Ozone generator cooling structure

By using a cooling mechanism composed of aluminum heat-conducting fins and U-shaped tubes, combined with a cooling cover made of alumina ceramic filter plates and phenolic foam composite boards, the problem of low cooling efficiency of ozone generators in high-temperature and enclosed environments has been solved, achieving efficient heat dissipation and improving equipment stability and lifespan.

CN224394596UActive Publication Date: 2026-06-23SHENZHEN GREEN FIELDS ENVIRONMENTAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHENZHEN GREEN FIELDS ENVIRONMENTAL TECH CO LTD
Filing Date
2025-07-29
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing ozone generators have low cooling efficiency in high-temperature, enclosed environments, leading to increased workload and affecting stability and service life.

Method used

The cooling mechanism, consisting of aluminum heat-conducting plates and U-shaped tubes, combined with a cooling cover made of alumina ceramic filter plates and phenolic foam composite boards, forms an efficient airflow cooling system through external coolant circulation and an intake fan, ensuring the ozone generating unit is cooled down.

Benefits of technology

The ozone generator achieves efficient heat dissipation in a high-temperature, enclosed environment, reducing workload and improving stability and service life.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an ozone generator cooling structure, it includes ozone generator casing, output pipe, two exhaust port and power cord, the left side fixed intercommunication of ozone generator casing has cooling cover, the inside of cooling cover is provided with cooling mechanism, the left side of cooling cover is provided with suction fan, the left side of suction fan is provided with filter plate, the cooling method of inside of part ozone generator of existing has solved, uses the fan to carry on the air -exhaust, makes the outside air to enter ozone generator ozone generator casing inside, forms the air current, and the temperature of inside ozone generation unit work produces is dissipated, especially when ozone generator is in the environment temperature is higher, and the space is more closed place and works, and the inside ozone generation unit can not obtain the efficient heat dissipation, and the ozone generator work load increase is easy to cause, and the problem of influence stability and service life.
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Description

Technical Field

[0001] This utility model relates to the field of ozone generators, and more particularly to a cooling structure for an ozone generator. Background Technology

[0002] An ozone generator is a device that converts oxygen into ozone using specific technology. It is widely used in disinfection, oxidation treatment, air purification and other fields.

[0003] Currently, Chinese patent CN219217574U discloses an ozone generator. The ozone generator features a flexible hose, connecting pipe, outlet pipe, vertical shaft, and bracket. The outlet pipe can be rotated to change its direction, allowing the ozone generator to be placed in a corner. This design makes assembly and pipe connection very convenient, avoiding the need to change the location due to insufficient installation space and improving the practicality of the ozone generator's connection.

[0004] Some existing ozone generators use fans to draw in outside air, creating an airflow that dissipates the heat generated by the ozone generating unit during operation. However, this method is inefficient when the ozone generator operates in a high-temperature, enclosed space. This can lead to increased workload, affecting stability and lifespan. Summary of the Invention

[0005] The main purpose of this invention is to provide a cooling structure for an ozone generator, aiming to solve the problem that some existing ozone generators use a fan to draw in outside air into the ozone generator housing to form an airflow, which dissipates the heat generated by the internal ozone generating unit during operation. However, this method is not efficient in dissipating heat, especially when the ozone generator is operating in a high-temperature, relatively enclosed space. This can easily lead to an increased workload on the ozone generator, affecting its stability and service life.

[0006] To achieve the above objectives, the present invention proposes an ozone generator cooling structure comprising an ozone generator housing, an output pipe, two exhaust vents and a power cord. A cooling cover is fixedly connected to the left side of the ozone generator housing. A cooling mechanism is provided inside the cooling cover. An intake fan is provided on the left side of the cooling cover, and a filter plate is provided on the left side of the intake fan.

[0007] The cooling mechanism includes several temperature-conducting plates, a U-shaped tube, and two liquid injection tubes. The side of the temperature-conducting plate closest to the U-shaped tube is fixedly connected to the surface of the U-shaped tube. The side of the liquid injection tube closest to the U-shaped tube is fixedly connected to the U-shaped tube. The U-shaped tube is fixedly connected inside the cooling cover. The temperature-conducting plates and the U-shaped tube are both made of aluminum.

[0008] Preferably, a fixing ring is fixedly connected to the left side of the cooling shroud, the air intake fan is fixedly connected to the inner wall of the fixing ring, and the right side of the filter plate is in contact with the left side of the fixing ring.

[0009] Preferably, the front and rear sides of the left side of the cooling cover are fixedly connected to support plates, and the left side of the support plates is fixedly connected to a slide rail, with the filter plate movably inserted into the slide rail.

[0010] Preferably, a connecting plate is fixedly connected to the top of the filter plate, the surface of the connecting plate is in contact with the surface of the slide rail, and a limit button is provided on the opposite side of the two slide rails. The side of the limit button near the connecting plate passes through the connecting plate and is connected to the internal thread of the slide rail.

[0011] Preferably, a handle is fixedly connected to the top of the connecting plate, and the filter plate is made of alumina ceramic.

[0012] Preferably, the cooling cover is made of phenolic foam composite board.

[0013] Preferably, a protective net is fixedly connected to the inner wall of the fixing ring, and the protective net is made of woven steel wire.

[0014] In this invention, the top and bottom injection pipes are connected to an external coolant circulation cooling device, allowing the external coolant to circulate within the loop tube. The cooling mechanism inside the cooling shroud consists of temperature-conducting fins, a loop tube, and injection pipes. Both the temperature-conducting fins and the loop tube are made of aluminum, utilizing aluminum's excellent thermal conductivity to transfer low temperatures. An external controller then controls the intake fan. The air drawn in by the fan first passes through an alumina ceramic filter plate to filter dust. The filter plate is securely installed and easily disassembled via slide rails and limit buttons on the support plate. The cooling shroud is made of phenolic foam composite board to reduce heat loss. The intake fan draws the filtered air into the cooling shroud, where it interacts with multiple low-temperature conductive elements. The cooling plate makes full contact with the ozone generator, allowing for rapid cooling before entering the ozone generator housing. This cools the ozone generating unit and prevents inefficient heat dissipation for the internal ozone generating unit when operating in high-temperature, relatively enclosed environments. It addresses the problem of some existing ozone generators using fans to draw in outside air, creating airflow to dissipate the heat generated by the internal ozone generating unit. This is particularly problematic in high-temperature, enclosed environments where inefficient heat dissipation increases the workload, affecting stability and lifespan. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.

[0016] Figure 1 This is a schematic diagram of the structure of an embodiment of the present utility model;

[0017] Figure 2 This is a three-dimensional structural diagram of the right side of the ozone generator housing in an embodiment of this utility model;

[0018] Figure 3 This is a three-dimensional connection diagram of the filter plate and the slide rail in an embodiment of this utility model;

[0019] Figure 4 This is a three-dimensional connection diagram of the cooling cover and the fixing ring in an embodiment of this utility model;

[0020] Figure 5 This is a three-dimensional connection diagram of the cooling mechanism in an embodiment of this utility model;

[0021] Figure 6 This is a three-dimensional connection diagram of the connecting plate and the filter plate in an embodiment of this utility model;

[0022] Figure 7 This is a three-dimensional exploded view of the fixing ring and the protective net in an embodiment of this utility model.

[0023] Explanation of reference numerals in the attached diagram: 1. Ozone generator housing; 2. Cooling cover; 3. Cooling mechanism; 301. Temperature conductive plate; 302. U-shaped tube; 303. Liquid injection tube; 4. Filter plate; 5. Output tube; 6. Exhaust vent; 7. Power cord; 8. Support plate; 9. Slide rail; 10. Connecting plate; 11. Fixing ring; 12. Handle; 13. Intake fan; 14. Protective net; 15. Limit button.

[0024] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0025] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0026] It should be noted that all directional indicators (such as up, down, left, right, front, back, etc.) in this utility model embodiment are only used to explain the relative positional relationship and movement of each component in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicator will also change accordingly.

[0027] Furthermore, in this utility model, the use of terms such as "first," "second," etc., is for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. In the description of this utility model, "multiple" means at least two, such as two, three, etc., unless otherwise explicitly specified.

[0028] Furthermore, the technical solutions of the various embodiments of this utility model can be combined with each other, but only if they are based on the ability of those skilled in the art to implement them. When the combination of technical solutions is contradictory or cannot be implemented, it should be considered that such combination of technical solutions does not exist and is not within the scope of protection claimed by this utility model.

[0029] This invention provides a cooling structure for an ozone generator, aiming to solve the problem that some existing ozone generators use a fan to draw in outside air into the ozone generator housing to dissipate the heat generated by the internal ozone generating unit. However, this method is inefficient in cooling the internal ozone generating unit, especially when the ozone generator is operating in a high-temperature, relatively enclosed space. This can lead to increased workload on the ozone generator, affecting its stability and service life.

[0030] like Figure 1-7 As shown, the ozone generator cooling structure provided in this embodiment includes an ozone generator housing 1, an output pipe 5, two exhaust ports 6 and a power cord 7. A cooling cover 2 is fixedly connected to the left side of the ozone generator housing 1. A cooling mechanism 3 is provided inside the cooling cover 2. An intake fan 13 is provided on the left side of the cooling cover 2. A filter plate 4 is provided on the left side of the intake fan 13.

[0031] The cooling mechanism 3 includes several temperature-conducting plates 301, a loop tube 302, and two liquid injection tubes 303. The side of the temperature-conducting plate 301 near the loop tube 302 is fixedly connected to the surface of the loop tube 302. The side of the liquid injection tube 303 near the loop tube 302 is fixedly connected to the loop tube 302. The loop tube 302 is fixedly connected inside the cooling cover 2. The temperature-conducting plates 301 and the loop tube 302 are both made of aluminum.

[0032] In this utility model's technical solution, by connecting the top injection pipe 303 and the bottom injection pipe 303 to an external coolant circulation refrigeration device, the external coolant circulates within the loop tube 302. The cooling mechanism 3 inside the cooling cover 2 consists of a temperature-conducting plate 301, a loop tube 302, and an injection pipe 303. Both the temperature-conducting plate 301 and the loop tube 302 are made of aluminum, utilizing aluminum's excellent thermal conductivity to transfer low temperatures. Then, the external controller controls the intake fan 13 to operate. The air drawn in by the intake fan 13 first passes through an alumina ceramic filter plate 4 to filter dust. The filter plate 4 is securely installed and easily disassembled via a slide rail 9 and a limit button 15 on the support plate 8. The cooling cover 2 uses phenolic foam composite board material to reduce cold loss. The intake fan 13 then... Air is drawn into the cooling shroud 2, where it comes into full contact with multiple low-temperature conductive fins 301, rapidly cooling before entering the ozone generator housing 1 to cool the ozone generating unit. This prevents the ozone generator from operating in high-temperature and relatively enclosed environments where the internal ozone generating unit cannot receive efficient heat dissipation. This solves the problem of existing ozone generators using fans to draw in external air into the ozone generator housing 1, creating an airflow to dissipate the heat generated by the internal ozone generating unit. This is especially problematic when the ozone generator is operating in a high-temperature, relatively enclosed space, where the internal ozone generating unit cannot receive efficient heat dissipation, easily leading to increased workload, affecting stability and service life.

[0033] Please refer to the following: Figure 4 and Figure 7 A fixing ring 11 is fixedly connected to the left side of the cooling cover 2, and an intake fan 13 is fixedly connected to the inner wall of the fixing ring 11. The right side of the filter plate 4 contacts the left side of the fixing ring 11. In this embodiment, the fixing ring 11 fixedly connected to the left side of the cooling cover 2 and the intake fan 13 installed on the inner wall ensure that the intake fan 13 operates stably, avoids displacement or noise due to vibration, ensures a stable air intake, and provides reliable airflow power for the cooling process. The right side of the filter plate 4 contacts the left side of the fixing ring 11 to prevent unfiltered air from entering the cooling cover 2.

[0034] For further information, please continue to refer to [link / reference]. Figure 3 , Figure 4 and Figure 6 The cooling cover 2 has support plates 8 fixedly connected to both the front and rear sides on the left side. A slide rail 9 is fixedly connected to the left side of the support plate 8, and the filter plate 4 is movably inserted into the slide rail 9. In this embodiment, the slide rail 9 fixedly connected to the left side of the cooling cover 2 via the support plate 8 allows the filter plate 4 to be movably inserted into it, realizing flexible disassembly and installation of the filter plate 4, which is convenient for daily maintenance and replacement of the filter plate 4.

[0035] Please continue to refer to this. Figure 3 , Figure 4 and Figure 6 A connecting plate 10 is fixedly connected to the top of the filter plate 4. The surface of the connecting plate 10 contacts the surface of the slide rail 9. Limit buttons 15 are provided on opposite sides of both slide rails 9. The side of the limit button 15 closest to the connecting plate 10 passes through the connecting plate 10 and is threadedly connected to the inside of the slide rail 9. In this embodiment, the contact between the connecting plate 10 at the top of the filter plate 4 and the surface of the slide rail 9, and the threaded connection via the limit buttons 15, ensures that the filter plate 4 is stably fixed during operation, preventing displacement due to airflow impact or vibration, and ensuring stable filtration performance.

[0036] Please refer to Figure 6 A handle 12 is fixedly connected to the top of the connecting plate 10, and the filter plate 4 is made of alumina ceramic. In this embodiment, the handle 12 on the top of the connecting plate 10, combined with the alumina ceramic filter plate 4, facilitates quick disassembly of the filter plate 4 by operators, and utilizes the high hardness and deformation resistance of alumina ceramic to ensure that the filter plate 4 is not easily damaged during long-term use, thus extending its service life.

[0037] Additionally, please refer to Figure 4 The cooling cover 2 is made of phenolic foam composite board. In this embodiment, the cooling cover 2 is made of phenolic foam composite board, which utilizes its excellent thermal insulation properties to reduce heat loss, effectively maintain the low temperature environment of the cooling area, improve cooling efficiency, and reduce energy consumption.

[0038] Please refer to Figure 4 and Figure 7 A protective mesh 14, made of woven steel wire, is fixedly connected to the inner wall of the fixing ring 11. In this embodiment, the steel wire protective mesh 14 on the inner wall of the fixing ring 11 ensures normal airflow while preventing foreign objects from entering the intake fan 13 when the filter plate 4 is disassembled and replaced.

[0039] It should be noted that ozone generators are a mature technology that has been published, and their basic mechanism will not be elaborated here.

[0040] The above description is only a preferred embodiment of the present utility model and does not limit the patent scope of the present utility model. All equivalent structural transformations made under the concept of the present utility model and using the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included in the patent protection scope of the present utility model.

Claims

1. A cooling structure for an ozone generator, characterized in that, The ozone generator cooling structure includes an ozone generator housing (1), an output pipe (5), two exhaust ports (6) and a power cord (7). A cooling cover (2) is fixedly connected to the left side of the ozone generator housing (1). A cooling mechanism (3) is provided inside the cooling cover (2). An air intake fan (13) is provided on the left side of the cooling cover (2). A filter plate (4) is provided on the left side of the air intake fan (13). The cooling mechanism (3) includes several temperature-conducting plates (301), a U-shaped tube (302), and two liquid injection tubes (303). The temperature-conducting plate (301) is fixedly connected to the surface of the U-shaped tube (302) on the side near the U-shaped tube (302). The liquid injection tube (303) is fixedly connected to the U-shaped tube (302) on the side near the U-shaped tube (302). The U-shaped tube (302) is fixedly connected inside the cooling cover (2). The temperature-conducting plate (301) and the U-shaped tube (302) are both made of aluminum.

2. The ozone generator cooling structure according to claim 1, characterized in that, The left side of the cooling cover (2) is fixedly connected to a fixing ring (11), the air intake fan (13) is fixedly connected to the inner wall of the fixing ring (11), and the right side of the filter plate (4) is in contact with the left side of the fixing ring (11).

3. The ozone generator cooling structure according to claim 1, characterized in that, The cooling cover (2) has a support plate (8) fixedly connected to the front and rear sides on the left side. The support plate (8) has a slide rail (9) fixedly connected to the left side. The filter plate (4) is movably inserted into the slide rail (9).

4. The ozone generator cooling structure according to claim 3, characterized in that, A connecting plate (10) is fixedly connected to the top of the filter plate (4). The surface of the connecting plate (10) is in contact with the surface of the slide rail (9). Limit buttons (15) are provided on opposite sides of the two slide rails (9). The side of the limit button (15) near the connecting plate (10) passes through the connecting plate (10) and is threadedly connected to the inside of the slide rail (9).

5. The ozone generator cooling structure according to claim 4, characterized in that, The top of the connecting plate (10) is fixedly connected to a handle (12), and the filter plate (4) is made of alumina ceramic.

6. The ozone generator cooling structure according to claim 1, characterized in that, The cooling cover (2) is made of phenolic foam composite board.

7. The ozone generator cooling structure according to claim 2, characterized in that, The inner wall of the fixing ring (11) is fixedly connected to a protective net (14), which is made of steel wire.