An ozone oxidation treatment device for non-polar material surfaces

By designing an ozone oxidation treatment device for non-polar material surfaces with an arc-shaped sealing plate, motor components, and material storage structure, the problem of dead corners caused by the fixation of porous and breathable support structures was solved, enabling the rotational oxidation of raw materials in the reaction chamber and improving processing efficiency.

CN224430716UActive Publication Date: 2026-06-30SHANGHAI WANFENG NEW MATERIAL TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI WANFENG NEW MATERIAL TECH CO LTD
Filing Date
2025-06-19
Publication Date
2026-06-30

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Abstract

This utility model relates to the technical field of oxidation treatment devices and discloses an ozone oxidation treatment device for the surface of non-polar materials. It includes a reaction chamber with flanges at the top and bottom. A material inlet slot communicating with the chamber's own space is provided on one side wall. An arc-shaped sealing plate, a motor component, and a material storage structure are arranged on the outside of the reaction chamber. The material storage structure is fitted inside the arc-shaped sealing plate, and the assembly formed by the arc-shaped sealing plate and the material storage structure aligns with the material inlet slot, enabling a sealed fit between the material inlet slot and the reaction chamber. This utility model, through the arc-shaped sealing plate, motor component, and material storage structure forming a multi-functional material storage structure, and subsequently combined with a combination baffle, long screw, and nut to form a locking structure, and the reaction chamber, not only meets the requirements for convenient material handling in the oxidation reaction but also allows the material to participate in the oxidation reaction inside the reaction chamber through rotational adjustment.
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Description

Technical Field

[0001] This utility model relates to the technical field of oxidation treatment devices, specifically an ozone oxidation treatment device for the surface of non-polar materials. Background Technology

[0002] Currently, ozone oxidation is one of the most important and commonly used treatment technologies in the surface treatment of non-polar materials. The main equipment of existing ozone oxidation treatment devices includes: air pretreatment, ozone generator, water-ozone contact reaction chamber, and ozone exhaust gas treatment. The specific working principle is to run the ozone generator to maintain a stable ozone concentration. The ozone enters the ozone contact reaction chamber through the connecting pipe and then fully contacts the material to be treated on the porous and breathable support structure in the reaction chamber. After a certain treatment time, the exhaust gas is discharged through the exhaust pipe and treated. The overall process is efficient and has a full reaction effect.

[0003] However, after actual operation, the applicant found that the porous and breathable support structure in the prior art is mostly a fixed design in the reaction chamber. This means that the material to be treated can only participate in the oxidation reaction in a flat manner, which is prone to dead corners and also imposes a basic structural limitation on the improvement of the upper limit of the processing efficiency. Therefore, in order to address the shortcomings of the prior art, the applicant will provide an ozone oxidation treatment device for non-polar material surfaces to improve it. Utility Model Content

[0004] This invention provides an ozone oxidation treatment device for non-polar material surfaces, which solves the problems mentioned in the background art.

[0005] This utility model provides the following technical solution: a non-polar material surface ozone oxidation treatment device, including a reaction chamber, flange pipes are provided at the top and bottom of the reaction chamber, a material taking groove communicating with its own space is opened on one side wall of the reaction chamber, an arc-shaped sealing plate, a motor component, and a material storage structure are provided on the outside of the reaction chamber, the material storage structure is fitted inside the arc-shaped sealing plate, and the combination formed by the arc-shaped sealing plate and the material storage structure is aligned with the material taking groove and can seal the material taking groove with the reaction chamber.

[0006] The motor component is mounted on the surface of the middle part of the arc-shaped sealing plate, and the output end of the motor component passes through the middle side wall of the arc-shaped sealing plate and is connected to one side of the storage structure, enabling the storage structure to rotate and adjust inside the reaction chamber.

[0007] The inner walls of the front and rear ends of the material receiving trough are fixedly nested with combined baffles. The inside of the combined baffles is fitted with a long screw that is fixed to the front end or rear end of the arc-shaped sealing plate. One end of the long screw is threaded with a nut.

[0008] Preferably, the storage structure includes a disc-shaped frame and a cover frame, wherein a first filter screen and a second filter screen are respectively nested in the structural gaps of the disc-shaped frame and the structural gaps of the cover frame;

[0009] The inner wall of the top of the disc-shaped frame is fixed with an internal threaded sleeve plate. The inside of the cover plate frame is provided with a clearance hole aligned with the internal threaded sleeve plate. The disc-shaped frame and the cover plate frame can be detachably installed by means of screws fitting into the clearance hole and then being threadedly connected to the internal threaded sleeve plate.

[0010] Preferably, the arc-shaped sealing plate has an assembly hole in the middle side wall, and the motor component includes a brake servo motor and a support base. The support base is installed between the surface of the brake servo motor housing and the surface of the middle part of the arc-shaped sealing plate, and the output end of the brake servo motor passes through the assembly hole and is connected to the middle part of one side of the disc frame.

[0011] Preferably, a bearing and a shaft seal are nested in the fitting gap between the output end of the brake servo motor and the assembly hole.

[0012] Preferably, the cover plate frame has several linkage screw holes inside, and T-shaped screws extending into the internal space of the disc-shaped frame are threaded into the linkage screw holes.

[0013] Preferably, a support frame is installed at the bottom of the reaction chamber, and an auxiliary support structure is provided on one side of the top of the support frame to support the storage structure that is separate from the reaction chamber.

[0014] Preferably, the front and rear ends of the top of the auxiliary support structure are provided with mounting grooves, and a number of movable rollers are installed in the mounting grooves along the transverse arrangement of the support frame, and the top surface of the movable rollers is movably connected to the bottom surface of the disc frame.

[0015] Preferably, the surface of the arc-shaped sealing plate is covered with an arc-shaped sealing sleeve, and the arc-shaped sealing sleeve can fill and seal the assembly gap between the arc-shaped sealing plate and the material receiving groove.

[0016] This utility model has the following beneficial effects:

[0017] 1. This utility model consists of an arc-shaped sealing plate, a motor component, and a material storage structure, forming a multi-functional material storage structure. When combined with a combination baffle, a long screw, and a nut to form a locking structure and a reaction chamber, it not only meets the conditions for convenient loading and unloading of raw materials for oxidation reactions, but also allows the raw materials to participate in the oxidation reaction inside the reaction chamber by rotating and adjusting, thus fully ensuring the contact between the raw materials and ozone.

[0018] 2. This utility model forms an auxiliary support structure through a support frame, an auxiliary support structure, and a movable roller fitted on top of the auxiliary support structure. When used in combination with the aforementioned multi-functional storage structure, it can provide auxiliary support and rolling guidance for the multi-functional storage structure, further optimizing the overall performance of the device. Attached Figure Description

[0019] Figure 1 This is a three-dimensional schematic diagram of the structure of this utility model;

[0020] Figure 2 This is a top view of the structure of this utility model;

[0021] Figure 3 This is a top view of the disc-shaped frame structure of this utility model;

[0022] Figure 4 This is a top view of the structural cover plate frame of this utility model;

[0023] Figure 5 This is a three-dimensional schematic diagram of the disc-shaped frame structure of this utility model;

[0024] Figure 6 The structure of this utility model Figure 1 Enlarged diagram of point A in the middle.

[0025] In the diagram: 1. Reaction chamber; 2. Feeding trough; 3. Arc-shaped sealing plate; 4. Motor components; 5. Material storage structure; 51. Disc-shaped frame; 52. First filter screen; 53. Internal threaded sleeve; 54. Cover plate frame; 55. Second filter screen; 6. Combined baffle; 7. Long screw; 8. Nut; 9. Support frame; 10. Auxiliary support structure; 11. T-shaped screw; 12. Arc-shaped sealing sleeve; 13. Movable roller. Detailed Implementation

[0026] 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.

[0027] Please see Figures 1-4An ozone oxidation treatment device for non-polar material surfaces includes a reaction chamber 1. Flange pipes are provided at the top and bottom of the reaction chamber 1. A material intake trough 2 communicating with its own space is opened on one side wall of the reaction chamber 1. An arc-shaped sealing plate 3, a motor component 4, and a material storage structure 5 are provided on the outside of the reaction chamber 1. The material storage structure 5 is fitted inside the arc-shaped sealing plate 3, and the combination formed by the arc-shaped sealing plate 3 and the material storage structure 5 is aligned with the material intake trough 2 and can seal the material intake trough 2 with the reaction chamber 1. The surface of the arc-shaped sealing plate 3 is covered with an arc-shaped sealing sleeve 12, and the arc-shaped sealing sleeve 12 can fill and seal the assembly gap between the arc-shaped sealing plate 3 and the material intake trough 2, so as to fully ensure the sealing effect of the overall structure of the reaction chamber 1 assembled and connected with the arc-shaped sealing plate 3 and the reaction chamber 1.

[0028] The motor component 4 is mounted on the surface of the middle part of the arc-shaped sealing plate 3, and the output end of the motor component 4 passes through the middle side wall of the arc-shaped sealing plate 3 and is connected to one side of the storage structure 5, enabling the storage structure 5 to rotate and adjust inside the reaction chamber 1.

[0029] The storage structure 5 includes a disc-shaped frame 51 and a cover frame 54. A first filter screen 52 and a second filter screen 55 are respectively nested in the structural gaps of the disc-shaped frame 51 and the structural gaps of the cover frame 54. An internally threaded sleeve plate 53 is fixed to the top inner wall of the disc-shaped frame 51. The cover frame 54 has a clearance hole that aligns with the internally threaded sleeve plate 53. The disc-shaped frame 51 and the cover frame 54 can be detached and installed by means of screws fitting into the clearance hole and then threadedly connected to the internally threaded sleeve plate 53. This facilitates subsequent maintenance and replacement and ensures the continuous use of the main structure of the overall device.

[0030] The arc-shaped sealing plate 3 has an assembly hole on its middle side wall. The motor component 4 includes a brake servo motor and a support base. The support base is installed between the surface of the brake servo motor housing and the surface of the middle part of the arc-shaped sealing plate 3. The output end of the brake servo motor passes through the assembly hole and is connected to the middle part of one side of the disc frame 51. This satisfies the requirements for the rotation and adjustment of the storage structure 5 and the raw materials to be processed carried inside the storage structure 5. Bearings and shaft seals are respectively nested in the fitting gap between the output end of the brake servo motor and the assembly hole, thereby ensuring the sealing effect after the arc-shaped sealing plate 3 and the reaction chamber 1 are assembled.

[0031] The inner walls of the front and rear ends of the material feeding trough 2 are fixedly nested with combined baffles 6. The combined baffles 6 are fitted with long screws 7 that are fixed to the front end or rear end of the arc-shaped sealing plate 3. One end of the long screws 7 is threaded with a nut 8.

[0032] In use, the granular raw material to be processed is placed into the filter space formed by the disc frame 51 and the first filter screen 52 inside it for temporary storage and the granular raw material is laid flat. Then, the assembly formed by the cover frame 54 and the second filter screen 55 is placed on the top of the disc frame 51. Then, the disc frame 51 and the cover frame 54 are stably connected by means of screws and clearance holes and then threaded connection with the internal threaded sleeve plate 53.

[0033] After the granular raw materials to be processed are placed, the arc-shaped sealing plate 3 and the storage structure 5 are pushed until the storage structure 5 is fitted inside the reaction chamber 1 through the material receiving groove 2 and the arc-shaped sealing plate 3 is spliced ​​inside the material receiving groove 2. The arc-shaped sealing sleeve 12 fills and seals the gap between the arc-shaped sealing plate 3 and the material receiving groove 2. At the same time, the locking guide of the long screw 7 and the combined baffle 6 constrains and ensures the stability of the movement of the arc-shaped sealing plate 3. Then, the nut 8 is turned so that the nut 8 and the long screw 7 after the movement adjustment are screwed together, thereby limiting and protecting the combination of the arc-shaped sealing plate 3 and the reaction chamber 1.

[0034] Subsequently, during the oxidation process of the raw materials to be treated stored inside the storage structure 5 by ozone entering the reaction chamber 1 through the connecting pipe, the brake servo motor inside the motor component 4 is started. The output end of the brake servo motor drives the storage structure 5 and the raw materials to be treated stored inside the storage structure 5 to rotate back and forth, thereby making the raw materials to be treated fully contact with ozone and fully ensuring the oxidation reaction effect.

[0035] Please see Figures 1-5 The cover plate frame 54 has several linkage screw holes inside, and T-shaped screws 11 extending into the internal space of the disc frame 51 are connected to the linkage screw holes by threads.

[0036] In use, for the oxidation treatment of plate-shaped raw materials, the plate-shaped raw materials can be temporarily stored in the filtration space formed by the disc-shaped frame 51 and the first filter screen 52 inside it. Then, the assembly formed by the cover frame 54 and the second filter screen 55 is placed on top of the disc-shaped frame 51. Then, the disc-shaped frame 51 and the cover frame 54 are stably connected by means of screws and clearance holes and threaded connection with the internal threaded sleeve plate 53. Then, one end of the T-shaped screw 11 is threaded to the corresponding linkage screw hole and, under the support of the cover frame 54, the plate-shaped raw materials are pressed and limited, which fully ensures the stability of the reciprocating rotation of the plate-shaped raw materials in the subsequent oxidation process.

[0037] Please see Figures 1-6A support frame 9 is installed at the bottom of the reaction chamber 1, and an auxiliary support structure 10 is provided on one side of the top of the support frame 9 to support the storage structure 5 which is separate from the reaction chamber 1. The front and rear ends of the top of the auxiliary support structure 10 are provided with mounting grooves, and several movable rollers 13 are installed in the mounting grooves along the transverse arrangement of the support frame 9. The top surface of the movable rollers 13 is movably connected to the bottom surface of the disc frame 51, thereby facilitating the movement and adjustment of the assembly formed by the arc-shaped sealing plate 3, the motor component 4 and the storage structure 5.

[0038] During use, as the material storage structure 5 is moved out of the interior of the reaction chamber 1, the top structure of the auxiliary support structure 10 and the movable roller 13 of the top structure set of the auxiliary support structure 10 will provide auxiliary support and rolling guidance for the assembly formed by the arc-shaped sealing plate 3, the motor component 4 and the material storage structure 5, thereby providing the user with an effective means to adjust the assembly formed by the arc-shaped sealing plate 3, the motor component 4 and the material storage structure 5.

[0039] It should be noted that, in this document, relational terms such as "first" and "second" are used merely to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such a process, method, article, or apparatus. Additionally, in the accompanying drawings of this utility model, the fill patterns are merely for distinguishing layers and do not constitute any other limitation.

[0040] Although embodiments of the present 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 present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A non-polar material surface ozone oxidation treatment device, comprising a reaction chamber (1), wherein flange pipes are provided at both the top and bottom of the reaction chamber (1), characterized in that: The reaction chamber (1) has a material chute (2) that communicates with its own space on one side wall. The outer side of the reaction chamber (1) is provided with an arc-shaped sealing plate (3), a motor component (4), and a material storage structure (5). The material storage structure (5) is fitted inside the arc-shaped sealing plate (3), and the combination formed by the arc-shaped sealing plate (3) and the material storage structure (5) is aligned with the material chute (2) and can seal the material chute (2) and the reaction chamber (1). The motor component (4) is mounted on the surface of the middle part of the arc-shaped sealing plate (3), and the output end of the motor component (4) passes through the middle side wall of the arc-shaped sealing plate (3) and is connected to one side of the storage structure (5) and can enable the storage structure (5) to rotate and adjust inside the reaction chamber (1). The inner walls of the front and rear ends of the material feeding trough (2) are fixedly nested with combined baffles (6). The interior of the combined baffles (6) is fitted with long screws (7) that are fixed to the front end or rear end of the arc-shaped sealing plate (3). One end of the long screws (7) is threaded with a nut (8).

2. The ozone oxidation treatment device for non-polar material surfaces according to claim 1, characterized in that: The storage structure (5) includes a disc frame (51) and a cover frame (54). The first filter screen (52) and the second filter screen (55) are respectively nested in the structural gaps of the disc frame (51) and the structural gaps of the cover frame (54). The inner wall of the top of the disc frame (51) is fixed with an internal threaded sleeve plate (53). The cover frame (54) has a clearance hole that is aligned with the internal threaded sleeve plate (53). The disc frame (51) and the cover frame (54) can be detachably installed by means of screws and clearance holes fitting together and then threaded connection with the internal threaded sleeve plate (53).

3. The ozone oxidation treatment device for non-polar material surfaces according to claim 2, characterized in that: The arc-shaped sealing plate (3) has an assembly hole in the middle side wall. The motor component (4) includes a brake servo motor and a support base. The support base is installed between the surface of the brake servo motor housing and the surface of the middle part of the arc-shaped sealing plate (3). The output end of the brake servo motor passes through the assembly hole and is connected to the middle part of one side of the disc frame (51) via a transmission.

4. The ozone oxidation treatment device for non-polar material surfaces according to claim 3, characterized in that: Bearings and shaft seals are respectively nested in the gap between the output end of the brake servo motor and the assembly hole.

5. The ozone oxidation treatment device for non-polar material surfaces according to claim 2, characterized in that: The cover plate frame (54) has several linkage screw holes inside, and T-shaped screws (11) extending into the internal space of the disc frame (51) are threaded into the linkage screw holes.

6. The ozone oxidation treatment device for non-polar material surfaces according to claim 1, characterized in that: The bottom of the reaction chamber (1) is equipped with a support frame (9), and an auxiliary support structure (10) is provided on one side of the top of the support frame (9) to support the storage structure (5) which is separate from the reaction chamber (1).

7. The ozone oxidation treatment device for non-polar material surfaces according to claim 6, characterized in that: The auxiliary support structure (10) has mounting grooves at both the front and rear ends, and several movable rollers (13) are installed in the mounting grooves along the transverse arrangement of the support frame (9), and the top surface of the movable rollers (13) is movably connected to the bottom surface of the disc frame (51).

8. The ozone oxidation treatment device for non-polar material surfaces according to claim 1, characterized in that: The surface of the arc-shaped sealing plate (3) is covered with an arc-shaped sealing sleeve (12), and the arc-shaped sealing sleeve (12) can fill and seal the gap between the arc-shaped sealing plate (3) and the material feeding groove (2).