An ozone generator

Abstract

The application discloses the technical field of ozone preparation, and particularly relates to an ozone generator, which comprises an ozone preparation water tank, a cut-off assembly, a reinforced sealing assembly, a control assembly and an electricity connection positioning assembly, a plurality of dismounting and connecting boxes are arranged at the lower end of the ozone preparation water tank, the ozone preparation module can be quickly assembled and electrified with the dismounting and connecting boxes through the electricity connection positioning assembly, the two reaction cover boxes of the ozone preparation module can be connected, sealed and stabilized with the four multifunctional combined connectors under the action of the reinforced sealing assembly, the interface water leakage does not occur, the built-in electricity connection slot further improves the operation safety, and the multifunctional combined connector can be blocked and connected when the ozone preparation module is connected with the multifunctional combined connector or separated from the multifunctional combined connector under the cooperation of the control assembly and the cut-off assembly, ozone preparation can be continuously carried out when a single or multiple ozone preparation modules are damaged, or the ozone preparation module can be quickly dismounted, repaired and maintained.

Description

Technical Field

[0001] This invention relates to the field of ozone preparation technology, specifically to an ozone generator. Background Technology

[0002] Ozone, also known as superoxide, is an allotrope of oxygen. At room temperature, it is a pale blue gas with a distinctive odor. Ozone can be used to purify air, bleach drinking water, sterilize, treat industrial waste, and as a bleaching agent. Ozone is easily decomposed and cannot be stored; it must be produced and used on-site.

[0003] The invention disclosed in CN107177861 A is an ozone generator nozzle, which includes a water inlet cover, a cavity with several independently separated electrolysis chambers, and a water outlet cover connected in sequence. The cavity has a positive electrolysis chamber in the middle and negative electrolysis chambers on both sides. The end of the cavity facing the water inlet cover has a positive water inlet hole that connects the positive electrolysis chamber to the water inlet pipe of the water inlet cover. It has the advantages of high working efficiency, reasonable structural layout, wide application and good sealing performance. It can further optimize the equipment for preparing ozone water by electrolysis, improve the ozone production efficiency and expand the scope of ozone application.

[0004] The above solution improves working efficiency by adding negative electrode electrolysis chambers on both sides. When preparing ozone through water electrolysis, the positive and negative electrode preparation modules play the main role. Since the preparation modules are mainly connected to the outside of the electrolysis tank through hoses, the sealing effect of the connection between the hoses and the preparation modules will directly affect the safety and effectiveness of the equipment. Because the preparation modules participate in the continuous electrolysis operation of the positive and negative electrodes, if one or more preparation modules are damaged after a long period of use, it is necessary to shut down the machine and carry out a long period of disassembly, inspection and maintenance, which is time-consuming and labor-intensive. Summary of the Invention

[0005] The purpose of this invention is to provide an ozone generator to solve the problems mentioned in the background art.

[0006] To achieve the above objectives, the present invention provides the following technical solution: an ozone generator, comprising:

[0007] An ozone-generating water tank is provided with several disassembly and assembly connection boxes installed at the lower end of the ozone-generating water tank. Two multi-functional combination connectors are symmetrically provided at both the upper and lower ends of each disassembly and assembly connection box. A reaction component is inserted into one side of each multi-functional combination connector. The reaction component includes an ozone-generating module. A positive electrode plate and a negative electrode plate are fixedly provided on both sides of the ozone-generating module. A reaction cover box is sealed and fixedly provided on one side of each of the positive and negative electrode plates. A circulation tube is symmetrically provided at both the upper and lower ends of each reaction cover box. The two circulation tubes of the reaction cover box are respectively inserted into the two multi-functional combination connectors on one side of the disassembly and assembly connection box.

[0008] The multi-functional combination joint is provided with a flow-blocking component and a reinforced sealing component. The flow-blocking component includes a sealing ball core, and the reinforced sealing component includes a deformable sealing ring and a push ring. The upper and lower ends of the disassembly and assembly connection box are respectively provided with control components. The control components include control boards, which are located between the two multi-functional combination joints. The control boards are respectively connected to the sealing ball core and the push ring of the two multi-functional combination joints.

[0009] A power-connecting positioning assembly includes a positioning insert plate, the two sides of which are respectively connected to a positive electrode plate and a negative electrode plate, and the positioning insert plate is inserted into one side of the disassembly and assembly connection box.

[0010] Preferably, the disassembly and assembly connection box has a U-shaped structure. A return flow support pipe is fixedly installed on one side of each of the two multi-functional combination connectors at the upper end of the disassembly and assembly connection box. The upper ends of the two return flow support pipes are respectively connected and fixedly inserted into the lower end of the ozone preparation water tank. A negative electrode water inlet pipe and a T-connector are respectively installed on one side of each of the two multi-functional combination connectors at the lower end of the disassembly and assembly connection box. The negative electrode water inlet pipe is connected to the reaction cover box of the negative electrode plate. A positive electrode water inlet pipe and a return water pipe are respectively connected to both sides of the T-connector. The upper ends of the positive electrode water inlet pipe, the return water pipe, and the negative electrode water inlet pipe are respectively connected and fixedly inserted into the lower end of the ozone preparation water tank. The upper end of the return flow support pipe connected to the reaction cover box on the positive electrode plate is inserted into the ozone preparation water tank and, together with the upper end of the return water pipe, is provided with an ozone collection bottle.

[0011] Preferably, a U-shaped slot is provided on one side of the disassembly and assembly connection box, the ozone preparation module is inserted into the U-shaped slot, and the four circulation tubes are all L-shaped structures. When the ozone preparation module is fully inserted into the U-shaped slot, the four circulation tubes are respectively horizontally inserted into one side of the four multi-functional combination connectors.

[0012] Preferably, the multifunctional combination connector is symmetrically fitted with two sealing rings on one side of the circulation cannula. The two sealing rings are fitted onto the circulation cannula. The multifunctional combination connector is provided with a compression groove on one side of the circulation cannula. A deformable sealing ring is inserted into the compression groove and fitted onto the circulation cannula. A compression ring is provided on the side of the compression groove near the deformable sealing ring. One side of the compression ring abuts against the deformable sealing ring, and the side of the compression ring that contacts the deformable sealing ring is a conical surface.

[0013] Preferably, the multi-functional combination joint has control grooves at both its upper and lower ends, and horizontal sliding grooves at the lower end of each control groove. The two control plates are slidably inserted into the two horizontal sliding grooves. A sleeve groove is provided on the side of the multi-functional combination joint near the extrusion groove. A push ring is movably sleeved on the multi-functional combination joint at the position of the sleeve groove. A strip groove is horizontally provided on the side of the sleeve groove of the multi-functional combination joint in the control groove. A synchronous pull rod is horizontally provided on the side of the push ring near the strip groove. The two synchronous pull rods pass through the strip groove and are inserted into the control groove and connected to one side of the control plate.

[0014] Preferably, the multifunctional combination connector has a sealing ball groove between the circulation tube and the return support tube. A sealing ball core is rotatably inserted into each sealing ball groove. A docking valve groove is penetrated through each sealing ball core. The diameter of the docking valve groove is the same as the inner diameter of the return support tube. A synchronous shaft is horizontally provided at the center of the side of the sealing ball core near the control movable groove. One side of the synchronous shaft is movably inserted into the control movable groove. A crescent gear is provided between the two synchronous shafts inserted into the control movable groove. A number of actuating teeth are provided on the upper side of the control plate, and the teeth of the crescent gear are meshed with the actuating teeth.

[0015] Preferably, the compression ring is symmetrically provided with a plurality of push rods on one side near the sleeve groove, and one side of each push rod is movably inserted into the sleeve groove. When the push ring compresses and pushes the push rods, the docking valve groove that seals the ball core is connected to the return support pipe and the circulation insertion pipe.

[0016] Preferably, a spring box is vertically provided on the upper side of the control board away from the actuating teeth. A constraint rod is vertically inserted into the spring box through a pressure block. A pressure spring is sleeved on the side of the pressure block inside the spring box for each constraint rod. Constraint slots are provided on both sides of the horizontal slide groove, and the constraint rod is selectively inserted into one of the constraint slots.

[0017] Preferably, both the positive and negative plates are provided with electrical terminals on the side near the disassembly and assembly box. The two sides of the positioning plate are fixedly connected to the two electrical terminals by electrical screws. A positioning slot is horizontally opened on one side of the disassembly and assembly box. The positioning plate is horizontally inserted into the positioning slot. Two electrical rods are electrically connected to the two electrical terminals on both sides of the positioning plate inserted into the positioning slot. Two electrical slots are symmetrically provided on both sides of the positioning slot, and the two electrical rods are respectively inserted into the two electrical slots.

[0018] Preferably, two positioning spring pieces are embedded in the upper and lower ends of the positioning slot, and positioning slots are horizontally opened at both ends of the positioning plate, with one side of each of the two positioning spring pieces elastically inserted into the two positioning slots.

[0019] Compared with the prior art, the beneficial effects of the present invention are:

[0020] Several disassembly and assembly connection boxes are installed at the lower end of the ozone preparation water tank. When the ozone preparation module is connected to the ozone preparation water tank, the ozone preparation module can be quickly assembled and powered on by the power connection positioning component. With the action of the enhanced sealing component, the two reaction chambers of the ozone preparation module and the four multi-functional combination connectors can be connected and sealed stably, and there will be no interface water leakage. The built-in power connection slot further improves the safety of operation. At the same time, with the cooperation of the control component and the interception component, when the ozone preparation module is connected and disconnected from the multi-functional combination connector, the multi-functional combination connector can be sealed and connected. In the event of damage to one or more ozone preparation modules, normal ozone preparation can continue, or it can be quickly disassembled for inspection and maintenance. Attached Figure Description

[0021] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0022] Figure 2 For the present invention Figure 1 Schematic diagram of part A;

[0023] Figure 3 This is a schematic diagram of the connection structure of the ozone collection bottle of the present invention;

[0024] Figure 4 This is a schematic diagram of the connection structure between the disassembly and assembly connection box and the ozone generation module of the present invention;

[0025] Figure 5 For the present invention Figure 4 Schematic diagram of part B;

[0026] Figure 6 This is a cross-sectional schematic diagram showing the connection between the circulatory cannula and the multifunctional combination connector of the present invention;

[0027] Figure 7 For the present invention Figure 6 Schematic diagram of part C;

[0028] Figure 8 For the present invention Figure 7 Schematic diagram of part D;

[0029] Figure 9 This is a side sectional view of the control board connection of the present invention;

[0030] Figure 10 For the present invention Figure 9 Schematic diagram of part E;

[0031] Figure 11 This is a side sectional view of the positioning insert plate connection of the present invention;

[0032] Figure 12 For the present invention Figure 11 Schematic diagram of part F;

[0033] Figure 13 This is a schematic diagram of the disassembly and assembly connection box structure of the present invention;

[0034] Figure 14 For the present invention Figure 13 Schematic diagram of part G;

[0035] Figure 15 This is a schematic diagram of the ozone preparation module and positioning plate combination of the present invention.

[0036] In the diagram: 1. Ozone preparation water tank; 2. Disassembly and assembly connection box; 3. Multifunctional combination connector; 4. Return support pipe; 5. Ozone preparation module; 6. Positive electrode plate; 7. Negative electrode plate; 8. Reaction hood box; 9. Circulation tube; 10. Positive electrode water inlet pipe; 11. Return water pipe; 12. Ozone collection bottle; 13. Negative electrode water inlet pipe; 14. Sealing ring; 15. Extrusion groove; 16. Deformable sealing ring; 17. Extrusion ring; 18. Sleeve groove; 19. Thrust ring; 20. Control movement groove; 11. Strip groove. 21. Horizontal slide groove; 22. Control panel; 23. Synchronous tie rod; 24. Sealing ball groove; 25. Sealing ball core; 26. Connecting valve groove; 27. Synchronous shaft; 28. Half-moon gear; 29. ​​Actuating gear; 30. Spring box; 31. Constraint insert rod; 32. Downward pressure spring; 33. Constraint groove; 34. Power terminal; 35. Positioning insert plate; 36. Positioning slot; 37. Power insert rod; 38. Power slot; 39. Positioning slot; 40. Positioning spring; 41. Push rod; 42. Detailed Implementation

[0037] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0038] Please see the appendix Figures 1-15 This application provides the following technical solutions.

[0039] Example 1: An ozone generator includes an ozone-generating water tank 1. Several disassembly and assembly connection boxes 2 are installed at the lower end of the ozone-generating water tank 1. Two multi-functional combination connectors 3 are symmetrically arranged at both the upper and lower ends of each disassembly and assembly connection box 2. A reaction component is inserted into one side of each multi-functional combination connector 3. The reaction component includes an ozone-generating module 5. A positive electrode plate 6 and a negative electrode plate 7 are fixedly arranged on both sides of the ozone-generating module 5, respectively. A reaction enclosure 8 is sealed and fixedly arranged on one side of both the positive electrode plate 6 and the negative electrode plate 7. Circulation tubes 9 are symmetrically arranged at both the upper and lower ends of the reaction enclosure 8, and the two circulation tubes 9 of the reaction enclosure 8 are respectively inserted into… The upper and lower multi-functional combination connectors 3 are connected to the disassembly and assembly connection box 2 on one side. The disassembly and assembly connection box 2 has a U-shaped structure. Each of the two multi-functional combination connectors 3 at the upper end of the disassembly and assembly connection box 2 is fixedly equipped with a return support pipe 4. The upper ends of the two return support pipes 4 are respectively connected to and fixedly inserted into the lower end of the ozone preparation water tank 1. The two multi-functional combination connectors 3 at the lower end of the disassembly and assembly connection box 2 are respectively equipped with a negative electrode water inlet pipe 13 and a three-way connector. The negative electrode water inlet pipe 13 is connected to the reaction chamber 8 of the negative electrode plate 7. The two sides of the three-way connector are respectively connected to a positive electrode water inlet pipe 10 and a return water pipe 11. The upper ends of pipe 10, return water pipe 11, and negative electrode inlet water pipe 13 are respectively connected and fixedly inserted into the lower end of ozone preparation water tank 1. The upper end of the return support pipe 4 connected to the reaction cover box 8 on the positive electrode plate 6 is inserted into the ozone preparation water tank 1 and together with the upper end of the return water pipe 11, an ozone collection bottle 12 is provided. When ozone is generated, the industrial water is filtered by a pure water machine. The purified water is then pumped into the ozone preparation water tank 1. The purified water entering the ozone preparation water tank 1 enters the reaction cover box 8 on one side of the positive electrode plate 6 and the negative electrode plate 7 through the return water pipe 11 and the negative electrode inlet water pipe 13, respectively. When water enters the reaction chamber 8, the positive electrode plate 6 and the negative electrode plate 7 produce ozone from the pure water. The ozone gas produced enters the reflux support tube 4 from the circulation tube 9 above the reaction chamber 8 of the positive electrode plate 6, and then enters the ozone collection bottle 12. Finally, the ozone from several ozone collection bottles 12 is collected. The hydrogen gas produced by ozone production enters the reaction chamber 8 on one side of the negative electrode plate 7 through the proton exchange membrane, and then flows back to the ozone production water tank 1 under the action of the circulation tube 9 and the reflux support tube 4, where it is collected and treated. The two reflux support tubes 4 are used for hydrogen and ozone reflux collection, respectively.

[0040] The multi-functional combination connector 3 is equipped with a flow-blocking component and a reinforced sealing component. The reinforced sealing component includes a deformable sealing ring 16 and a push ring 19. A U-shaped slot is provided on one side of the disassembly and assembly connection box 2. The ozone preparation module 5 is inserted into the U-shaped slot. The four circulation tubes 9 are all L-shaped structures. When the ozone preparation module 5 is fully inserted into the U-shaped slot, the four circulation tubes 9 are horizontally inserted into one side of the four multi-functional combination connectors 3. Two sealing rings 14 are symmetrically embedded on the side of the multi-functional combination connector 3 that is fitted onto the circulation tube 9. The two sealing rings 14 are fitted onto the circulation tube 9. A compression groove 15 is provided on the side of the multi-functional combination connector 3 that is fitted onto the circulation tube 9. A deformable sealing ring 16 is inserted into the compression groove 15. The deformable sealing ring 16 is fitted onto the circulation tube 9. On the ring tube 9, an extrusion ring 17 is provided on the side of the extrusion groove 15 near the deformable sealing ring 16. One side of the extrusion ring 17 abuts against the deformable sealing ring 16, and the side of the extrusion ring 17 in contact with the deformable sealing ring 16 is a conical surface. When the ozone preparation module 5 is assembled and connected to the disassembly and assembly connection box 2, it is installed by horizontal insertion. At this time, the four circulation tubes 9 are respectively inserted into the four multi-functional combination connectors 3. The insertion operation is stable and reliable, and under the action of the sealing ring 14, the seal is reliable after connection. When it is necessary to enhance the sealing effect between the multi-functional combination connector 3 and the circulation tube 9, the conical surface of the extrusion ring 17 can be used to extrude the conical surface of the deformable sealing ring 16, so that the deformable sealing ring 16 deforms and extrudes the circulation tube 9, thereby enhancing the sealing effect.

[0041] The upper and lower ends of the disassembly and assembly connection box 2 are respectively equipped with control components, including control plates 23. The control plates 23 are located between two multi-functional combination connectors 3. The upper and lower ends of the multi-functional combination connectors 3 are provided with control movable grooves 20. The lower end of each control movable groove 20 is provided with a horizontal sliding groove 22. The two control plates 23 are slidably inserted into the two horizontal sliding grooves 22 respectively. The side of the multi-functional combination connector 3 near the extrusion groove 15 is provided with a sleeve groove 18. The multi-functional combination connector 3 is movably sleeved with a push ring 19 at the position of the sleeve groove 18. The control movable groove 20 is located within the multi-functional combination connector 3. The connecting joint 3 has horizontally opened strip grooves 21 on one side of the socket groove 18. The push ring 19 near the strip groove 21 has horizontally opened synchronous pull rods 24. The two synchronous pull rods 24 pass through the strip groove 21 and are inserted into the control movable groove 20 and connected to one side of the control plate 23. When the control plate 23 is pulled horizontally in the horizontal sliding groove 22, the two push rings 19 can be controlled to move towards the squeezing ring 17 by the horizontal sliding of the synchronous pull rods 24 in the strip groove 21. The sliding insertion of the strip groove 21 and the synchronous pull rods 24 also guides and supports the horizontal sliding of the control plate 23.

[0042] The flow-stopping assembly includes a sealing ball core 26. A sealing ball groove 25 is provided within the multi-functional combination connector 3 between the circulation tube 9 and the return support tube 4. A sealing ball core 26 is rotatably inserted into each sealing ball groove 25. A docking valve groove 27 is provided through each sealing ball core 26, with the diameter of the docking valve groove 27 being the same as the inner diameter of the return support tube 4. A synchronous shaft 28 is horizontally positioned at the center of each sealing ball core 26 near the control movable groove 20. One side of the synchronous shaft 28 is movably inserted into the control movable groove 20. A crescent gear 29 is provided between the two synchronous shafts 28 in the moving groove 20. Several actuating teeth 30 are provided on one side of the upper end of the control plate 23, and the teeth of the crescent gear 29 are meshed with the actuating teeth 30. When the ozone preparation module 5 is not connected to the disassembly and assembly connection box 2, the multi-functional combination connector 3 can perform self-sealing operation through the sealing ball core 26. The operation is performed by moving the control plate 23 horizontally and actuating the crescent gear 29 to control the sealing ball core 26 to rotate 90 degrees, so that the docking valve groove 27 is misaligned with the return support pipe 4.

[0043] A plurality of push rods 42 are symmetrically arranged on one side of the compression ring 17 near the socket groove 18. One side of each push rod 42 is movably inserted into the socket groove 18. When the push ring 19 compresses and pushes the push rods 42, the docking valve groove 27 of the sealing ball 26 is connected to the return support pipe 4 and the circulation pipe 9. When the circulation pipe 9 is inserted into the multi-functional combination connector 3, the ozone preparation module 5 is in the working requirement state. In order to ensure that there is no pure water leakage when the circulation pipe 9 is connected to the multi-functional combination connector 3, and the circulation pipe 9 When connected to the return support pipe 4, the control plate 23 is pulled to control the push ring 19 to contact the push rod 42, pushing the push rod 42 and the compression ring 17 to move towards the position of the deformable sealing ring 16, compressing and deforming the deformable sealing ring 16, and strengthening the contact sealing effect between the deformable sealing ring 16 and the circulation tube 9. After the control plate 23 moves, the teeth 30 are turned to rotate the half-moon gear 29, so that the docking valve groove 27 of the sealing ball 26 is connected to the return support pipe 4 and the circulation tube 9, and normal ozone preparation can be carried out.

[0044] Conversely, when it is necessary to disassemble the ozone preparation module 5 from the disassembly and assembly connection box 2, the control plate 23 slides back to its original position, the deformable sealing ring 16 loses its reinforced sealing pressure state, and the sealing ball core 26 cuts off and seals the multi-functional combination connector 3. At this time, the ozone preparation module 5 can be pulled out forcefully, and the four circulation tubes 9 can be moved away from the multi-functional combination connector 3 to complete the rapid replacement of the ozone preparation module 5.

[0045] A spring box 31 is vertically provided on the upper side of the control plate 23 away from the actuating teeth 30. A constraint rod 32 is vertically inserted into the spring box 31 through a pressure block. A pressure spring 33 is sleeved on the side of the pressure block inside the spring box 31 for each constraint rod 32. A constraint groove 34 is provided on both sides of the horizontal slide groove 22, and the constraint rod 32 is selectively inserted into one of the constraint grooves 34. When the control plate 23 has two position holding states, a constraint groove 34 is provided in each of the two positions. When the control plate 23 moves to the position, the constraint rod 32 is inserted into it to limit and fix the movement of the control plate 23, and maintain the blocking or connecting state of the sealing ball 26.

[0046] In this embodiment:

[0047] Example 2: Based on Example 1, a power connection positioning component is set up to optimize the positive and negative electrode wires of the ozone generation module 5. The power connection positioning component includes a positioning plate 36, with its two sides connected to the positive electrode plate 6 and the negative electrode plate 7, respectively. The positioning plate 36 is inserted into one side of the disassembly and assembly connection box 2. Both the positive electrode plate 6 and the negative electrode plate 7 have power connection terminals 35 on the side near the disassembly and assembly connection box 2. The two sides of the positioning plate 36 are fixedly connected to the two power connection terminals 35 by power connection screws. A positioning slot 37 is horizontally opened on one side of the disassembly and assembly connection box 2, and the positioning plate 36 is horizontally inserted into it. The positioning plate 36 is inserted into the positioning slot 37. The two sides of the positioning plate 36 are electrically connected to the two electrical terminals 35 respectively. Two electrical connectors 38 are provided. Two electrical slots 39 are symmetrically provided on both sides of the positioning slot 37. The two electrical connectors 38 are inserted into the two electrical slots 39 respectively. Through the structure of the built-in electrical slots 39 and the added matching electrical connectors 38, the problem of leakage caused by exposed electrical wires is avoided. The electrical position is protected. When the ozone preparation module 5 is disassembled and replaced, it can be easily disassembled by the horizontal insertion of the ozone preparation module 5.

[0048] Two positioning springs 41 are embedded in the upper and lower ends of the positioning slot 37. Positioning slots 40 are horizontally opened at both ends of the positioning plate 36. One side of each of the two positioning springs 41 is elastically inserted into the two positioning slots 40. When the ozone preparation module 5 is inserted into the disassembly and assembly connection box 2, the elastic insertion of the positioning springs 41 and the positioning slots 40 can maintain the basic position of the ozone preparation module 5, which is convenient for subsequent operation of the control board 23.

[0049] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. An ozone generator, characterized in that, include: Ozone preparation water tank (1), the lower end of the ozone preparation water tank (1) is equipped with several disassembly and assembly connection boxes (2), the upper and lower ends of the disassembly and assembly connection box (2) are symmetrically provided with two multi-functional combination connectors (3), one side of the multi-functional combination connector (3) is inserted with a reaction component, the reaction component includes an ozone preparation module (5), the two sides of the ozone preparation module (5) are respectively fixed with a positive electrode plate (6) and a negative electrode plate (7), one side of the positive electrode plate (6) and the negative electrode plate (7) are respectively sealed and fixed with a reaction cover box (8), the upper and lower ends of the reaction cover box (8) are symmetrically provided with circulation tubes (9), and the two circulation tubes (9) of the reaction cover box (8) are respectively inserted into the upper and lower two multi-functional combination connectors (3) on one side of the disassembly and assembly connection box (2); The multi-functional combination connector (3) is provided with a flow-blocking component and a reinforced sealing component. The flow-blocking component includes a sealing ball core (26), and the reinforced sealing component includes a deformable sealing ring (16) and a push ring (19). The upper and lower ends of the disassembly and assembly connection box (2) are respectively provided with control components. The control components include a control plate (23). The control plate (23) is located between the two multi-functional combination connectors (3). The control plate (23) is connected to the sealing ball core (26) and the push ring (19) of the two multi-functional combination connectors (3) respectively. The power-connecting positioning assembly includes a positioning insert (36), the two sides of which are connected to the positive electrode plate (6) and the negative electrode plate (7) respectively, and the positioning insert (36) is inserted into one side of the disassembly and assembly connection box (2). The disassembly and assembly connection box (2) has a U-shaped slot on one side. The ozone preparation module (5) is inserted into the U-shaped slot. The four circulation tubes (9) are all L-shaped structures. When the ozone preparation module (5) is fully inserted into the U-shaped slot, the four circulation tubes (9) are respectively horizontally inserted into one side of the four multi-functional combination connectors (3). The multifunctional combination connector (3) is fitted with two sealing rings (14) symmetrically on one side of the circulation tube (9). The two sealing rings (14) are fitted onto the circulation tube (9). The multifunctional combination connector (3) is fitted with a compression groove (15) on one side of the circulation tube (9). A deformable sealing ring (16) is inserted into the compression groove (15). The deformable sealing ring (16) is fitted onto the circulation tube (9). A compression ring (17) is provided on one side of the compression groove (15) near the deformable sealing ring (16). One side of the compression ring (17) abuts against the deformable sealing ring (16), and the side of the compression ring (17) that contacts the deformable sealing ring (16) is a conical surface. The upper and lower ends of the disassembly and assembly connection box (2) are provided with control movement grooves (20), and the lower end of the control movement grooves (20) is provided with horizontal sliding grooves (22). The two control plates (23) are slidably inserted into the two horizontal sliding grooves (22). The multi-functional combination joint (3) is provided with a sleeve groove (18) on the side near the extrusion groove (15). The multi-functional combination joint (3) is provided with a push ring (19) in the sleeve groove (18). The control movement groove (20) is provided with a horizontal strip groove (21) on the side of the sleeve groove (18) of the multi-functional combination joint (3). The side of the push ring (19) near the strip groove (21) is provided with a horizontal synchronous pull rod (24). The two synchronous pull rods (24) pass through the strip groove (21) and are inserted into the control movement groove (20) and connected to one side of the control plate (23). The multi-functional combination connector (3) is provided with a sealing ball groove (25) between the circulation tube (9) and the return support tube (4). A sealing ball core (26) is rotatably inserted into the sealing ball groove (25). A docking valve groove (27) is provided through the sealing ball core (26). The diameter of the docking valve groove (27) is the same as the inner diameter of the return support tube (4). A synchronous shaft (28) is horizontally provided at the center of the side of the sealing ball core (26) close to the control active groove (20). One side of the synchronous shaft (28) is movably inserted into the control active groove (20). A crescent gear (29) is provided between the two synchronous shafts (28) inserted into the control active groove (20). A number of actuating teeth (30) are provided on the upper side of the control plate (23). The teeth of the crescent gear (29) are meshed with the actuating teeth (30). The compression ring (17) is symmetrically provided with several push rods (42) on one side near the socket groove (18). One side of each push rod (42) is movably inserted into the socket groove (18). When the push ring (19) squeezes and pushes the push rod (42), the docking valve groove (27) of the sealing ball core (26) is connected to the return support pipe (4) and the circulation insertion pipe (9).

2. An ozone generator according to claim 1, characterized in that: The disassembly and assembly connection box (2) has a U-shaped structure. The two multi-functional combination connectors (3) at the upper end of the disassembly and assembly connection box (2) are each fixedly provided with a return support pipe (4). The upper ends of the two return support pipes (4) are respectively connected to and fixedly inserted into the lower end of the ozone preparation water tank (1). The two multi-functional combination connectors (3) at the lower end of the disassembly and assembly connection box (2) are respectively provided with a negative electrode water inlet pipe (13) and a three-way connector. The negative electrode water inlet pipe (13) and the negative electrode plate (7) are reacted together. The box (8) is connected, and the two sides of the three-way connector are respectively connected to the positive electrode water inlet pipe (10) and the return water pipe (11). The upper ends of the positive electrode water inlet pipe (10), the return water pipe (11) and the negative electrode water inlet pipe (13) are respectively connected and fixedly inserted into the lower end of the ozone preparation water tank (1). The upper end of the return support pipe (4) connected to the reaction cover box (8) on the positive electrode plate (6) is inserted into the ozone preparation water tank (1) and together with the upper end of the return water pipe (11), an ozone collection bottle (12) is provided.

3. An ozone generator according to claim 2, characterized in that: The control board (23) has a spring box (31) vertically installed on the upper side away from the actuating teeth (30). A constraint rod (32) is vertically inserted into the spring box (31) through a pressure block. A pressure spring (33) is sleeved on the side of the pressure block inside the spring box (31) of the constraint rod (32). A constraint groove (34) is opened on both sides of the horizontal slide (22), and the constraint rod (32) is selectively inserted into one of the constraint grooves (34).

4. An ozone generator according to claim 3, characterized in that: The positive electrode plate (6) and the negative electrode plate (7) are provided with electrical terminals (35) on the side near the disassembly and assembly connection box (2). The two sides of the positioning plate (36) are fixedly connected to the two electrical terminals (35) by electrical screws. The disassembly and assembly connection box (2) is provided with a horizontal positioning slot (37) on one side. The positioning plate (36) is horizontally inserted into the positioning slot (37). The two sides of the positioning plate (36) inserted into the positioning slot (37) are electrically connected to the two electrical terminals (35) and provided with two electrical rods (38). The two sides of the positioning slot (37) are symmetrically provided with two electrical slots (39), and the two electrical rods (38) are inserted into the two electrical slots (39) respectively.

5. An ozone generator according to claim 4, characterized in that: The positioning slot (37) is equipped with two positioning spring pieces (41) at both the upper and lower ends. The positioning insert plate (36) is horizontally provided with positioning slots (40) at both the upper and lower ends. One side of each of the two positioning spring pieces (41) is elastically inserted into the two positioning slots (40).

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