization equipment 5a as shown in FIG.
[0056]
In the water system 4 shown in the upper part of FIG. 6, a circulation pump 29, an ozone dissolving unit 2, a gas-liquid separating unit 7, and an ozone utilization facility 5 are provided in order from the upstream side to the downstream side. A gas containing ozone from the means 1 is blown. Further, the water system 4 from the raw water supply device 3 joins the inlet side of the circulation pump 29.
[0057]
In another water system 4a shown in the lower part of FIG. 6, another circulation pump 29a, another ozone dissolving means 2a, and another ozone utilization facility 5a are provided in order from the upstream side to the downstream side, and the other ozone dissolving means is provided. A gas component containing a high concentration of ozone separated by the gas-liquid separation means 7 is blown into 2a. Further, another water system 4a from another raw water supply device 3a joins the inlet side of another circulation pump 29a.
[0058]
By operating the circulation pump 29, the system water of the water system 4 flows into the ozone dissolving means 2, where the gas containing ozone from the ozone generating means 1 is blown, and the ozone water and the gas are supplied to the downstream side of the water system 4. The gas-liquid mixture of the components flows out. The gas-liquid mixture then flows into the gas-liquid separation means 7, where the gaseous component containing a high concentration of ozone is separated from the ozone water. The ozone water flows into the ozone utilization facility 5 provided downstream therefrom, and the separated gas component flows from the pipe f into another ozone dissolving means 2a provided in another water system 4a.
[0059]
On the other hand, by operating the other circulation pump 29a, the system water of the other water system 4a flows into the other ozone dissolving means 2a, where the gas component including the ozone gas from the gas-liquid separation means 7 is blown, The gas-liquid mixture of the ozone water and the gas component flows out downstream thereof. The gas-liquid mixture then flows into another ozone utilization facility 5a, and the used relatively low-concentration ozone water is discharged downstream. Then, the discharged ozone water is circulated again to another ozone dissolving means 2a via another circulation pump 29a.
[0060]
In the present embodiment shown by a solid line, the concentration of ozone water required for the ozone utilization facility 5 provided in the upper water system 4 is lower than the concentration of ozone water required for the other ozone utilization facility 5a provided in the other lower water system 4a. It can be suitably applied when the concentration of ozone water to be used is low.
[0061]
On the other hand, another ozone generating means 1a can be provided in the pipe f as shown by a dotted line. When such another ozone generating means 1a is provided, as described in the example of FIG. 1, a gas component having a higher ozone concentration can be supplied to another ozone dissolving means 2a. This embodiment can be applied even when the concentration of ozone water required for another ozone utilization facility 5a provided in the water system 4a is relatively high.
[0062]
In the present embodiment, one ozone utilization facility 5 or another ozone utilization facility 5a is provided for each of the water system 4 and the other water system 4a, but a plurality of ozone utilization facilities 5 and 5a may be provided for each. . In that case, the ozone dissolving means 2 (or another ozone dissolving means 2a) is additionally provided as appropriate according to the example of FIG.
[0063]
Further, in the present embodiment, both the water system 4 and the other water system 4a are configured as circulating water systems, but at least one of the water system 4 and the other water system 4a is of a non-circulating type, that is, the water system 4 or other water system. Of the ozone utilization facilities 5, 5a provided at the most downstream side of the water system 4a. In that case, the circulation pump 29 or another circulation pump 29a is omitted, and the wastewater from the ozone utilization facility 5 or the other ozone utilization facility 5a is discharged from a pipe c shown by a dotted line to a wastewater treatment facility (not shown).
[0064]
In each of the embodiments described so far, the portions where the means and piping come into contact with the high-concentration ozone gas and its mist may be corroded or deteriorated due to a strong oxidizing action. Therefore, it is desirable that these portions are made of a material having excellent ozone resistance or oxidation resistance, for example, stainless steel, or that a fluororesin coating layer is formed on the portions.
[0065]
【The invention's effect】
As described above, the ozone water production system of the present invention is provided with a plurality of ozone dissolving means and gas-liquid separating means, and one of the ozone dissolving means is supplied with a gas containing ozone gas flowing out of the ozone generating means from a water system. The dissolved ozone is blown into water to dissolve ozone, the gas component containing undissolved ozone gas is separated from the obtained ozone-containing water by gas-liquid separation means, and the separated gas component is supplied to other ozone dissolution means, where the water The ozone gas is dissolved by blowing into water supplied from the system.
[0066]
According to the ozone water production system of the present invention configured as described above, the ozone gas generated by the ozone generation means is reused without being discarded, so that the operation cost can be significantly reduced as compared with the conventional system. Further, since the utilization rate of ozone is extremely high, the capacity of the ozone generating means can be reduced, and the occupied area and installation cost of the entire system can be suppressed.
[0067]
Further, when the supply system of the ozone water is long or after a certain period of time has passed since the generation of the ozone water, it is possible to avoid a decrease in the ozone concentration of the ozone water to be supplied to the ozone utilization facility and a non-uniform concentration over time. Further, even when the ozone utilization equipment requires high-concentration ozone water, the demand can be easily met.
[0068]
In the above-mentioned ozone water production system, another ozone generating means may be provided, where ozone is further generated from the gas component separated by the gas-liquid separating means and supplied to the other ozone dissolving means. In this way, the gas containing high-concentration ozone gas can be supplied to the other ozone dissolving means by the other ozone dissolving means, so that it is possible to easily cope with a case where the ozone utilization equipment requires a high concentration of ozone water.
[0069]
In any of the above ozone water production systems, the other ozone dissolving means can be provided in another water system. By supplying the gas thus separated by the gas-liquid separation means to the ozone dissolving means provided in another water system, gas components containing excess ozone gas in one water system can be reused in another water system. Can be.
[0070]
Further, in any of the above-described ozone water production systems, at least one of the water system and the other water system can be configured as a circulating water system. By configuring such a circulating water system, wastewater from the ozone utilization facility can be reused without performing wastewater treatment. Therefore, the treatment capacity of the wastewater treatment device can be significantly reduced, and in some cases, wastewater treatment equipment can be omitted.
[0071]
Further, in any of the above-described ozone water production systems, the gas-liquid separation means includes a gas-liquid separation chamber, an inlet portion of a gas-liquid mixture provided at a lower portion of the gas-liquid separation chamber, and an outlet portion of degassed ozone water, A gas outlet provided at the upper part of the gas-liquid separation chamber, a regulating valve provided in communication with the gas outlet, and a liquid level control device, wherein the liquid level of the gas-liquid separation chamber is within a predetermined range. Thus, the control valve can be controlled by the liquid level control device.
[0072]
According to the gas-liquid separation means configured as described above, a gas component containing a high concentration of ozone gas can be easily separated from a gas-liquid mixture of ozone gas and ozone water. Further, since the liquid level of the gas-liquid separation chamber is always maintained within a predetermined level range, there is no possibility that ozone water is mixed into a pipe for conveying the separated gas components.
[0073]
Further, in any of the ozone water production systems described above, the gas component from the gas-liquid separation unit may be configured to be pressurized by the pressurizing unit and supplied to another ozone dissolving unit. By providing such a pressurizing means, the gas component can be reliably blown into the other ozone dissolving means without being influenced by the water pressure of the system water supplied to the other ozone dissolving means.
[0074]
Further, in any of the above-described ozone water production systems, the gas component from the gas-liquid separation means may be configured to be supplied to another ozone dissolving means by a Venturi action by a water flow in a water system or another water system. Since the ozone dissolving means utilizing such a venturi action can dissolve ozone gas substantially without power, the energy consumption of the system can be reduced.
[0075]
Further, another ozone water production system according to the present invention is provided with gas-liquid separation means for separating a gas component containing undissolved ozone gas from the ozone-containing water obtained by the ozone dissolution means, and converts the separated gas component into the ozone water. It is characterized in that it is configured to supply to the generating means as a part of the raw air. According to the ozone water production system according to the present invention configured as described above, in addition to the above-described effects, a smaller and more efficient ozone generator can be configured, so that the installation cost of the entire system can be further reduced.
[Brief description of the drawings]
FIG. 1 is a process flow diagram of an ozone water production system according to the present invention.
FIG. 2 is a schematic explanatory view of an ozone dissolving means 2 using a water pipe.
FIG. 3 is a schematic explanatory view of an ozone dissolving means 2 using a venturi action.
FIG. 4 is a sectional view showing an example of the gas-liquid separation means 7 shown in FIG.
FIG. 5 is another process flow chart of the ozone water production system according to the present invention.
FIG. 6 is still another process flow chart of the ozone water production system according to the present invention.
FIG. 7 is a process flow diagram of a conventional ozone water production system.
[Explanation of symbols]
1 Ozone generation means
1a Other ozone generating means
2 Ozone dissolving means
2a Other ozone dissolving means
2b Third Ozone Dissolving Means
3 Raw water supply device
3a Other raw water supply equipment
4 Water system
4a Other water systems
5 Ozone utilization equipment
5a Other equipment using ozone
5b Third ozone utilization facility
6 Exhaust gas treatment device
7 Gas-liquid separation means
7a Other gas-liquid separation means
8 Body
9 diffuser
10 Aperture part
11 Nozzle tube
12 pumps
13 Gas-liquid separation chamber
13a Partition plate
14 Entrance
15, 16 exit
17 Regulating valve
18 Liquid level control device
18a float
18b lever
18c drive rod
19 On-off valve
20 riser
21 Downcomer
22 On-off valve
23 Pressure measuring device
24 Gas relief valve
25 Float type automatic liquid level control means
26 On-off valve
27 Buffer tank
28 Pressurizing means
29 Circulation pump
29a Other circulation pump
a-fa piping
P ₀ ~ P ₄ Water pressure
Pa, Pb pressure

Claims (8)

Ozone generating means 1 for generating ozone gas from oxygen in the air, and ozone dissolving means 2 for dissolving ozone by blowing gas containing ozone gas flowing out of the ozone generating means 1 into water supplied from a water system 4. In the ozone water production system,
A plurality of ozone dissolving means 2 and 2a and a gas-liquid separating means 7 are provided, and one of the ozone dissolving means (2) supplies gas containing ozone gas flowing out of the ozone generating means 1 to water supplied from a water system 4. To dissolve the ozone gas, the gas component containing the undissolved ozone gas is separated from the obtained ozone-containing water by the gas-liquid separation means 7, and the separated gas component is supplied to another ozone dissolution means 2a. An ozone water production system characterized in that ozone gas is dissolved by blowing into water supplied from a water system 4. In Claim 1, another ozone generating means 1a is provided, wherein ozone is further generated from the gas component separated by the gas-liquid separating means 7 and supplied to the other ozone dissolving means 2a. Characterized ozone water production system. 3. The ozone water production system according to claim 1, wherein the other ozone dissolving means 2a is provided in another water system 4a. The ozone water production system according to any one of claims 1 to 3, wherein at least one of the water system 4 and another water system 4a constitutes a circulating water system. 5. The gas-liquid separation means 7 according to claim 1, wherein the gas-liquid separation means 7 includes a gas-liquid separation chamber 13, an inlet 14 for a gas-liquid mixture provided below the gas-liquid separation chamber 13, and an outlet of degassed ozone water. A gas outlet section 16 provided at an upper portion of the gas-liquid separation chamber 13, a regulating valve 17 provided in communication with the gas outlet section 16, and a liquid level control device 18. An ozone water production system characterized in that the regulating valve 17 is controlled by a liquid level control device 18 so that the liquid level of 13 is within a predetermined range. 6. An ozone water production system according to claim 1, wherein the gas component from the gas-liquid separation unit 7 is pressurized by the pressurization unit 28 and supplied to another ozone dissolving unit 2a. . In any one of claims 1 to 5, the gas component from the gas-liquid separation means 7 is supplied to another ozone dissolving means 2a by a Venturi action by a water flow of the water system 4 or another water system 4a. Characterized ozone water production system. Ozone generating means 1 for generating ozone gas from oxygen in the air, and ozone dissolving means 2 for dissolving ozone by blowing gas containing ozone gas flowing out of the ozone generating means 1 into water supplied from a water system 4. In the ozone water production system, a gas-liquid separation unit 7 for separating a gas component containing undissolved ozone gas from the ozone-containing water obtained by the ozone dissolving unit 2 is provided. An ozone water production system characterized in that it is configured to be supplied as a part of air.

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