An ozone generator discharge tube anti-arc monitoring device

By setting up a monitoring structure and electrical control cabinet in the ozone generator, the operating status of the discharge tube can be monitored in real time, solving the problem that equipment failures cannot be detected in a timely manner in the existing technology, and realizing safe operation of the equipment and reduction of maintenance costs.

CN224430204UActive Publication Date: 2026-06-30JIANGSU KONER OZONE

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU KONER OZONE
Filing Date
2025-06-16
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The existing ozone generators are not equipped with monitoring devices, which makes it impossible to detect faults in a timely manner during operation, resulting in equipment damage, high maintenance costs, and long construction periods.

Method used

An anti-arcing monitoring device for the discharge tube of an ozone generator was designed, including a monitoring structure and an electrical control cabinet. The device monitors the operation of the discharge tube in real time through a monitoring instrument probe, promptly feeds back signals, and stops the equipment to prevent damage caused by arcing.

Benefits of technology

This enabled timely prevention of equipment damage, reduced maintenance costs and construction time, and ensured the normal operation of the equipment.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This utility model relates to the field of ozone generator technology, specifically to an ozone generator discharge tube anti-arc monitoring device, including an ozone generator cylinder and an electrical control cabinet. The ozone generator cylinder includes a cylinder shell, a left side door fixedly connected to one side of the cylinder shell by bolts, an electrode protective cover fixedly connected to the top of the cylinder shell, an insulating column fixedly connected inside the electrode protective cover, and a high-voltage copper rod inserted into the surface of the insulating column. Three sets of glass tube electrode tubes are arranged inside the cylinder shell, and a monitoring structure is arranged inside the left side door. This utility model has a monitoring structure to prevent accidents caused by arcing inside the ozone generator cylinder, ensuring the ozone equipment remains intact and undamaged. The ozone generator cylinder has an orderly and clear structural layout, is easy to install, and plays an essential role in the long-term operation of the ozone generator.
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Description

Technical Field

[0001] This utility model belongs to the field of ozone generator technology, specifically relating to an ozone generator discharge tube operation anti-arc monitoring device. Background Technology

[0002] In the entire ozone generator operating system, if the quality of the externally introduced oxygen is substandard, especially if the oxygen source dew point is high (high water content), or if the connection between the two high-voltage electrodes is loose and the contact is not fully aligned, the corona discharge between the high-voltage electrode and the low-voltage electrode will generate open sparks, burning through the glass tube and the stainless steel tube of the external electrode. Such situations will ultimately damage the ozone generator and prevent it from operating normally.

[0003] Existing ozone generators lack internal monitoring devices, making it impossible to detect internal malfunctions in a timely manner. This can lead to damage and malfunction of the ozone generator, which is costly to maintain, requires the replacement of numerous parts, and involves a relatively long maintenance period. Therefore, we propose an anti-arc monitoring device for the operation of the discharge tube in ozone generators. Utility Model Content

[0004] In order to overcome the above-mentioned technical problems, the purpose of this utility model is to provide an anti-arc monitoring device for the operation of the discharge tube of an ozone generator, so as to solve the problem mentioned in the background art that the existing ozone generators do not have a monitoring device installed inside, and when internal faults occur during operation, they cannot be observed in time, which eventually leads to the ozone generator being damaged and unable to operate normally. The damage requires high maintenance costs, many replacement parts, and relatively long maintenance period, which is labor-intensive, time-consuming and costly.

[0005] To achieve the above objectives, this utility model provides the following technical solution: an ozone generator discharge tube anti-arc monitoring device, comprising an ozone generator cylinder and an electrical control cabinet. The ozone generator cylinder includes a cylinder shell, a left side door fixedly connected to one side of the cylinder shell by bolts, and a right side door fixedly connected to the other side of the cylinder shell by bolts. An electrode protective cover is fixedly connected to the top of the cylinder shell, an insulating column is fixedly connected inside the electrode protective cover, a high-voltage copper rod is inserted into the surface of the insulating column, and a conductive connecting strip is fixedly connected to the surface of the high-voltage copper rod. Four sets of perforated plates are fixedly connected inside the cylinder shell, and external electrode tubes are fixedly connected to the surfaces of the four sets of perforated plates. Three sets of glass tube electrode tubes are arranged inside the cylinder shell. The electrode tube includes a discharge tube dielectric glass tube, and an inner electrode tube is fixedly connected inside the discharge tube dielectric glass tube. A supporting insulating tape is wrapped around the outside of the discharge tube dielectric glass tube. A monitoring structure is installed inside the left door. The monitoring structure includes an outer shell cylinder. An outer shell cover plate is fixedly connected to one side of the outer shell cylinder. A wire hole is opened on the surface of the outer shell cover plate. A wire locking device is rotatably connected inside the wire hole. A light-transmitting cover is rotatably connected to the other side of the outer shell cylinder. A fixing ring is fixedly connected to the inner wall of the outer shell cylinder. A monitoring instrument housing is sleeved on the inner side of the fixing ring. A monitoring instrument probe is fixedly connected to the surface of the monitoring instrument housing. The ozone generator cylinder and the monitoring structure are both electrically connected to the electrical control cabinet.

[0006] Preferably, one end of the insulating column and the high-voltage copper rod is disposed inside the electrode protective cover, and the other end of the insulating column and the high-voltage copper rod is disposed inside the outer shell of the cylinder. One end of the high-voltage copper rod is higher than the insulating column, and the other end of the high-voltage copper rod is fixedly connected to the conductive connecting strip. The insulating column is made of PTFE insulating material.

[0007] Preferably, three sets of glass tube electrode tubes are equidistantly arranged inside the outer shell of the cylinder, and four sets of perforated plates are respectively arranged at the top and bottom of the three sets of glass tube electrode tubes.

[0008] Preferably, one end of the inner electrode tube of the discharge tube extends to the outside of the dielectric glass tube of the discharge tube, and the three sets of inner electrode tubes of the discharge tube are interconnected by the conductive connecting strip. The upper set of inner electrode tubes of the discharge tube is interconnected with the high voltage copper rod by the conductive connecting strip.

[0009] Preferably, a gap is provided between the external electrode tube and the discharge tube dielectric glass tube, and the supporting insulating tape is disposed in the gap, wherein the supporting insulating tape is made of insulating material.

[0010] Preferably, the glass tube electrode tube is located in the middle of the left side door, and the surface of the threaded lock is provided with a thread, and the threaded lock is rotatably connected to the threaded hole through the thread.

[0011] Preferably, the light-transmitting cover is made of transparent plexiglass, and the outer casing cylinder has a threaded second on the side away from the outer casing cover plate. The light-transmitting cover is rotatably connected to the surface of the outer casing cylinder through the threaded second, and the monitoring instrument probe is located on the side of the monitoring instrument housing close to the light-transmitting cover.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] 1. This ozone generator discharge tube anti-arcing monitoring device is equipped with a monitoring structure. The monitoring instrument probe at the front of the monitoring instrument housing is located inside a light-transmitting cover on the side of the housing near the inside of the housing. The monitoring instrument probe can monitor the real-time status of the glass tube electrode tube inside the housing directly opposite the housing when it generates ozone through high-voltage corona discharge. At the same time, it monitors and records the conductive operation of the high-voltage copper rod, conductive connecting strip, and the connection point with the electrode tube inside the discharge tube, as well as the air gap position between the electrode tube inside and outside the discharge tube when it generates ozone through high and low voltage corona discharge. As soon as an arcing phenomenon occurs, the monitoring instrument probe immediately transmits the signal back to the program controller of the electrical control cabinet. The electrical control cabinet then immediately stops the operation of the ozone generator housing and displays an alarm and illuminates the alarm warning light on the electrical control cabinet. This can prevent accidents caused by arcing inside the ozone generator housing and ensure that the ozone equipment remains intact and undamaged.

[0014] 2. This ozone generator discharge tube anti-sparking monitoring device includes an ozone generator cylinder. A high-voltage copper rod is connected to the high-voltage end of a high-voltage transformer via a high-voltage cable and fixed thereon. One end of the high-voltage copper rod is higher than the insulating post, making connection to the high-voltage cable easier. Multiple sets of glass tube electrodes and four sets of external electrode tubes mounted on a perforated plate can simultaneously generate ozone, increasing generator efficiency. The external electrode tubes are welded to the inner wall of the cylinder shell via the perforated plate. The cylinder shell is connected to a zero-potential grounding electrode and connected to the low-voltage end of the high-voltage transformer via a cable. The external electrode tubes serve as a low-voltage zero-potential grounding electrode, forming the low-voltage electrode required for high-voltage corona discharge of the ozone generator discharge tube. The three sets of discharge tubes... The electrode tube and the high-voltage copper rod are connected in series via conductive connecting strips, making the inner electrode tube of the discharge tube equivalent to the high-voltage copper rod as a high-voltage electrode, forming a high-voltage electrode required for high-voltage corona discharge in the ozone generator discharge tube. When the high-voltage transformer of the ozone generator is energized, the inner electrode tube of the glass tube electrode tube obtains high voltage through the high-voltage copper rod. A gap channel is separated by a supporting insulating tape, forming a gap channel required for high-voltage corona discharge between the inner electrode tube and the outer electrode tube low-voltage electrode. The glass tube of the discharge tube serves as the medium required for the discharge between the high-voltage and low-voltage electrodes. Oxygen flowing in the gap channel is converted into ozone through the corona discharge between the high-voltage and low-voltage electrodes. The structure and process are arranged in an orderly manner, are easy to understand, and are easy to install, playing an essential role in the long-term operation of the ozone generator. Attached Figure Description

[0015] Figure 1 This is a three-dimensional structural schematic diagram of the present invention;

[0016] Figure 2 This is a front sectional view of the structure of this utility model;

[0017] Figure 3 This is a front sectional view of the structure of the ozone generator cylinder and the glass tube electrode tube of this utility model;

[0018] Figure 4 This is a cross-sectional view of the structure at point A of this utility model;

[0019] Figure 5 This is a schematic diagram of the electrical control cabinet of this utility model.

[0020] In the diagram: 1. Ozone generator cylinder; 11. Cylinder shell; 12. Left side door; 13. Right side door; 14. Electrode protective cover; 15. Insulating column; 16. High-voltage copper rod; 17. Conductive connecting strip; 18. Corrugated plate; 19. External electrode tube; 2. Glass tube electrode tube; 21. Discharge tube dielectric glass tube; 22. Discharge tube inner electrode tube; 23. Supporting isolation tape; 3. Monitoring structure; 31. Outer shell cylinder; 32. Outer shell cover plate; 33. Wiring hole; 34. Wiring lock; 35. Light-transmitting cover; 36. Fixing ring; 37. Monitoring instrument shell; 38. Monitoring instrument probe; 4. Electrical control cabinet. Detailed Implementation

[0021] 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.

[0022] Please see Figure 1-5 One embodiment provided by this utility model:

[0023] An ozone generator discharge tube anti-arc monitoring device includes an ozone generator cylinder 1 and an electrical control cabinet 4. The ozone generator cylinder 1 includes a cylinder shell 11. A left door 12 is bolted to one side of the cylinder shell 11, and a right door 13 is bolted to the other side of the cylinder shell 11. An electrode protective cover 14 is fixedly connected to the top of the cylinder shell 11. An insulating column 15 is fixedly connected inside the electrode protective cover 14. A high-voltage copper rod 16 is inserted into the surface of the insulating column 15. A conductive connecting strip 17 is fixedly connected to the surface of the high-voltage copper rod 16. Four sets of perforated plates 18 are fixedly connected inside the cylinder shell 11. External electrode tubes 19 are fixedly connected to the surface of each of the four sets of perforated plates 18. Three sets of glass tube electrodes are installed inside the cylinder shell 11. Electrode 2, the glass tube electrode tube 2 includes a discharge tube dielectric glass tube 21, an inner discharge tube electrode tube 22 is fixedly connected inside the discharge tube dielectric glass tube 21, and a supporting insulating tape 23 is wrapped around the outside of the discharge tube dielectric glass tube 21. A monitoring structure 3 is installed inside the left door 12. The monitoring structure 3 includes an outer casing cylinder 31, an outer casing cover plate 32 is fixedly connected to one side of the outer casing cylinder 31, a wire-passing hole 33 is opened on the surface of the outer casing cover plate 32, a wire-passing lock 34 is rotatably connected inside the wire-passing hole 33, a light-transmitting cover 35 is rotatably connected to the other side of the outer casing cylinder 31, a fixing ring 36 is fixedly connected to the inner wall of the outer casing cylinder 31, a monitoring instrument housing 37 is sleeved on the inner side of the fixing ring 36, and the surface of the monitoring instrument housing 37 is fixedly connected to... The ozone generator cylinder 1 and monitoring structure 3 are electrically connected to the electrical control cabinet 4, and monitoring instrument probe 38 is installed at the front of the monitoring instrument housing 37. The monitoring instrument probe 38 is installed inside the light-transmitting cover 35 on the side of the housing 31 near the inside of the housing 11. The monitoring instrument probe 38 can monitor the real-time status of the glass tube electrode tube 2 inside the housing 11 opposite the main body when it generates ozone through high-voltage corona discharge. At the same time, it monitors and records the conductive operation of the high-voltage copper rod 16, the conductive connecting strip 17 and the connection point with the electrode tube 22 inside the discharge tube, as well as the position of the air gap between the electrode tube 22 inside the discharge tube and the outer electrode tube 19 when high and low voltage corona discharge is applied to generate ozone. As soon as an arcing phenomenon occurs, the monitoring instrument probe 38 will immediately detect it. The signal feedback is transmitted to the electrical control cabinet 4, which immediately stops the ozone generator cylinder 1 from operation and displays an alarm and illuminates the alarm warning light on the electrical control cabinet 4. This prevents accidents caused by arcing inside the ozone generator cylinder 1, ensuring the ozone equipment remains intact and undamaged. The ozone generator cylinder 1 is constructed, and the high-voltage copper rod 16 is connected to the high-voltage end of the high-voltage transformer via a high-voltage cable. One end of the high-voltage copper rod 16 is higher than the insulating post 15, making connection to the high-voltage cable easier. Multiple sets of glass tube electrode tubes 2 and four sets of external electrode tubes 19 mounted on the perforated plate 18 can simultaneously generate ozone, increasing the generator's operating efficiency.The external electrode tube 19 is welded to the inner wall of the outer shell 11 via a perforated plate 18. The outer shell 11 is connected to the zero-potential grounding electrode and connected to the low-voltage end of the high-voltage transformer via a cable for installation and fixation. Thus, the external electrode tube 19 serves as the low-voltage zero-potential grounding electrode, forming a low-voltage electrode required for high-voltage corona discharge of the ozone generator discharge tube. The three sets of inner electrode tubes 22 and high-voltage copper rods 16 are connected in series via conductive connecting strips 17, making the inner electrode tubes 22 equivalent to the high-voltage copper rods 16 as high-voltage electrodes, forming a high-voltage electrode required for high-voltage corona discharge of the ozone generator discharge tube. When the high-voltage transformer of the oxygen generator is energized, the inner electrode tube 22 of the glass tube electrode tube 2 receives high voltage through the high-voltage copper rod 16. A gap channel is created by the supporting insulating tape 23, forming the air gap channel required for high-voltage corona discharge between the inner electrode tube 22 and the outer electrode tube 19 (low-voltage electrode). The glass tube 21, the dielectric medium, serves as the medium for the discharge between the high-voltage and low-voltage electrodes. Oxygen flowing through the air gap channel is converted into ozone through the corona discharge between the high-voltage and low-voltage electrodes. The structure and flow are orderly and easy to understand, facilitating installation and playing an essential role in the long-term operation of the ozone generator.

[0024] Furthermore, one end of the insulating post 15 and the high-voltage copper rod 16 is located inside the electrode protective cover 14, and the other end of the insulating post 15 and the high-voltage copper rod 16 is located inside the outer shell 11 of the cylinder. One end of the high-voltage copper rod 16 is higher than the insulating post 15, and the other end of the high-voltage copper rod 16 is fixedly connected to the conductive connecting strip 17. The insulating post 15 is made of PTFE insulation material. The high-voltage copper rod 16 is led to the high-voltage end of the high-voltage transformer by a high-voltage cable and fixed. The higher high-voltage copper rod 16 is more convenient to connect to the high-voltage cable.

[0025] Furthermore, three sets of glass tube electrode tubes 2 are equidistantly arranged inside the outer shell 11 of the cylinder, and four sets of perforated plates 18 are respectively arranged at the top and bottom of the three sets of glass tube electrode tubes 2. Multiple sets of glass tube electrode tubes 2 can work together with the outer electrode tube 19 to generate ozone, thereby increasing the operating efficiency of the generator.

[0026] Furthermore, one end of the inner electrode tube 22 of the discharge tube extends to the outside of the dielectric glass tube 21 of the discharge tube. The three sets of inner electrode tubes 22 of the discharge tube are interconnected by conductive connecting strips 17. The upper set of inner electrode tubes 22 of the discharge tube is interconnected with the high voltage electrode copper rod 16 by conductive connecting strips 17. The three sets of inner electrode tubes 22 of the discharge tube and the high voltage electrode copper rod 16 are connected in series by conductive connecting strips 17, so that the inner electrode tube 22 of the discharge tube is equivalent to the high voltage electrode copper rod 16 as a high voltage electrode, forming a high voltage electrode required for high voltage corona discharge of the ozone generator discharge tube. The outer shell 11 of the cylinder is connected to the zero potential grounding electrode and introduced to the low voltage end of the high voltage transformer by a cable for installation and fixation. The outer electrode tube 19 is welded to the inner wall of the outer shell 11 of the cylinder by a perforated plate 18, so that the outer electrode tube 19 serves as a low voltage zero potential grounding electrode, forming a low voltage electrode required for high voltage corona discharge of the ozone generator discharge tube.

[0027] Furthermore, a gap is provided between the external electrode tube 19 and the discharge tube dielectric glass tube 21, and a supporting insulating tape 23 is placed in the gap. The supporting insulating tape 23 is made of insulating material. When the high voltage transformer of the ozone generator is energized, the inner electrode tube 22 of the discharge tube of the glass tube electrode tube 2 obtains high voltage through the high voltage electrode copper rod 16. The supporting insulating tape 23 separates an air gap channel, forming an air gap channel required for high voltage corona discharge between the outer electrode tube 19 and the low voltage electrode. The discharge tube dielectric glass tube 21 serves as the medium required for the discharge between the high voltage electrode and the low voltage electrode. The oxygen flowing in the air gap channel is converted into ozone through the corona discharge between the high voltage electrode and the low voltage electrode.

[0028] Furthermore, the glass tube electrode tube 2 is located in the middle of the left door 12. The surface of the wire lock 34 is provided with a thread, and the wire lock 34 is rotatably connected to the wire hole 33 through the thread. The monitoring instrument housing 37 is connected to the electrical control cabinet 4 through the connecting wire. The connecting wire is bundled and fixed in the wire hole 33 by the wire lock 34 to prevent the connecting wire from becoming tangled.

[0029] Furthermore, the light-transmitting cover 35 is made of transparent organic glass. The outer shell cylinder 31 has a threaded second on the side away from the outer shell cover plate 32. The light-transmitting cover 35 is rotatably connected to the surface of the outer shell cylinder 31 through the threaded second. The monitoring instrument probe 38 is set on the side of the monitoring instrument housing 37 close to the light-transmitting cover 35. The fixing ring 36 is elastic and can securely hold the monitoring instrument housing 37 inside the outer shell cylinder 31. The monitoring instrument probe 38 can monitor the real-time status of the glass tube electrode tube 2 inside the opposite cylinder housing 11 when it generates ozone through high-voltage corona discharge. At the same time, it can monitor and record the conductive operation status of the high-voltage copper rod 16, the conductive connecting strip 17 and the connection point with the inner electrode tube 22 of the discharge tube, as well as the air gap position between the inner electrode tube 22 and the outer electrode tube 19 when high and low voltage corona discharge is applied to generate ozone.

[0030] Working principle: Both the ozone generator cylinder 1 and the monitoring structure 3 are electrically connected to the electrical control cabinet 4. The electrical control cabinet 4 provides unified control of the ozone generator cylinder 1 and the monitoring structure 3. This is existing technology and will not be described in detail hereafter. The monitoring instrument probe 38 at the front of the monitoring instrument housing 37 is located inside the light-collecting cover 35 on the side of the housing 31 near the inside of the cylinder housing 11. The monitoring instrument probe 38 can monitor the real-time status of the glass tube electrode tube 2 inside the opposite cylinder housing 11 when it generates ozone through high-voltage corona discharge. At the same time, it monitors and records the high-voltage copper rod 16 and the conductive connecting strip 17. The monitoring instrument probe 38 immediately transmits a signal to the control cabinet 4 if any sparking occurs. The control cabinet 4 then immediately stops the ozone generator cylinder 1 and displays an alarm and illuminates the alarm warning light. This prevents accidents caused by sparking inside the ozone generator cylinder 1, ensuring the ozone equipment remains intact and undamaged. The external electrode tube 19 passes through... The tube sheet 18 is welded to the inner wall of the outer shell 11. The outer shell 11 is connected to the zero-potential grounding electrode and connected to the low-voltage end of the high-voltage transformer via a cable. Thus, the outer electrode tube 19 serves as the low-voltage zero-potential grounding electrode, forming a low-voltage electrode required for high-voltage corona discharge of the ozone generator discharge tube. The three sets of inner electrode tubes 22 and high-voltage copper rods 16 are connected in series via conductive connecting strips 17, making the inner electrode tubes 22 equivalent to the high-voltage copper rods 16, forming a high-voltage electrode required for high-voltage corona discharge of the ozone generator discharge tube. When the high-voltage transformer is energized, the inner electrode tube 22 of the glass tube electrode tube 2 obtains high voltage through the high-voltage copper rod 16. A gap channel is separated by the supporting insulating tape 23, forming the air gap channel required for high-voltage corona discharge between the outer electrode tube 19 and the low-voltage electrode. The glass tube 21 of the discharge tube serves as the medium required for the discharge between the high-voltage electrode and the low-voltage electrode. Oxygen flowing in the air gap channel is converted into ozone through the corona discharge between the high-voltage electrode and the low-voltage electrode. The structure and process are arranged in an orderly manner, which is easy to understand and install. It plays an essential role in the long-term operation of the ozone generator.

[0031] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A spark prevention monitoring device for the discharge tube of an ozone generator, comprising an ozone generator cylinder (1) and an electrical control cabinet (4), characterized in that: The ozone generator cylinder (1) includes a cylinder shell (11). A left door (12) is bolted to one side of the cylinder shell (11), and a right door (13) is bolted to the other side of the cylinder shell (11). An electrode protective cover (14) is fixedly connected to the top of the cylinder shell (11). An insulating column (15) is fixedly connected inside the electrode protective cover (14). A high-voltage copper rod (16) is inserted into the surface of the insulating column (15). A conductive connecting strip (17) is fixedly connected to the surface of the high-voltage copper rod (16). Four sets of perforated plates (18) are fixedly connected inside the cylinder shell (11). An external electrode tube (19) is fixedly connected to the surface of each of the four sets of perforated plates (18). Three sets of glass tube electrode tubes (2) are arranged inside the cylinder shell (11). Each glass tube electrode tube (2) includes a discharge tube dielectric glass tube (21). The discharge tube dielectric glass tube (21) has a solid internal structure. A discharge tube inner electrode tube (22) is fixedly connected. The outer side of the discharge tube dielectric glass tube (21) is wrapped with a supporting insulating tape (23). A monitoring structure (3) is set inside the left door (12). The monitoring structure (3) includes an outer shell cylinder (31). An outer shell cover plate (32) is fixedly connected to one side of the outer shell cylinder (31). A wire hole (33) is opened on the surface of the outer shell cover plate (32). The inside of the wire hole (33) is rotatably connected. There is a wire lock (34), and a light-transmitting cover (35) is rotatably connected to the other side of the outer shell cylinder (31). A fixing ring (36) is fixedly connected to the inner wall of the outer shell cylinder (31). A monitoring instrument shell (37) is sleeved on the inner side of the fixing ring (36). A monitoring instrument probe (38) is fixedly connected to the surface of the monitoring instrument shell (37). The ozone generator cylinder (1) and the monitoring structure (3) are both electrically connected to the electrical control cabinet (4).

2. The ozone generator discharge tube anti-arc monitoring device according to claim 1, characterized in that: One end of the insulating column (15) and the high-voltage copper rod (16) is disposed inside the electrode protective cover (14), and the other end of the insulating column (15) and the high-voltage copper rod (16) is disposed inside the outer shell of the cylindrical body (11). One end of the high-voltage copper rod (16) is higher than the insulating column (15), and the other end of the high-voltage copper rod (16) is fixedly connected to the conductive connecting strip (17). The insulating column (15) is made of PTFE insulating material.

3. The ozone generator discharge tube anti-arc monitoring device according to claim 1, characterized in that: The glass tube electrode tubes (2) are arranged in three sets at equal intervals inside the outer shell (11) of the cylinder, and the four sets of flower plates (18) are respectively arranged at the top and bottom of the three sets of glass tube electrode tubes (2).

4. The ozone generator discharge tube anti-arc monitoring device according to claim 3, characterized in that: One end of the inner electrode tube (22) of the discharge tube extends to the outside of the discharge tube dielectric glass tube (21). The three sets of inner electrode tubes (22) of the discharge tube are connected to each other through the conductive connecting strip (17). The upper set of inner electrode tubes (22) of the discharge tube is connected to the high voltage copper rod (16) through the conductive connecting strip (17).

5. The ozone generator discharge tube anti-arc monitoring device according to claim 1, characterized in that: A gap is provided between the external electrode tube (19) and the discharge tube dielectric glass tube (21), and the supporting isolation tape (23) is placed in the gap. The supporting isolation tape (23) is made of insulating material.

6. The ozone generator discharge tube anti-arc monitoring device according to claim 1, characterized in that: The glass tube electrode tube (2) is located in the middle of the left side door (12), and the surface of the threaded lock (34) is provided with a thread, and the threaded lock (34) is rotatably connected to the threaded hole (33) through the thread.

7. The ozone generator discharge tube anti-arc monitoring device according to claim 1, characterized in that: The light-transmitting cover (35) is made of transparent organic glass. The outer shell cylinder (31) is provided with a threaded second on the side away from the outer shell cover plate (32). The light-transmitting cover (35) is rotatably connected to the surface of the outer shell cylinder (31) through the threaded second. The monitoring instrument probe (38) is located on the side of the monitoring instrument housing (37) close to the light-transmitting cover (35).