Glass dielectric double-gap ozone discharge tube

CN224362563UActive Publication Date: 2026-06-16XUZHOU JINYUAN OZONE EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
XUZHOU JINYUAN OZONE EQUIP CO LTD
Filing Date
2025-07-22
Publication Date
2026-06-16

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Abstract

The utility model discloses a glass medium double gap ozone discharge tube, it includes bottom plate, the upper surface fixed connection of bottom plate has two fixed frame, the upper surface fixed connection of two fixed frame has cooling box, the lateral surface intercommunication of cooling box has the water inlet pipe, the other end of water inlet pipe intercommunication to the inside of stainless steel pipe, the lateral surface fixed connection water pump of cooling box, the upper surface of cooling box is provided with the exhaust port, the upper surface fixed connection of cooling box has motor no.
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Description

Technical Field

[0001] This utility model relates to the field of cooling technology, and in particular to a glass dielectric double-gap ozone discharge tube. Background Technology

[0002] In ozone production and related fields, the stability of the discharge environment and temperature control have a crucial impact on product quality and equipment efficiency. Traditional equipment often experiences excessively high temperatures during operation because the large amount of heat generated during discharge cannot be dissipated in time. This not only accelerates ozone decomposition and reduces production efficiency but also causes equipment components to age and break down faster due to prolonged exposure to high temperatures, severely impacting the equipment's lifespan. Furthermore, vibrations and displacements during equipment operation also interfere with the stability of the discharge environment, adversely affecting overall operational performance. Utility Model Content

[0003] The purpose of this invention is to solve at least one of the technical problems existing in the prior art, and to provide a glass dielectric double-gap ozone discharge tube, which solves the problem that in the operation of traditional equipment, a large amount of heat generated by discharge cannot be dissipated in time, resulting in excessively high local temperature, which not only accelerates the decomposition of ozone but also reduces production efficiency.

[0004] This invention also provides a glass dielectric double-gap ozone discharge tube as described above. The circulating cooling system directly absorbs the discharge heat through the interlayer water flow, the stirring blades accelerate the heat exchange of the cooling water, and the fan enhances the heat dissipation efficiency, forming a highly efficient cooling cycle. This can effectively suppress the impact of high temperature on ozone decomposition, while avoiding component aging or damage due to long-term high-temperature operation, thus extending the service life of the equipment. The stable connection of the stainless steel mesh, stainless steel pipe and other structures, together with the support of the bracket and fixed frame, reduces vibration and displacement during operation, further ensuring the stability of the discharge environment.

[0005] This technical solution discloses a glass dielectric double-gap ozone discharge tube, comprising: a base plate; two supports fixedly connected to the upper surface of the base plate; stainless steel tubes fixedly connected to the upper surfaces of the two supports; a glass tube disposed on the inner surface of the stainless steel tube; a stainless steel mesh sleeved on the inner wall of the glass tube; a high-voltage electrode rod disposed inside the stainless steel mesh; two fixing frames fixedly connected to the upper surface of the base plate; a cooling box fixedly connected to the upper surface of the two fixing frames; a water inlet pipe connected to the side surface of the cooling box; the other end of the water inlet pipe connected to the interior of the stainless steel tube; a water pump fixedly connected to the side surface of the cooling box; the output end of the water pump connected to the interior of the cooling box; and a drain valve disposed on the upper surface of the cooling box. The cooling box has an air inlet, and a motor is fixedly connected to the upper surface of the cooling box. A fan is fixedly connected to the output end of the motor. A second motor is fixedly connected to the lower surface of the cooling box. A stirring blade is fixedly connected to the output end of the second motor. The circulating cooling system of the above components directly absorbs the discharge heat through the jacketed water flow. The stirring blade accelerates the heat exchange of the cooling water, and the fan enhances the heat dissipation efficiency, forming a highly efficient cooling cycle. This can effectively suppress the impact of high temperature on ozone decomposition, and at the same time avoid the aging or damage of components due to long-term high-temperature operation, thus extending the service life of the equipment. The stable connection of the stainless steel mesh, stainless steel pipe and other structures, together with the support of the bracket and fixed frame, reduces vibration and displacement during operation, further ensuring the stability of the discharge environment.

[0006] According to the present invention, a glass dielectric double-gap ozone discharge tube is provided with a support leg fixedly connected to the lower surface of the base plate, and a base is provided on the lower surface of the support leg. The above components can reduce vibration during machine operation.

[0007] According to the present invention, a glass dielectric double-gap ozone discharge tube is provided, wherein the input end of the water pump is connected to a drain pipe, and the other end of the drain pipe is connected to the interior of a stainless steel pipe, thereby facilitating the discharge of water from the stainless steel pipe.

[0008] According to the present invention, in a glass dielectric double-gap ozone discharge tube, both ends of the stainless steel mesh are sealed, and one end of the stainless steel mesh is connected to a stainless steel electrode. By sealing both ends of the above components, the electric field distribution can be more uniform, the edge effect can be reduced, and the discharge can be more stable.

[0009] According to the present invention, in a glass dielectric double-gap ozone discharge tube, water from the inlet pipe is discharged into the interlayer between the stainless steel tube and the glass tube, and the above components can be used to cool the discharge tube during operation.

[0010] According to the present invention, a glass dielectric double-gap ozone discharge tube is provided, wherein the high-voltage electrode rod is fixedly connected to a stainless steel electrode connector. The high-voltage electrode rod is made of stainless steel. The above components have strong corrosion resistance and high mechanical strength, making them suitable for use in humid, dusty, or chemically corrosive environments.

[0011] According to the present invention, a glass dielectric double-gap ozone discharge tube is provided with a flexible plate on the lower surface of the base. The flexible plate is made of rubber. The above components can reduce the noise generated during machine operation.

[0012] According to the present invention, a glass dielectric double-gap ozone discharge tube is provided with multiple air inlets at one end of the stainless steel tube and an exhaust pipe at the other end of the stainless steel tube. Through the multiple air inlets of the above components, the gas can enter the discharge tube more evenly, avoid the gas from concentrating in a certain area, ensure that the gas concentration in various parts of the discharge gap is relatively consistent, and create a stable environment for ozone generation.

[0013] Beneficial effects: The circulating cooling system directly absorbs discharge heat through the jacketed water flow, the stirring blades accelerate the heat exchange of the cooling water, and the fan enhances heat dissipation efficiency, forming a highly efficient cooling cycle. This can effectively suppress the impact of high temperature on ozone decomposition, while also preventing equipment from aging or being damaged due to long-term high-temperature operation, thus extending the service life of the equipment. The stable connection of the stainless steel mesh, stainless steel pipes, and other structures, combined with the support of brackets and fixed frames, reduces vibration and displacement during operation, further ensuring the stability of the discharge environment. Attached Figure Description

[0014] The present invention will be further described below with reference to the accompanying drawings and embodiments;

[0015] Figure 1 This is a front view of the glass dielectric double-gap ozone discharge tube of this utility model;

[0016] Figure 2 This is a top view of the glass dielectric double-gap ozone discharge tube of this utility model;

[0017] Figure 3 This is a bottom view of the glass dielectric double-gap ozone discharge tube of this utility model;

[0018] Figure 4 This is a side cross-sectional view of the glass dielectric double-gap ozone discharge tube of this utility model.

[0019] Legend:

[0020] 1. Base plate; 2. Support legs; 3. Base; 4. Bracket; 5. Fixing frame; 6. Exhaust pipe; 7. Water inlet pipe; 8. Drain pipe; 9. Stainless steel electrode connector; 10. Air inlet; 11. Water pump; 12. Cooling tank; 13. Motor 1; 14. Exhaust port; 15. Fan; 16. Stirring blades; 17. Motor 2; 18. Stainless steel pipe; 19. Glass tube; 20. High-voltage electrode rod; 21. Stainless steel mesh. Detailed Implementation

[0021] This section will describe in detail the specific embodiments of the present utility model. The preferred embodiments of the present utility model are shown in the accompanying drawings. The purpose of the drawings is to supplement the textual description with graphics, so that people can intuitively and vividly understand each technical feature and the overall technical solution of the present utility model, but they should not be construed as limiting the scope of protection of the present utility model.

[0022] Reference Figure 1-4 This utility model discloses a glass dielectric double-gap ozone discharge tube, comprising: a base plate 1, a support leg 2 fixedly connected to the lower surface of the base plate 1, a base 3 provided on the lower surface of the support leg 2, a flexible plate made of rubber provided on the lower surface of the base 3, two brackets 4 fixedly connected to the upper surface of the base plate 1, a stainless steel tube 18 fixedly connected to the upper surface of the two brackets 4, a plurality of air inlets 10 provided at one end of the stainless steel tube 18, an exhaust pipe 6 provided at the other end of the stainless steel tube 18, a glass tube 19 provided on the inner surface of the stainless steel tube 18, a stainless steel mesh 21 sleeved on the inner wall of the glass tube 19, both ends of the stainless steel mesh 21 being sealed, a stainless steel electrode connector 9 at one end of the stainless steel mesh 21, a high-voltage electrode rod 20 provided inside the stainless steel mesh 21, the high-voltage electrode rod 20 being fixedly connected to the stainless steel electrode connector 9, and the high-voltage electrode rod 20 being made of stainless steel.

[0023] Specifically: The equipment introduces the gas to be treated through multiple air inlets 10 at one end of the stainless steel tube 18. The gas flows inside the stainless steel tube 18 and enters the double-gap discharge region composed of the stainless steel tube 18, glass tube 19, stainless steel mesh 21, and high-voltage electrode rod 20. The glass tube 19 acts as a medium, separating two discharge gaps: one between the stainless steel tube 18 and the glass tube 19, and the other between the glass tube 19 and the stainless steel mesh 21. When the high-voltage power supply supplies power to the high-voltage electrode rod 20 through the stainless steel electrode connector 9, a strong electric field is formed between the high-voltage electrode rod 20, the stainless steel mesh 21, and the stainless steel tube 18, causing the gas flowing through the double gap to ionize and generate a large number of high-energy electrons and active particles. Oxygen molecules decompose and recombine under the action of these particles to generate ozone. Because the stainless steel mesh 21 is sealed at both ends and stably connected to the high-voltage electrode rod 20, combined with the fixed structure of the stainless steel tube 18, the electric field distribution is ensured to be uniform, improving the gas ionization efficiency and the ozone generation concentration.

[0024] Two fixed brackets 5 are fixedly connected to the upper surface of the base plate 1. A cooling box 12 is fixedly connected to the upper surface of the two fixed brackets 5. A water inlet pipe 7 is connected to the side surface of the cooling box 12. The other end of the water inlet pipe 7 is connected to the inside of the stainless steel pipe 18. The water in the water inlet pipe 7 is discharged into the interlayer between the stainless steel pipe 18 and the glass pipe 19. A water pump 11 is fixedly connected to the side surface of the cooling box 12. The output end of the water pump 11 is connected to the inside of the cooling box 12. The input end of the water pump 11 is connected to the drain pipe 8. The other end of the drain pipe 8 is connected to the inside of the stainless steel pipe 18. An exhaust port 14 is provided on the upper surface of the cooling box 12. A motor 13 is fixedly connected to the upper surface of the cooling box 12. A fan 15 is fixedly connected to the output end of the motor 13. A motor 2 17 is fixedly connected to the lower surface of the cooling box 12. A stirring blade 16 is fixedly connected to the output end of the motor 2 17.

[0025] Specifically: Cooling water in the cooling tank 12 flows into the interlayer between the stainless steel pipe 18 and the glass pipe 19 through the inlet pipe 7 to absorb the heat generated during the discharge process; the water pump 11 pumps the cooled water after absorbing heat back to the cooling tank 12 through the drain pipe 8; the second motor 17 drives the stirring blades 16 to stir the cooling water and accelerate the heat diffusion; the first motor 13 drives the fan 15 to blow air into the cooling tank 12 through the exhaust port 14 to further reduce the water temperature, forming a circulating cooling system to avoid ozone decomposition or equipment damage caused by high temperature.

[0026] Working Principle: The equipment introduces the gas to be treated through multiple air inlets 10 at one end of the stainless steel tube 18. The gas flows inside the stainless steel tube 18 and enters the double-gap discharge region composed of the stainless steel tube 18, glass tube 19, stainless steel mesh 21, and high-voltage electrode rod 20. The glass tube 19 acts as a medium, separating two discharge gaps: one between the stainless steel tube 18 and the glass tube 19, and the other between the glass tube 19 and the stainless steel mesh 21. When the high-voltage power supply supplies power to the high-voltage electrode rod 20 through the stainless steel electrode connector 9, a strong electric field is formed between the high-voltage electrode rod 20, the stainless steel mesh 21, and the stainless steel tube 18. This ionizes the gas flowing through the double gap, generating a large number of high-energy electrons and active particles. Under the action of these particles, oxygen molecules decompose and recombine. Ozone is generated. Due to the sealed ends of the stainless steel mesh 21 and its stable connection with the high-voltage electrode rod 20, combined with the fixed structure of the stainless steel tube 18, the electric field distribution is ensured to be uniform, which improves the gas ionization efficiency and ozone generation concentration. At the same time, the cooling system operates synchronously: the cooling water in the cooling tank 12 flows into the interlayer between the stainless steel tube 18 and the glass tube 19 through the water inlet pipe 7 to absorb the heat generated during the discharge process; the water pump 11 pumps the cooled water after absorbing heat back to the cooling tank 12 through the drain pipe 8; the second motor 17 drives the stirring blades 16 to stir the cooling water and accelerate the heat diffusion; the first motor 13 drives the fan 15 to blow air into the cooling tank 12 through the exhaust port 14 to further reduce the water temperature, forming a circulating cooling system to avoid ozone decomposition or equipment damage caused by high temperature.

[0027] The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings. However, the present utility model is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present utility model.

Claims

1. A glass dielectric double-gap ozone discharge tube, characterized in that, include: A base plate (1) has two supports (4) fixedly connected to its upper surface. A stainless steel tube (18) is fixedly connected to the upper surface of each support (4). A glass tube (19) is installed on the inner surface of the stainless steel tube (18). A stainless steel mesh (21) is fitted onto the inner wall of the glass tube (19). A high-voltage electrode rod (20) is installed inside the stainless steel mesh (21). Two fixing frames (5) are fixedly connected to the upper surface of the base plate (1). A cooling box (12) is fixedly connected to the upper surface of the two fixing frames (5). A water inlet pipe (7) is connected to the side surface of the cooling box (12). The other end of the water inlet pipe (7) is connected to the interior of the stainless steel pipe (18). A water pump (11) is fixedly connected to the side surface of the cooling box (12). The output end of the water pump (11) is connected to the interior of the cooling box (12). An exhaust port (14) is provided on the upper surface of the cooling box (12). A motor (13) is fixedly connected to the upper surface of the cooling box (12). A fan (15) is fixedly connected to the output end of the motor (13). A motor (17) is fixedly connected to the lower surface of the cooling box (12). A stirring blade (16) is fixedly connected to the output end of the motor (17).

2. The glass dielectric double-gap ozone discharge tube according to claim 1, characterized in that, The lower surface of the base plate (1) is fixedly connected to a support leg (2), and the lower surface of the support leg (2) is provided with a base (3).

3. The glass dielectric double-gap ozone discharge tube according to claim 1, characterized in that, The input end of the water pump (11) is connected to a drain pipe (8), and the other end of the drain pipe (8) is connected to the interior of a stainless steel pipe (18).

4. The glass dielectric double-gap ozone discharge tube according to claim 1, characterized in that, Both ends of the stainless steel mesh (21) are sealed, and one end of the stainless steel mesh (21) is a stainless steel electrode connector (9).

5. The glass dielectric double-gap ozone discharge tube according to claim 1, characterized in that, Water from the inlet pipe (7) is discharged into the interlayer between the stainless steel pipe (18) and the glass pipe (19).

6. The glass dielectric double-gap ozone discharge tube according to claim 1, characterized in that, The high-voltage electrode rod (20) is fixedly connected to the stainless steel electrode connector (9), and the high-voltage electrode rod (20) is made of stainless steel.

7. A glass dielectric double-gap ozone discharge tube according to claim 2, characterized in that, The lower surface of the base (3) is provided with a soft plate, which is made of rubber.

8. The glass dielectric double-gap ozone discharge tube according to claim 1, characterized in that, The stainless steel pipe (18) has multiple air inlets (10) at one end and an exhaust pipe (6) at the other end.