JP2000354747A - Ozone gas dissolving device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact ozone gas dissolving device for ozonic water used for the removal of harmful material contained in water or industrial waste water, decoloration and deodorization and for the sterilization, decoloration and deodorization of food or the like without needing any special electric power for feeding air. SOLUTION: An ozone generating chamber 9 is formed between a casing and an electrode supporting cylinder by disposing an electrode belt 6 consisting of a belt like or wire like electrode whose outer peripheral surface is covered to be insulated with a dielectric on the outer peripheral part of the electrode supporting cylinder 4 provided in a hermetic casing. One end of a suction pipe opened to the ozone generating chamber is connected to an ejector 14 provided in a water passing pipe 11 inserted into the inside of the electrode supporting cylinder, many through holes are formed on the electrode supporting cylinder formed by integrating the generating device and the dissolving device of the ozone gas, an air chamber 12 is formed between the electrode supporting cylinder and the water passing pipe, the air chamber is communicated with the outside air of the casing and the air in the air chamber is controlled to be sent to the ozone generating chamber from the through holes of the electrode supporting cylinder. Further plural heat sinks 10 are attached to the inner peripheral surface of the electrode supporting cylinder and the tip is provided extendingly to the air chamber.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for dissolving ozone gas, and more particularly, to ozone water used for removing, decolorizing, and deodorizing harmful substances contained in clean water, sewage, and industrial wastewater.
Alternatively, the present invention relates to an apparatus for producing ozone water used for sterilization, decolorization, and deodorization of foods and the like.

[0002]

2. Description of the Related Art Conventionally, an ozone gas producing apparatus and an ozone gas dissolving apparatus are known. Japanese Patent Application Laid-Open No. 8-59215
As described in the publication, the ozone gas producing device and the ozone gas dissolving device are independent devices, and a system is formed by combining auxiliary devices such as a compressor and a blower according to a request of the generator. Was.

[0003]

However, a system incorporating the above-mentioned conventional ozone gas generating device and dissolving device tends to have a large system volume and require a considerable installation space. It was difficult to incorporate the system into other machines. Further, in addition to the power for the generator, the power of the auxiliary equipment is required, so that it is not very economical. An object of the present invention is to provide a compact ozone gas dissolving apparatus that integrates an ozone gas generator and an ozone gas dissolving apparatus and does not require special power for air supply.

[0004]

The gist of the present invention resides in that an electrode support cylinder is provided in a closed casing, and an electrode band is provided on an outer peripheral portion of the electrode support cylinder, so that the casing and the electrode support are provided. An ozone generation chamber is formed between the cylinders, a water pipe is inserted into the electrode support cylinder, and one end of a suction pipe opened to the ozone generation chamber is connected to an ejector provided on the water pipe, and an ozone gas generator and This is an integrated melting device. Specifically, the electrode band is formed of a band-shaped or linear electrode whose outer peripheral surface is coated with a dielectric material. Also, a large number of through-holes are provided in the electrode support cylinder, an air chamber is formed between the electrode support cylinder and the water pipe, and this air chamber is communicated with the outside of the casing. Air is supplied to the generation chamber, and is a compact ozone gas dissolving apparatus that does not require special power for air supply. And, disposing a plurality of heat sinks on the inner peripheral surface of the electrode support cylinder,
The heat radiation of the electrode strip is prevented by the heat radiating plate, thereby preventing a decrease in the amount of generated ozone. If a check valve is attached to the suction pipe connected to the ejector, it is possible to prevent the backflow of the water to be treated into the ozone generation chamber when the flow of water is stopped.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION In an ozone gas dissolving apparatus according to the present invention, when an AC or DC high voltage is supplied to an electrode band provided on an outer peripheral portion of a support cylinder, a discharge occurs along the electrodes to generate ozone. On the other hand, when water is supplied to the water pipe from the water supply pump, the ozone generated in the ozone generating chamber is sucked from the suction port of the ejector and mixed with the water to be treated in the venturi section to generate ozone water in the water pipe. It flows out of one of the water pipes. The ozone generating chamber is sucked to have a negative pressure, and the air in the air chamber flows into the ozone generating chamber from the through hole of the electrode support cylinder. The air naturally flows into the air chamber from which the air has flowed out from the filter chamber which has been released to the atmosphere.

[0006]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to an embodiment. First, in FIGS. 1 and 2, reference numeral 1 denotes a cylindrical casing, and a sealed container is formed by a front plate 2 and a rear plate 3 at the front and rear. It is formed. An electrode support tube 4 is disposed inside the casing 1 in the longitudinal direction. On the outer peripheral surface of the electrode support tube 4, as shown in FIG. The electrode band 6 is formed by being wound endlessly in the circumferential direction, and the electrode band 6 is connected to a control device 8 attached to the casing 1 by a power cable 7. Then, 6 KV is applied to the electrode band 6 from the control device 8.
When the above voltage is supplied, ozone is generated in the ozone generation chamber 9 between the casing 1 and the electrode support cylinder 4. A plurality of heat sinks 1 are provided on the inner peripheral surface of the electrode support tube 4.
Are fixed to each other, and the ends thereof extend in the axial direction of the electrode support tube 4. The heat rise of the electrode band 6 due to the application of voltage is radiated by the heat radiating plate 10 to increase the temperature of the electrode band 6. Thus, a decrease in the amount of ozone generated due to the above is prevented.

A water pipe 11 is inserted through the center of the electrode support tube 4, and the water pipe 11 is supported by the front plate 2 and the rear plate 3 of the casing 1. Also,
The electrode support tube 4 has a front end supported by the front plate 2 of the casing 1 and a rear end side wall 4 a supported by the ejector 14. An air chamber 12 is provided inside the electrode support tube 4, and the ozone generation chamber 9 and the air chamber 12 are provided with a large number of through holes 13 provided on the peripheral surface of the electrode support tube 4, as shown in FIG.
It is communicated with. The water pipe 11 is provided with an ejector 14 having a reduced diameter at the supply start end of the water to be treated, and the other end of the suction pipe 15 opened to the ozone generation chamber 9 is reduced so that the ventilator portion of the ejector 14 is formed. Connected. A check valve 16 is attached to the opening end of the suction pipe 15 to the ozone generation chamber 9. From the water supply pump 17 to the water pipe 11
When the to-be-processed water supplied to the suction passage 15 passes through the venturi section of the ejector 14, a negative pressure is generated in the suction pipe 15, and the check pressure of the check valve 16 moves toward the venturi section due to the negative pressure. Then, ozone in the ozone generating chamber 9 is sucked, and the water to be treated and the ozone gas are mixed to generate ozone water. The air in the air chamber 12 is supplied to the through-hole 13 of the electrode support cylinder 4 in the ozone generation chamber 9 which has become a negative pressure.
It is made to flow naturally from. Next, when the water suction pump 17 is stopped and no negative pressure is generated in the suction pipe 15,
The check ball of the check valve 16 is moved toward the ozone generation chamber 9 by the support spring and closes the suction port. As a result, the ozone generation chamber 9 is removed from the water pipe 11 when the water flow is stopped.
Backflow of the water to be treated can be prevented. The suction pipe 15 connected to the ejector 14 has an ozone water concentration,
A plurality may be provided depending on the flow rate of the water to be treated.

The front plate 2 is provided with a plurality of vents 18 communicating with the air chamber 12 around the water pipe 11. In the air chamber 12 near the ventilation port 18 provided in the front plate 2, there is provided a rectifying plate 19 for allowing inflow air to flow into the center of the air chamber 12.
The air flowing along is cooled by the water to be treated via the water pipe 11. After contacting with the heat radiating plate 10 on the inner peripheral surface of the electrode support tube 4 extending to the vicinity of the water pipe 11 to exchange heat and indirectly cool the electrode strip 6, the electrode band 6 passes through the through hole 13 of the electrode support tube 4. And flows into the ozone generation chamber 9. Also,
Support plate 20 and front plate 2 at the front end of casing 1
A filter 21 is housed between the filters 21 to remove dust from the air flowing from the support plate 20 side of the filter 21 released to the atmosphere. Although the casing 1 and the electrode support tube 4 are cylindrical in the embodiment, they can be used as long as they are cylindrical, and the cross-sectional shape is not limited to a circle. Reference numeral 22 denotes a connection port on the water supply pump 17 side of the ozone gas dissolving apparatus, and reference numeral 23 denotes an ozone water outlet.

[0009]

The ozone gas dissolving apparatus according to the present invention has the following features.
Since the ozone gas dissolving device is provided inside the ozone gas generating device, the ozone gas generating device and the dissolving device are integrated into a compact ozone gas dissolving device. In other words, in the conventional ozone gas generator, the capacity of the system is large and it is difficult to incorporate it into other machines, and the power of the auxiliary equipment is also required. Since the outside of the electrode support cylinder provided with the electrode band is an ozone generation chamber and the inside of the electrode support cylinder having a through hole is an air chamber for supplying air, the supply of air to the electrode band is uniform. The ozone generator becomes compact, and the ozone in the ozone generation chamber is sucked by the ejector action of the venturi tube provided in the water pipe, so that the natural suction of air becomes possible and the power for air supply is unnecessary. Things. Further, since a heat radiator is provided in the air chamber inside the electrode support cylinder, the heat rise of the electrode band is cooled by the heat radiator to prevent a decrease in ozone generation. Therefore, the apparatus for producing ozone water becomes compact, the capacity of the equipment provided with the reaction tower and the waste ozone treatment tower is reduced, and it is easy to incorporate the ozone water into other mechanical devices.

[Brief description of the drawings]

FIG. 1 is a vertical side view of an ozone gas dissolving apparatus according to the present invention.

FIG. 2 is a cross-sectional side view of the ozone gas dissolving apparatus taken along the line AA in FIG.

FIG. 3 is a partial longitudinal sectional side view showing a main part electrode band according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Casing 4 Electrode support cylinder 5 Electrode 6 Electrode band 9 Ozone generation chamber 10 Heat sink 11 Water passage pipe 12 Air chamber 13 Through hole 14 Ejector 15 Suction pipe 16 Check valve 17 Water supply pump 21 Filter

Continued on the front page F term (reference) 4D050 AA03 AA13 AA15 AB03 AB04 AB07 BB02 BD03 BD04 BD08 4F033 AA09 QB02X QB03Y QB12X QD04 QD14 4G035 AA01 AE13 4G042 CA01 CC03 CC10 CC16 CE01

Claims (6)

[Claims] An electrode support tube (4) is provided in a sealed casing (1), and an electrode band (6) is provided on an outer peripheral portion of the electrode support tube (4). An ozone generation chamber (9) is formed between the support cylinders (4), and a water pipe (11) is inserted into the electrode support cylinder (4), so that an ejector (14) provided in the water pipe (11) is provided. An ozone gas dissolving apparatus, wherein one end of a suction pipe (15) opened to an ozone generation chamber (9) is connected. 2. The ozone gas dissolving apparatus according to claim 1, wherein said electrode strip comprises a strip-shaped or linear electrode whose outer peripheral surface is insulated with a dielectric. 3. A large number of through holes (1) in said electrode support cylinder (4).
3), an air chamber (12) is formed between the electrode support cylinder (4) and the water pipe (11), and the air chamber (12) is communicated with the outside of the casing (1). The ozone gas dissolving apparatus according to claim 1 or 2, wherein: 4. A plurality of heat radiating plates (10...) Are fixed to the inner peripheral surface of the electrode support cylinder (4), and the ends thereof are connected to an air chamber (12).
The ozone gas dissolving apparatus according to claim 1, wherein the apparatus is extended. 5. The ozone gas dissolving apparatus according to claim 1, wherein a check valve (16) is mounted on a suction pipe (15) connected to the ejector (14). 6. A filter (21) for removing dust is provided on the casing (1), one end of the filter (21) is communicated with the air chamber (12), and the other end is released to the atmosphere. The ozone gas dissolving apparatus according to claim 1, wherein a water supply pump (17) is connected to (11).