Glass frosting powder mixing tank with up-down flipping structure

By introducing an up-and-down tumbling structure and multiple components into the glass frosting powder mixing tank, the problem of uneven mixing caused by raw material agglomeration was solved, achieving a more uniform and thorough mixing effect.

CN224388650UActive Publication Date: 2026-06-23DENGFENG CITY YUKE GLASS TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DENGFENG CITY YUKE GLASS TECH
Filing Date
2025-07-23
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing glass frosting powder mixing tanks are prone to clumping when used for a long time or when the raw materials are damp, resulting in uneven mixing.

Method used

Design a glass frosted powder mixing tank with an up-and-down tilting structure. By fixing a connecting plate to the end of the connecting rod and fixing multiple crushing rods to the connecting plate, combined with a rotating connecting block, a material distribution plate, an elastic rope, and crushing nails, the raw materials are dispersed, diffused, and crushed to avoid clumping and ensure uniform mixing.

Benefits of technology

It effectively reduces the clumping of raw materials during the mixing process due to moisture or movement in the same direction, and improves the uniformity and thoroughness of mixing.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224388650U_ABST
    Figure CN224388650U_ABST
Patent Text Reader

Abstract

This utility model belongs to the field of chemical equipment technology, specifically a glass frosting powder mixing tank with an up-and-down tilting structure. It includes a base plate, a first fixing plate fixed to the base plate, a motor fixed to the first fixing plate, and a rotating shaft fixed to the output end of the motor. The rotating shaft and the first fixing plate are through-connected and rotatably connected. A second fixing plate is fixed to the base plate, corresponding to the first fixing plate. A hollow shaft is fixed to the second fixing plate, and a mixing tank is rotatably connected between the rotating shaft and the hollow shaft. A connecting rod is fixed to the second fixing plate, located inside the hollow shaft, and through-connected to the mixing tank. A connecting plate is fixed to the end of the connecting rod, and multiple crushing rods are fixed to the connecting plate. The mixing tank has a feed inlet. By fixing the connecting plate to the end of the connecting rod and the multiple crushing rods to the connecting plate, the raw materials can be dispersed during the mixing process, reducing the possibility of raw materials clumping due to moisture or unidirectional movement, thus preventing uneven mixing.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model belongs to the field of chemical equipment technology, specifically a glass frosting powder mixing tank with an up-and-down tilting structure. Background Technology

[0002] Glass frosting powder is a chemical material used for glass surface treatment. It is usually composed of ammonium fluoride, potassium hydrofluoride, calcium fluoride and other main components, with the addition of ammonium sulfate, barium sulfate, potassium sulfate and other additives, and is formulated into a powder product.

[0003] The glass frosting powder mixing tank is a device used to thoroughly and evenly mix the raw materials and additives of glass frosting powder. It adopts a design with multiple sets of stirring rods and scrapers, combined with an up-and-down reciprocating motion mechanism to mix the raw materials. Its core function is to provide high-quality frosting powder for subsequent glass frosting processes.

[0004] Existing glass frosting powder mixing tanks typically place the raw materials inside the tank and then mix them using methods such as stirring. However, during long-term use and observation, it has been found that when the raw materials are damp or are continuously moved in the same direction, they are prone to clumping, which leads to uneven mixing. Therefore, to address the above problems, a glass frosting powder mixing tank with an up-and-down tilting structure is proposed. Utility Model Content

[0005] To overcome the shortcomings of existing technologies and address the problems of existing equipment, this utility model proposes a glass frosting powder mixing tank with an up-and-down tilting structure.

[0006] The technical solution adopted by this utility model to solve its technical problem is a glass frosting powder mixing tank with an up-and-down flipping structure, including a bottom plate, a first fixing plate fixedly connected to the bottom plate, a motor fixedly connected to the first fixing plate, a rotating shaft fixedly connected to the output end of the motor, the rotating shaft and the first fixing plate being through-connected and rotatably connected, a second fixing plate fixedly connected to the bottom plate, the second fixing plate and the first fixing plate being correspondingly arranged, a hollow shaft fixedly connected to the second fixing plate, a mixing tank being rotatably connected between the rotating shaft and the hollow shaft, a connecting rod fixedly connected to the second fixing plate, the connecting rod being located inside the hollow shaft, the connecting rod and the mixing tank being through-connected, a connecting plate fixedly connected to the end of the connecting rod, and multiple crushing rods fixedly connected to the connecting plate, the mixing tank having a feed inlet. By fixing the connecting plate to the end of the connecting rod and fixing multiple crushing rods to the connecting plate, the raw materials can be broken up during the mixing process, reducing the possibility of raw materials clumping due to moisture or movement in the same direction during the mixing process, thus reducing the possibility of uneven mixing.

[0007] Preferably, a connecting block is rotatably connected to the end of the crushing rod, and multiple material dispersing plates are fixedly connected to the connecting block. By rotatably connecting the connecting block to the crushing rod and fixing multiple material dispersing plates to the connecting block, the raw materials can be diffused to the inside of the mixing tank during use, making the raw materials more dispersed inside the mixing tank and making the mixing of the raw materials more thorough.

[0008] Preferably, multiple elastic ropes are fixedly connected to the bulk material plate, and hollow balls are fixedly connected to the ends of the elastic ropes. By fixing elastic ropes to the bulk material plate and hollow balls to the ends of the elastic ropes, the raw materials can be further diffused during use, so that the raw materials can be mixed more evenly.

[0009] Preferably, a plurality of crushing nails are fixedly attached to the bulk material plate, and the crushing nails are arranged in an array. By fixing a plurality of crushing nails to the bulk material plate, the agglomerated raw materials can be further crushed during use, thereby further reducing the situation where the raw materials are difficult to mix evenly due to agglomeration.

[0010] Preferably, the connecting plate is provided with a connecting component, and a diffusion plate is fixedly connected to the connecting component. By fixing the diffusion plate to the connecting component, the raw materials can be dispersed during use, reducing the situation where the raw materials fall together during the up-and-down turning process, which would make it difficult to mix the raw materials evenly.

[0011] Preferably, the connecting assembly includes a spring telescopic rod, which is fixedly connected to the connecting plate, and the other end of the spring telescopic rod is fixedly connected to the diffuser plate. By fixing the spring telescopic rod between the connecting plate and the connecting assembly, the diffuser plate can be lifted upwards during use, thereby further diffusing the raw materials that have not completely fallen off the diffuser plate to the surrounding areas, making the raw materials more evenly mixed.

[0012] The advantages of this utility model are:

[0013] This utility model provides a glass frosting powder mixing tank with an up-and-down flipping structure. By fixing a connecting plate to the end of the connecting rod, and fixing multiple crushing rods to the connecting plate, the raw materials can be flipped and broken up during use, reducing the possibility of raw materials clumping due to moisture or movement in the same direction during the mixing process, thus reducing the possibility of uneven mixing.

[0014] This utility model provides a glass frosting powder mixing tank with an up-and-down tilting structure. By rotating a connecting block on the crushing rod and fixing multiple material dispersing plates on the connecting block, the raw materials can be diffused to the inside of the mixing tank during use, making the raw materials more dispersed inside the mixing tank and making the mixing of the raw materials more thorough. Attached Figure Description

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

[0016] Figure 1 This is a schematic diagram of the main body of the present utility model;

[0017] Figure 2 This is a schematic diagram of the connecting plate in this utility model;

[0018] Figure 3 This is a schematic diagram of the connecting block in this utility model;

[0019] Figure 4 This is a schematic diagram of the elastic rope in this utility model;

[0020] Figure 5 This is a schematic diagram of the spring telescopic rod in this utility model.

[0021] In the diagram: 1. Base plate; 11. First fixing plate; 12. Motor; 13. Rotating shaft; 14. Second fixing plate; 15. Hollow shaft; 16. Mixing tank; 17. Connecting rod; 18. Connecting plate; 19. Crushing rod; 110. Feed inlet; 2. Connecting block; 21. Dispersing plate; 3. Elastic rope; 31. Hollow ball; 4. Crushing nail; 5. Connecting assembly; 51. Diffuser plate; 6. Spring telescopic rod; 7. Control box. Detailed Implementation

[0022] 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 scope of protection of the present utility model.

[0023] Please see Figures 1-5As shown, a glass frosting powder mixing tank with an up-and-down tilting structure includes a base plate 1. A first fixing plate 11 is fixedly connected to the base plate 1. A motor 12 is fixedly connected to the first fixing plate 11. A rotating shaft 13 is fixedly connected to the output end of the motor 12. The rotating shaft 13 and the first fixing plate 11 are through-connected and rotatably connected. A second fixing plate 14 is fixedly connected to the base plate 1. The second fixing plate 14 and the first fixing plate 11 are correspondingly arranged. A hollow shaft 15 is fixedly connected to the second fixing plate 14. A mixing tank 1 is rotatably connected between the rotating shaft 13 and the hollow shaft 15. 6. A connecting rod 17 is fixedly connected to the second fixing plate 14. The connecting rod 17 is located inside the hollow shaft 15. The connecting rod 17 and the mixing tank 16 are connected through each other. A connecting plate 18 is fixedly connected to the end of the connecting rod 17. Multiple crushing rods 19 are fixedly connected to the connecting plate 18. The mixing tank 16 has a feed inlet 110. During operation, the frosting powder raw material to be mixed is put into the mixing tank 16 through the feed inlet 110. Then, the feed inlet 110 is sealed with bolts. After sealing, the motor is turned on through the control box 7 set on the first fixing plate 11. 12. When motor 12 is turned on, it drives shaft 13 to rotate. When shaft 13 rotates, it drives mixing tank 16 to rotate accordingly. When mixing tank 16 rotates, it tumbles and mixes the raw materials inside. During the tumbling and mixing process, the raw materials are driven to rotate from the bottom of mixing tank 16. When the raw materials rotate to the designated position, they fall towards feed inlet 110 under their own gravity. When the raw materials fall towards feed inlet 110, the multiple crushing rods 19 fixed on connecting plate 18 come into contact with them. When the raw materials come into contact with the multiple crushing rods 19, the multiple crushing rods 19 crush the raw materials. After being broken up, the raw materials fall into the mixing tank 16 and are turned up and down again. After the mixing is completed, the motor 12 controlled by the control box 7 rotates the feed port 110 to the direction close to the bottom plate 1. Then the feed port 110 is opened to take out the mixed raw materials. By fixing the connecting plate 18 to the end of the connecting rod 17, and fixing multiple crushing rods 19 on the connecting plate 18, the raw materials can be turned up and broken up during the mixing process. This reduces the situation where the raw materials clump together due to moisture or movement in the same direction during the mixing process, which leads to uneven mixing of the raw materials.

[0024] Please see Figures 2-4As shown, a connecting block 2 is rotatably connected to the end of the crushing rod 19. Multiple material dispersing plates 21 are fixedly attached to the connecting block 2. When the raw material rotates with the mixing tank 16 to the designated position, the raw material falls under its own gravity. When the raw material falls, it comes into contact with the connecting block 2. When the raw material comes into contact with the connecting block 2, the connecting block 2 rotates. When the connecting block 2 rotates, the part of the raw material in contact with the connecting block 2 is dispersed to the surroundings. By rotatably connecting the connecting block 2 to the crushing rod 19 and fixing multiple material dispersing plates 21 to the connecting block 2, the raw material can be diffused to the surroundings inside the mixing tank 16 during use, making the raw material more dispersed inside the mixing tank 16 and making the raw material more thoroughly mixed.

[0025] Please see Figure 4 As shown, multiple elastic ropes 3 are fixed to the bulk material plate 21, and hollow balls 31 are fixed to the ends of the elastic ropes 3. When raw materials fall onto the bulk material plate 21, the connecting block 2 rotates. When the bulk material plate 21 rotates, it drives the elastic ropes 3 to rotate. When the elastic ropes 3 rotate, they drive the hollow balls 31 to rotate as well. When the hollow balls 31 rotate, they strike the raw materials. The striking further disperses the raw materials that have not been dispersed by the bulk material plate 21. By fixing the elastic ropes 3 to the bulk material plate 21 and fixing the hollow balls 31 to the ends of the elastic ropes 3, the raw materials can be further diffused during use, so that the raw materials can be mixed more evenly.

[0026] Please see Figure 4 As shown, multiple crushing nails 4 are fixedly attached to the bulk material plate 21. The crushing nails 4 are arranged in an array. When the raw material moves to the designated position, it falls towards the bottom plate 1. When the raw material falls onto the surface of the bulk material plate 21, it comes into contact with the crushing nails 4. At this time, the crushing nails 4 crush the agglomerated raw material. The crushed raw material falls into the mixing tank 16. By fixing multiple crushing nails 4 to the bulk material plate 21, the agglomerated raw material can be further crushed during use, further reducing the situation where the raw material is difficult to mix evenly due to agglomeration.

[0027] Please see Figures 3-5 As shown, a connecting component 5 is provided on the connecting plate 18, and a diffusion plate 51 is fixedly connected to the connecting component 5. When the raw material is driven to a designated position by the rotating mixing tank 16, the raw material moves towards the bottom plate 1. When the raw material falls onto the diffusion plate 51, the diffusion plate 51 disperses the fallen raw material. The dispersed raw material moves in different directions and falls into the mixing tank 16. By fixing the diffusion plate 51 to the connecting component 5, the raw material can be dispersed during use, reducing the situation where the raw material falls together during the up-and-down turning process, which makes it difficult to mix the raw material evenly.

[0028] Please see Figure 5As shown, the connecting assembly 5 includes a spring telescopic rod 6, which is fixedly connected to the connecting plate 18. The other end of the spring telescopic rod 6 is fixedly connected to the diffuser plate 51. When the raw material is turned to a designated position, it falls towards the bottom plate 1. When the raw material falls onto the surface of the diffuser plate 51, the diffuser plate 51 is subjected to force. When the diffuser plate 51 is subjected to force, the spring telescopic rod 6 is compressed. When a portion of the raw material falls off the diffuser plate 51, the force on the spring telescopic rod 6 decreases. At this time, the diffuser plate 51 is lifted up by the elastic force of the spring telescopic rod 6 itself. When the diffuser plate 51 is lifted up, the remaining raw material on the diffuser plate 51 is bounced upward and splashes in all directions. By fixing the spring telescopic rod 6 between the connecting plate 18 and the connecting assembly 5, the diffuser plate 51 can be lifted upward during use, thereby further diffusing the raw material that has not completely fallen off the diffuser plate 51 in all directions, making the raw material mix more evenly.

[0029] Working principle: During operation, the frosting powder raw material to be mixed is fed into the mixing tank 16 through the feed inlet 110, and then the feed inlet 110 is sealed with bolts. After sealing, the motor 12 is turned on by the control box 7 set on the first fixed plate 11. When the motor 12 is turned on, it drives the rotating shaft 13 to rotate. When the rotating shaft 13 rotates, it drives the mixing tank 16 to rotate as well. When the mixing tank 16 rotates, the raw material inside the mixing tank 16 is tumbled and mixed. During the tumbling and mixing process, the raw material is driven to rotate from the bottom of the mixing tank 16. When the raw material rotates to the designated position, it falls towards the feed inlet 110 under its own gravity. When the material falls from the feed inlet 110, the multiple crushing rods 19 fixed on the connecting plate 18 come into contact. When the material comes into contact with the multiple crushing rods 19, the multiple crushing rods 19 break up the material. The broken material falls into the mixing tank 16 and is tumbled up and down again. After mixing is completed, the motor 12 controlled by the control box 7 rotates the feed inlet 110 to the direction close to the bottom plate 1. Then the feed inlet 110 is opened to take out the mixed material. When the material rotates with the mixing tank 16 to the designated position, the material falls under its own gravity. When the material falls, it comes into contact with the connecting block 2. When the material comes into contact with the connecting block 2, the connecting block 2 rotates. When the connecting block 2 rotates, it breaks up the material. The raw material in contact with block 2 is dispersed in all directions. When the raw material falls onto the material distribution plate 21, the connecting block 2 rotates. The rotation of the material distribution plate 21 drives the elastic rope 3 to rotate, which in turn drives the hollow ball 31 to rotate. As the hollow ball 31 rotates, it strikes the raw material, further dispersing any raw material that has not been dispersed by the material distribution plate 21. When the raw material reaches the designated position, it falls towards the bottom plate 1. When the raw material falls onto the surface of the material distribution plate 21, it comes into contact with the crushing nail 4. At this time, the crushing nail 4 crushes the clumps of raw material. The crushed raw material falls into the mixing tank 16. The raw material is then carried by the rotating mixing tank 16 to the designated position. After being positioned, the raw material moves towards the bottom plate 1. When the raw material falls onto the diffuser plate 51, the diffuser plate 51 disperses the falling raw material. The dispersed raw material moves in different directions and falls into the mixing tank 16. When the raw material is turned to the designated position, it falls towards the bottom plate 1. When the raw material falls onto the surface of the diffuser plate 51, the diffuser plate 51 is subjected to force. When the diffuser plate 51 is subjected to force, the spring telescopic rod 6 is compressed. When a part of the raw material falls off the diffuser plate 51, the force on the spring telescopic rod 6 decreases. At this time, the spring telescopic rod 6 lifts the diffuser plate 51 under its own elastic force. When the diffuser plate 51 is lifted, the remaining raw material on the diffuser plate 51 is bounced upward and splashes in all directions.

[0030] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.

[0031] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model.

Claims

1. A glass frosting powder mixing tank with an up-and-down tilting structure, characterized in that: Includes a base plate (1), on which a first fixing plate (11) is fixedly connected, and a motor (12) is fixedly connected to the first fixing plate (11). A rotating shaft (13) is fixedly connected to the output end of the motor (12). The rotating shaft (13) and the first fixing plate (11) are through-connected and rotatably connected. A second fixing plate (14) is fixedly connected to the base plate (1), and the second fixing plate (14) and the first fixing plate (11) are correspondingly connected. A hollow shaft is fixedly connected to the second fixing plate (14). 15), a mixing tank (16) is rotatably connected between the rotating shaft (13) and the hollow shaft (15). A connecting rod (17) is fixedly connected to the second fixed plate (14). The connecting rod (17) is located inside the hollow shaft (15). The connecting rod (17) and the mixing tank (16) are connected through each other. A connecting plate (18) is fixedly connected to the end of the connecting rod (17). Multiple crushing rods (19) are fixedly connected to the connecting plate (18). A feed inlet (110) is opened on the mixing tank (16).

2. The glass frosting powder mixing tank with an up-and-down tilting structure according to claim 1, characterized in that: The end of the crushing rod (19) is rotatably connected to a connecting block (2), and multiple material distribution plates (21) are fixedly connected to the connecting block (2).

3. A glass frosting powder mixing tank with an up-and-down tilting structure according to claim 2, characterized in that: Multiple elastic ropes (3) are fixedly connected to the bulk material plate (21), and hollow balls (31) are fixedly connected to the ends of the elastic ropes (3).

4. A glass frosting powder mixing tank with an up-and-down tilting structure according to claim 2, characterized in that: Multiple crushing nails (4) are fixedly attached to the bulk material plate (21), and the crushing nails (4) are arranged in an array.

5. A glass frosting powder mixing tank with an up-and-down tilting structure according to claim 1, characterized in that: A connecting component (5) is provided on the connecting plate (18), and a diffuser plate (51) is fixedly connected to the connecting component (5).

6. A glass frosting powder mixing tank with an up-and-down tilting structure according to claim 5, characterized in that: The connecting component (5) includes a spring telescopic rod (6), which is fixedly connected to the connecting plate (18), and the other end of the spring telescopic rod (6) is fixedly connected to the diffuser plate (51).

7. A glass frosting powder mixing tank with an up-and-down tilting structure according to claim 1, characterized in that: A control box (7) is fixedly connected to the first fixing plate (11), and the control box (7) is used to control the start and stop of the motor (12).