CN215711779U - Double-gap high-concentration ozone generating equipment - Google Patents

Abstract

The utility model relates to double-gap high-concentration ozone generating equipment which comprises a shell, an ozone generating tube guide plate, an ozone generating tube fixing plate, a spring pressing plate and a fixing column, wherein the ozone generating tube guide plate is arranged on the shell; the shell is in a hollow cylindrical shape with two ends sealed; the ozone generating tube comprises a radiating tube, a quartz tube, an anode tube and a tetrafluoro plate; the quartz tube is arranged in the middle of the radiating tube, and the anode tube is arranged in the middle of the quartz tube; a first gap is arranged between the outer wall of the quartz tube and the inner wall of the heat radiating tube, and a second gap is arranged between the inner wall of the quartz tube and the anode tube. Through the first clearance and the second clearance that set up, it is efficient, output big to generate ozone.

Description

Double-gap high-concentration ozone generating equipment

Technical Field

The utility model relates to an ozone generator, in particular to double-gap high-concentration ozone generating equipment.

Background

Ozone is a universally recognized broad-spectrum efficient sterilization disinfectant, has strong oxidizing property, mainly has the effects of oxidation, sterilization, decoloration and deodorization, and is used for diminishing inflammation and sterilizing in various industries, such as dust-free workshops in the food industry; the ozone used is generally produced by means of an ozone generator.

The application range of the ozone generator is as follows:

1. chemical oxidation: ozone is used as oxidant, catalyst and refining agent in chemical industry, petroleum industry, paper making industry, textile industry, pharmaceutical industry and essence industry. The strong oxidizing ability of ozone can easily break the carbon chain bond of olefin and alkyne organic matters, so that the organic matters are partially oxidized to synthesize new compounds.

2. Bleaching paper pulp: ozone is used in pulp and paper industry for improving the mechanical properties of chemical or mechanical pulp and reducing the environmental pollution of chlorine during the pulp bleaching process.

3. Water treatment: ozone has high killing rate on bacteria, viruses and other microbes in water, can remove organic compounds and other pollutants thoroughly without secondary pollution, and can reduce Biochemical Oxygen Demand (BOD) and Chemical Oxygen Demand (COD), remove nitrite, suspended solids and decolor. Is applied to urban sewage treatment, urban drinking water treatment bottled water industrial wastewater treatment, water circulation and reuse of swimming pools of ocean halls and the like

The existing ozone generator generally discharges in a single gap mode during working, and has the problems of small discharge gap, small ozone yield and low ozone concentration when the discharge gap is large, so that the problem is urgently solved.

From the above, how to design a double gap high concentration ozone generating device, the ozone concentration and the ozone yield are high, which is the problem we are to solve at present.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an ozone generator which has high concentration of generated ozone and high yield of generated ozone.

In order to solve the problems, the utility model adopts the following technical proposal,

a double-gap high-concentration ozone generating device comprises an ozone generating tube; the ozone generating tube comprises a radiating tube, a quartz tube and an anode tube;

the quartz tube is arranged in the middle of the radiating tube, and the anode tube is arranged in the middle of the quartz tube; a first gap is arranged between the outer wall of the quartz tube and the inner wall of the heat radiating tube, and a second gap is arranged between the inner wall of the quartz tube and the outer wall of the anode tube.

Further, the ozone generator comprises a shell, an ozone generating tube guide plate, an ozone generating tube fixing plate, a spring pressing plate and a fixing column;

the shell is in a hollow cylindrical shape with two ends sealed; an ozone generating tube guide plate and an ozone generating tube fixing plate are arranged in the shell from top to bottom;

one end of the fixing column is arranged on the upper surface of the middle of the ozone generating tube fixing plate;

the other end of the fixing column penetrates through the ozone generating tube guide plate and is fixedly connected with the spring pressing plate;

the ozone generating tube also comprises a tetrafluoro plate;

the radiating pipe is arranged on one side of the fixing column;

one end of the radiating tube, one end of the quartz tube and one end of the anode tube are fixedly connected with the ozone generating tube fixing plate;

the other end of the radiating pipe penetrates through the ozone generating pipe guide plate and is fixedly connected with the tetrafluoro plate;

the other end of the quartz tube is fixedly connected with the tetrafluoro plate;

the other end of the positive pole tube penetrates through the tetrafluoro plate and is connected with the spring pressing plate through a spring;

the middle upper part of the radiating pipe is clamped with the guide plate of the ozone generating pipe.

Furthermore, a water outlet and a water inlet for cooling the ozone generating pipe are formed in the side wall of the shell; the side wall of the shell is also provided with a compressed air inlet and an ozone outlet which are used for generating ozone; the water inlet and the water outlet are respectively communicated with the interior of the shell; the compressed air inlet and the ozone outlet are respectively communicated with the first gap and the second gap.

Further, when the ozone generating tube works, the positive electrode of the high-voltage power supply is electrically connected with the spring pressing plate, and the spring pressing plate is electrically connected with the positive electrode tube through the spring; and the negative electrode of the high-voltage power supply is electrically connected with the radiating pipe.

Further, the number of the ozone generating tubes is at least one.

The utility model has the beneficial effects that:

1. the positive pole tube is arranged in the middle of the radiating tube through the quartz tube, and the positive pole tube is arranged in the middle of the quartz tube; a first gap is formed between the outer wall of the quartz tube and the inner wall of the heat radiating tube, and a second gap is formed between the inner wall of the quartz tube and the anode tube; through the design of double gaps, the inlet amount of compressed air can be increased, so that the yield of ozone is increased, and the concentration of ozone is ensured;

2. the other end of the radiating pipe is fixedly connected with the tetrafluoro plate, and the tetrafluoro plate is not conductive under the action of high voltage, so that the radiating pipe can be prevented from being directly conducted with the positive electrode of a high-voltage power supply and burnt out;

3. one end of the spring is fixedly connected with a spring pressing plate serving as the anode of the ozone generator through the arranged spring, and the other end of the spring is connected with the anode tube; this has the advantage that if the high voltage supply voltage is too high, the spring is directly blown and the ozone generator is no longer operating; if adopt other connected mode, often can take place because of the too big problem of puncturing the quartz capsule of high voltage power supply voltage, quartz capsule cost per se is than higher, and the installation is dismantled inconveniently simultaneously, so the design of this spring has solved the too big problem of voltage occasionally, unusual practicality.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is an enlarged view of FIG. 1 at B;

FIG. 3 is a schematic external view of the present invention;

FIG. 4 is a schematic view of the structure of an ozone generating tube;

fig. 5 is a cross-sectional view taken at a-a of fig. 4.

The reference numbers in the figures illustrate:

the ozone generator comprises a shell 1, an ozone generating tube 2, an ozone generating tube 3, an ozone generating tube 4, an ozone generating tube fixing plate 5, an ozone outlet 6, a water inlet 6, a water outlet 7, a compressed air inlet 8, a fixed column 9, a spring pressing plate 30, a spring 31, a positive pole tube 32, a quartz tube 33, a radiating tube 34, a teflon plate 35, a first gap 36 and a second gap 37.

Detailed Description

The drawings in the embodiments of the utility model will be combined; the technical scheme in the embodiment of the utility model is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the utility model; but not all embodiments, are based on the embodiments of the utility model; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

Examples

As shown in fig. 1-5:

a double-gap high-concentration ozone generating device comprises an ozone generating tube 3; the ozone generating tube 3 comprises a heat radiating tube 34, a quartz tube 33 and a positive tube 32;

the quartz tube 33 is arranged in the middle of the heat dissipation tube 34, and the anode tube 32 is arranged in the middle of the quartz tube 33; a first gap 37 is arranged between the outer wall of the quartz tube 33 and the inner wall of the radiating tube 34, and a second gap 36 is arranged between the inner wall of the quartz tube 33 and the outer wall of the anode tube 32; this device quartz capsule 33 is inside and quartz capsule 33 is outside double gap discharge, and increase ozone generation concentration improves the result of use, reduces equipment volume, reduces the input cost.

The ozone generator also comprises a shell 1, an ozone generating tube guide plate 2, an ozone generating tube fixing plate 4, a spring pressing plate 30 and a fixing column 9;

the shell 1 is a hollow cylinder with two ends sealed; an ozone generating tube guide plate 2 and an ozone generating tube fixing plate 4 are arranged in the shell 1 from top to bottom;

one end of the fixing column 9 is arranged on the upper surface of the middle of the ozone generating tube fixing plate 4;

the other end of the fixing column 9 penetrates through the ozone generating tube guide plate 2 and is fixedly connected with the spring pressing plate 30;

the ozone generating tube 3 further comprises a tetrafluoro plate 35; the teflon plate 35 is used for insulating the heat dissipation pipe 34 from the anode pipe 32;

the radiating pipe 34 is arranged outside the fixing column 9;

one end of the radiating pipe 34, one end of the quartz pipe 33 and one end of the anode tube 32 are all fixedly connected with the ozone generating tube fixing plate 4;

the other end of the radiating pipe 34 passes through the ozone generating pipe guide plate 2 and is fixedly connected with the tetrafluoro plate 35;

the other end of the quartz tube 33 is fixedly connected with the tetrafluoro plate 35;

the other end of the positive pole tube 32 passes through the tetrafluoro plate 35 and then is connected with the spring pressing plate 30 through a spring 31;

the middle upper part of the radiating pipe 34 is clamped with the ozone generating pipe guide plate 2.

A water outlet 7 and a water inlet 6 for cooling the ozone generating pipe 3 are arranged on the side wall of the shell 1; the side wall of the shell 1 is also provided with a compressed air inlet 8 and an ozone outlet 5 for generating ozone; the water inlet 6 and the water outlet 7 are respectively communicated with the shell 1; is used for absorbing the heat emitted by the ozone generator when in work; the compressed air inlet 8 and the ozone outlet 5 communicate with the first gap 36 and the second gap 37, respectively.

When the ozone generating tube 3 works, the anode of a required high-voltage power supply is electrically connected with the spring pressing plate 30, and the spring pressing plate 30 is electrically connected with the anode tube 32 through the spring 31; the negative pole of the high voltage power supply is electrically connected with the heat dissipation pipe 34.

The other end of the positive pole tube 32 sequentially penetrates through the ozone generating tube guide plate 2 and the tetrafluoro plate 35 and is connected with the spring pressing plate 30 through a spring 31; the advantage of this is that if the voltage is too large, the spring 31 is directly blown, the ozone generator is not working, if other connection methods are adopted, the problem that the quartz tube 33 is broken due to the too large voltage often occurs, the cost of the quartz tube 33 itself is high, and the installation and disassembly are inconvenient, so the design of the spring 31 solves the problem that the voltage is unstable and occasionally too large in the production.

When the ozone generating tube 3 works, the positive pole of the high-voltage power supply is electrically connected with the spring pressing plate 30, and the negative pole of the high-voltage power supply is electrically connected with the radiating tube 34. The high voltage power source discharges through the space between the anode tube 32 and the heat dissipating tube 34 to generate ozone, and during the high voltage discharge, the high voltage power passes through the tube wall of the quartz tube 33 to form plasma, which corona the oxygen in the air to form ozone.

The number of the ozone generating tubes 3 is at least one, and the number of the ozone generating tubes 3 can be increased or decreased according to the ozone amount requirement of a user in unit time. However, the required voltage of the high-voltage power supply needs to be increased, the sectional area of the shell 1 and the total amount of the required high-voltage gas and cooling water need to be increased, and overheating and burnout of the device caused by insufficient cooling water are avoided.

The working process of the utility model is as follows:

the device is installed, the device is electrified, high-pressure air enters the ozone generator 4, and ozone is generated in the first gap 36 and the second gap 37 of the ozone generating tube 3; meanwhile, the cooling water enters the pipe wall of the radiating pipe 34 through the water inlet to absorb the heat released when the ozone is generated, thereby preventing the generated ozone from being damaged due to high temperature and improving the efficiency of the ozone generating pipe 3.

The above; but are merely preferred embodiments of the utility model; the scope of the utility model is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the utility model are equally replaced or changed; are intended to be covered by the scope of the present invention.

Claims (5)

1. A double-gap high-concentration ozone generating device is characterized by comprising an ozone generating tube (3); the ozone generating tube (3) comprises a radiating tube (34), a quartz tube (33) and a positive tube (32);

the quartz tube (33) is arranged in the middle of the radiating tube (34), and the anode tube (32) is arranged in the middle of the quartz tube (33); the outer wall of quartz tube (33) with be equipped with first clearance (37) between cooling tube (34) inner wall, the inner wall of quartz tube (33) with be equipped with second clearance (36) between positive pole pipe (32) outer wall.

2. A double gap high concentration ozone generating apparatus according to claim 1, wherein: the ozone generator also comprises a shell (1), an ozone generating tube guide plate (2), an ozone generating tube fixing plate (4), a spring pressing plate (30) and a fixing column (9);

the shell (1) is in a hollow cylindrical shape with two ends being blocked; an ozone generating tube guide plate (2) and an ozone generating tube fixing plate (4) are arranged in the shell (1) from top to bottom;

one end of the fixing column (9) is arranged on the upper surface of the middle of the ozone generating tube fixing plate (4);

the other end of the fixed column (9) penetrates through the ozone generating tube guide plate (2) and is fixedly connected with the spring pressing plate (30);

the ozone generating tube (3) also comprises a tetrafluoro plate (35);

the radiating pipe (34) is arranged on the outer side of the fixing column (9);

one end of the radiating pipe (34), one end of the quartz pipe (33) and one end of the anode tube (32) are fixedly connected with the ozone generating tube fixing plate (4);

the other end of the radiating pipe (34) penetrates through the ozone generating pipe guide plate (2) to be fixedly connected with the tetrafluoro plate (35);

the other end of the quartz tube (33) is fixedly connected with the tetrafluoro plate (35);

the other end of the positive tube (32) penetrates through the tetrafluoro plate (35) and then is connected with the spring pressing plate (30) through a spring (31);

the middle upper part of the radiating pipe (34) is clamped with the ozone generating pipe guide plate (2).

3. A double gap high concentration ozone generating apparatus according to claim 2, wherein: a water outlet (7) and a water inlet (6) for cooling the ozone generating pipe (3) are arranged on the side wall of the shell (1); the side wall of the shell (1) is also provided with a compressed air inlet (8) and an ozone outlet (5) for generating ozone; the water inlet (6) and the water outlet (7) are respectively communicated with the inside of the shell (1); the compressed air inlet (8) and the ozone outlet (5) communicate with the first gap (36) and the second gap (37), respectively.

4. A double gap high concentration ozone generating apparatus according to claim 3, wherein: when the ozone generating tube (3) works, the spring pressing plate (30) is electrically connected with the positive electrode of a high-voltage power supply, and the spring pressing plate (30) is electrically connected with the positive pole tube (32) through the spring (31); the radiating pipe (34) is electrically connected with the negative pole of the high-voltage power supply.

5. The double gap high concentration ozone generating apparatus as claimed in claim 4, wherein: the number of the ozone generating tubes (3) is at least one.

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