Molecular iodine mixing and filling device
By using automated filtration components and adjustable filling heads, the problems of filter clogging and filling equipment adapting to different bottle types have been solved, enabling an efficient and continuous molecular iodine filling process.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WEIFANG RUNWU MEDICAL TECHNOLOGY CO LTD
- Filing Date
- 2025-08-08
- Publication Date
- 2026-06-19
AI Technical Summary
The filters of traditional molecular iodine mixing and filling equipment are prone to clogging, requiring regular disassembly and cleaning. This is cumbersome and can easily introduce secondary pollution. Furthermore, the filling process requires stopping the machine to replace the filling head to adapt to different bottle types, affecting production continuity.
It adopts automated filtration, anti-clogging and adjustment components to achieve automatic discharge of impurities, adjustable filling head diameter, reduce downtime for maintenance and replacement, and adapt to different bottle types.
It reduces filter clogging and downtime maintenance frequency, lowers labor intensity, maintains production continuity, avoids downtime caused by contamination and bottle shape changes, and improves filling efficiency.
Smart Images

Figure CN224377664U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of filling machine technology, specifically a molecular iodine mixing filling equipment. Background Technology
[0002] Molecular iodine is the diatomic elemental form of iodine. It has unique physicochemical properties and is widely used in chemical synthesis, industrial production, medical disinfection and many other fields.
[0003] In the industrial production process, molecular iodine is transported through pipelines to the filling tank, where impurities are intercepted by the filter screen inside the pipeline. The motor at the top of the filling tank drives the stirring blades to rotate inside the storage tank, breaking up the iodine preparation precipitate layer. The mixed molecular iodine is then quantitatively controlled by automated mixing and filling equipment to ensure that the amount is kept in a consistent ratio during filling.
[0004] In the molecular iodine mixing and conveying pipeline, after a long period of filtration, impurities accumulate in the filter holes, which can cause blockage. The filter needs to be cleaned regularly. Traditional filters usually need to be disassembled, which requires stopping the equipment and disassembling each part one by one. The operation is relatively cumbersome, and disassembly and reinstallation can easily introduce secondary pollution.
[0005] Therefore, this utility model provides a molecular iodine mixing and filling equipment. Utility Model Content
[0006] In order to overcome the shortcomings of the prior art, at least one technical problem raised in the background art is solved.
[0007] The technical solution adopted by this utility model to solve its technical problem is as follows: A molecular iodine mixing and filling device of this utility model includes a filling platform, a conveyor belt installed in the middle of the filling platform; a filling box installed on the top of the filling platform, a quantitative module installed at the bottom of the filling box, a filling head fixedly connected to the bottom of the quantitative module, and an adjusting component installed in the middle of the filling head; a fixing frame fixedly connected to the outer wall of the filling box, a conveying pipe fixedly connected to the top of the filling box, and the fixing frame fixedly connected to the middle of the conveying pipe; a first motor installed on the top of the filling box, the output end of the first motor penetrating through the top of the filling box, a rotating shaft fixedly connected to the output end of the first motor, and multiple stirring blades fixedly connected to the middle of the rotating shaft; a filter component installed in the middle of the conveying pipe; and an anti-clogging component installed at the end of the conveying pipe.
[0008] Preferably, the filter assembly includes a rotating plate rotatably connected to the middle of the conveying pipe; one end of the rotating plate passes through the middle of the conveying pipe, and a filter screen is fixedly connected to the other end of the rotating plate; a first discharge port is opened at the middle of the rotating plate near the filter screen, and a second discharge port is opened at the middle of the conveying pipe, with the first discharge port and the second discharge port corresponding to each other; a toothed groove is opened at the end of the rotating plate located outside the conveying pipe (15), and two sealing rings are fixedly connected to the middle of the conveying pipe, with the two sealing rings arranged on both sides of the end of the rotating plate; a limit plate is fixedly connected to the side wall of the toothed groove, and a stop block is fixedly connected to the middle of the conveying pipe; a gear is meshed in the middle of the toothed groove, and the output end of a second motor is fixedly connected to the middle of the gear, with the second motor installed on the top of the filling platform; a first fixing rod is fixedly connected to the inner side wall of the conveying pipe, the first fixing rod being L-shaped, and a first scraper is fixedly connected to the middle of the first fixing rod; a collection box is installed on the top of the filling platform, and the collection box is located at the position corresponding to the second discharge port.
[0009] Preferably, the adjusting assembly includes multiple arc-shaped baffles, which are rotatably connected to the inner wall of the filling head and are equidistantly distributed. A connecting shaft is fixed to the end of each arc-shaped baffle, and an adjusting rod is rotatably connected to the middle of the connecting shaft. A threaded sleeve is threaded to the end of the filling head, and a rotating seat is rotatably connected to the end of the threaded sleeve. The end of the adjusting rod is rotatably connected to the middle of the rotating seat.
[0010] Preferably, the anti-clogging component includes a third motor, which is fixedly connected to the top of the filling platform. A rotating rod is fixedly connected to the output end of the third motor. The rotating rod extends through the wall of the conveying pipe and into the middle of the conveying pipe 15. The lower part of the rotating rod is provided with a bidirectional threaded groove. A nut is threadedly connected to the middle of the bidirectional threaded groove. Two connecting rods are fixedly connected to the middle of the nut. The two connecting rods are arranged in a mirror image. A second scraper is fixedly connected to the end of the two connecting rods. The sidewall of the second scraper is in contact with the conveying pipe. An elastic rod is fixedly connected to the middle of the connecting rod. A striking ball is fixedly connected to the end of the elastic rod.
[0011] Preferably, a guide block is fixed to the inner wall of the filling box; two second fixing rods are fixed to the rotating shaft, the two second fixing rods are arranged opposite each other, and the two second fixing rods are respectively arranged at both ends of the rotating shaft; springs are fixed to the ends of the two second fixing rods, and a third scraper is fixed between the ends of the two springs, the third scraper being in contact with the inner wall of the filling box.
[0012] Preferably, a protective cover is fixed to the outer wall of the conveying pipe, and the protective cover is disposed outside the rotating plate and the gear.
[0013] Preferably, an observation plate is fixedly connected to the middle of the filling box, and the observation plate is made of transparent glass.
[0014] The beneficial effects of this utility model are as follows:
[0015] 1. The molecular iodine mixing and filling equipment of this utility model, through the above structure, can periodically and automatically discharge the intercepted and filtered impurities, reducing the blockage of the filter screen due to the accumulation of impurities after a period of use, reducing the decrease in material flow rate during transportation caused by the accumulation of impurities, eliminating the need to stop the machine to disassemble the conveying pipe and filter screen, reducing the tedious operation of periodic disassembly and cleaning, and reducing the problem of pollution caused by impurities introduced during the disassembly of the conveying pipe and filter screen, effectively shortening maintenance time, reducing the frequency of manual cleaning, and reducing labor intensity.
[0016] 2. The molecular iodine mixing and filling equipment described in this utility model can quickly adjust the size of the filling head discharge through the above structure. It can adapt to small bottles by reducing the diameter and reduce liquid splashing, while expanding the diameter can quickly fill large bottles, reduce filling time, control the liquid flow rate, and reduce the problem of needing to stop the machine for replacement when changing the traditional fixed filling port. It can dynamically adapt to the filling rhythm of different bottle types, reduce the downtime or speed fluctuation caused by changes in bottle type, and maintain production continuity. Attached Figure Description
[0017] The present invention will be further described below with reference to the accompanying drawings.
[0018] Figure 1 This is a perspective view of the present invention;
[0019] Figure 2 This is a schematic diagram of the structure of the filter assembly in this utility model;
[0020] Figure 3 This is a schematic diagram of the gear structure in this utility model;
[0021] Figure 4 This is a schematic diagram of the structure of the adjustment component in this utility model;
[0022] Figure 5 This is a schematic diagram of the anti-clogging component in this utility model;
[0023] Figure 6 This is a schematic diagram of the observation plate in this utility model;
[0024] Figure 7 This is a schematic diagram of the structure of the third scraper in this utility model.
[0025] In the diagram: 1. Filling platform; 10. Conveyor belt; 11. Filling box; 12. Quantitative module; 13. Filling head; 14. Fixing frame; 15. Conveying pipe; 16. First motor; 17. Rotating shaft; 18. Stirring blade; 2. Filter assembly; 21. Rotating plate; 22. Filter screen; 23. First discharge port; 24. Second discharge port; 25. Gear groove; 26. Limiting plate; 27. Stop block; 28. Gear; 29. Second motor; 20. Sealing ring; 201. First fixing rod; 20 2. First scraper; 203. Collection box; 3. Adjustment assembly; 31. Arc-shaped baffle; 32. Connecting shaft; 33. Adjusting rod; 34. Rotating seat; 35. Threaded sleeve; 4. Anti-blocking assembly; 41. Third motor; 42. Rotating rod; 43. Bidirectional threaded groove; 44. Nut; 45. Connecting rod; 46. Second scraper; 47. Elastic rod; 48. Striking ball; 5. Guide block; 51. Second fixing rod; 52. Spring; 53. Third scraper; 6. Protective cover; 7. Observation plate. Detailed Implementation
[0026] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.
[0027] like Figures 1 to 7As shown, an embodiment of the present invention provides a molecular iodine mixing and filling device, comprising a filling platform 1, with a conveyor belt 10 installed in the middle of the filling platform 1. A filling box 11 is installed on the top of the filling platform 1, a quantitative module 12 is installed at the bottom of the filling box 11, a filling head 13 is fixedly connected to the bottom of the quantitative module 12, and an adjusting component 3 is installed in the middle of the filling head 13. A fixing frame 14 is fixedly connected to the outer wall of the filling box 11, and a conveying pipe 15 is fixedly connected to the top of the filling box 11, with the fixing frame 14 fixedly connected to the middle of the conveying pipe 15. A first motor 16 is installed on the top of the filling box 11, with the output end of the first motor 16 penetrating through the top of the filling box 11. A rotating shaft 17 is fixedly connected to the output end of the first motor 16, and multiple stirring blades 18 are fixedly connected to the middle of the rotating shaft 17. A filter component 2 is installed in the middle of the conveying pipe 15, and an anti-clogging component 4 is installed at the end of the conveying pipe 15. The filter assembly 2 includes a rotating plate 21, which is rotatably connected to the middle of the conveying pipe 15. One end of the rotating plate 21 radially penetrates the middle of the conveying pipe 15, and a filter screen 22 is fixedly connected to the other end of the rotating plate 21. A first discharge port 23 is opened at the middle of the rotating plate 21 near the filter screen 22, and a second discharge port 24 is opened at the middle of the conveying pipe 15, with the first discharge port 23 and the second discharge port 24 corresponding to each other. A toothed groove 25 is opened at the end of the rotating plate 21 located outside the conveying pipe 15. Two sealing rings 20 are fixedly connected to the middle of the conveying pipe 15, and the two sealing rings 20 are respectively located on both sides of the end of the rotating plate 21 located outside the conveying pipe 15. A limit plate 26 is fixedly connected to the side wall of the toothed groove 25, and a stop block 27 is fixedly connected to the middle of the conveying pipe 15. A gear 28 is meshed in the middle of the toothed groove 25, and the output end of a second motor 29 is fixedly connected to the middle of the gear 28. The second motor 29 is mounted on the top of the filling table 1. A first fixing rod 201 is fixedly connected to the inner wall of the conveying pipe 15. The first fixing rod 201 is L-shaped, and a first scraper 202 is fixedly connected to the middle of the first fixing rod 201. A collection box 203 is installed on the top of the filling table 1, and the collection box 203 is located at the position corresponding to the second discharge port 24. The raw material to be filled enters the filling box 11 through the conveying pipe 15. First, when the raw material passes through the middle of the conveying pipe 15, impurities in the raw material are intercepted by the filter screen 22, allowing pure raw material liquid to enter the filling box 11. The control system turns on the first motor 16, and the output end of the first motor 16 drives the rotating shaft 17 to rotate. Multiple stirring blades 18 uniformly mix the material inside the filling box 11. The dispensing container is placed on the conveyor belt 10, and the drive system drives the conveyor belt 10 to run. When the dispensing container moves to below the filling head 13, the infrared receiver disconnects the power signal, causing the conveyor belt 10 to stop running. A certain amount of material is discharged through the filling head 13 by the quantitative module 12, and the material enters the container below for filling.When the material is no longer fed into the filling box 11 from the conveying pipe 15, the control system turns on the second motor 29. The output of the second motor 29 drives the gear 28 to rotate. The gear 28 simultaneously drives the rotating plate 21 to rotate through the tooth groove 25. During the rotation of the rotating plate 21, the material intercepted in the filter screen 22 is scraped off by the first scraper 202. When the first discharge port 23 and the second discharge port 24 coincide, the scraped impurities are discharged to the outside and collected in the collection box 203. When the limiting plate 26 rotates to the side of the stop block 27, it is limited by the stop block 27. The output of the second motor 29 rotates in the opposite direction to reset the rotating plate 21. Sealing strips are provided at the edges of the first discharge port 23 and the second discharge port 24. The sealing strips seal the rotating plate 21 and the conveying pipe 15. Two sealing rings 20 seal the end of the rotating plate 21 and the conveying pipe 15 to reduce material leakage. The above structure can automatically discharge the filtered impurities periodically, reducing the blockage of the filter screen 22 due to impurity accumulation after a period of use, and reducing the problem of reduced material flow rate during conveying caused by impurity accumulation. It eliminates the need to stop the machine to disassemble the conveying pipe 15 and the filter screen 22, reducing the tedious operation of periodic disassembly and cleaning, and also reducing the problem of contamination caused by impurities introduced during the disassembly of the conveying pipe 15 and the filter screen 22, effectively shortening maintenance time, reducing the frequency of manual cleaning, and reducing labor intensity.
[0028] like Figure 4 As shown, the adjusting assembly 3 includes multiple arc-shaped baffles 31, which are rotatably connected to the inner wall of the filling head 13 and are equidistantly distributed. A connecting shaft 32 is fixedly connected to the end of each arc-shaped baffle 31, and an adjusting rod 33 is rotatably connected to the middle of the connecting shaft 32. A threaded sleeve 35 is threadedly connected to the end of the filling head 13, and a rotating seat 34 is rotatably connected to the end of the threaded sleeve 35. The end of the adjusting rod 33 is rotatably connected to the middle of the rotating seat 34. During operation, the filling head 13 is adjusted according to the size of the bottle opening. When the bottle opening is small, the threaded sleeve 35 is rotated, and the rotating threaded sleeve 35 moves upward in the middle of the filling head 13. The rotating seat 34 rotates at the end of the threaded sleeve 35, and the threaded sleeve 35 drives the rotating seat 34 to move upward. Multiple adjusting rods 33 push one end of the arc-shaped baffle 31. The adjusting rods 33 rotate in the middle of the rotating seat 34 and the connecting shaft 32. The one end of the arc-shaped baffle 31 moves towards the center position with the end of the adjusting rods 33, thereby adjusting the amount of material discharged. Through the above structure, the discharge size of the filling head 13 can be quickly adjusted. The diameter can be reduced to fit small bottles, reducing liquid splashing, while the diameter can be enlarged to quickly fill large bottles, reducing filling time and controlling the liquid flow rate. This reduces the problem of having to stop the machine to change the traditional fixed filling port. It dynamically adapts to the filling rhythm of different bottle types, reduces downtime or speed fluctuations caused by changes in bottle type, and maintains production continuity.
[0029] like Figure 5As shown, the anti-clogging component 4 includes a third motor 41, which is fixedly connected to the top of the filling station 1. A rotating rod 42 is fixedly connected to the output end of the third motor 41. The rotating rod 42 penetrates the wall of the conveying pipe 15 and extends into the middle of the conveying pipe 15. The lower part of the rotating rod 42 is provided with a bidirectional threaded groove 43. A nut 44 is threadedly connected to the middle of the bidirectional threaded groove 43. Two connecting rods 45 are fixedly connected to the middle of the nut 44. The two connecting rods 45 are arranged in a mirror image. A second scraper 46 is fixedly connected to the end of the two connecting rods 45. The side wall of the second scraper 46 is in contact with the conveying pipe 15. A vertically arranged elastic rod 47 is fixedly connected to the middle of the connecting rod 45. A striking ball 48 is fixedly connected to the upper end of the elastic rod 47. During operation, as the material is discharged from the end of the conveying pipe 15 into the filling box 11, the material impacts the stirring blades 18 as they rotate, causing it to splash onto the inner wall of the end of the conveying pipe 15. This material is prone to remain on the inner wall of the conveying pipe 15. The third motor 41 is then activated, and its output drives the rotating rod 42 to rotate inside the conveying pipe 15. As the rotating rod 42 rotates, the nut 44 moves in the middle of the bidirectional threaded groove 43. At this time, the second scraper 46 scrapes away the residue at the end of the conveying pipe 15 through the connecting rod 45, and the remaining material falls back into the filling box 11. As the nut 44 continues to move upward, the two striking balls 48 collide with the inner wall of the conveying pipe 15, causing a slight vibration in the side wall of the conveying pipe 15. This shakes off some of the material adhering to the inner wall of the conveying pipe 15, keeping the inner wall of the end of the conveying pipe 15 clean. The above structure can effectively reduce the material adhering to the inner wall of the connection between the conveying pipe 15 and the filling box 11. The two striking balls 48 cause the loose residue to fall off through the vibration generated by the collision with the conveying pipe 15. The cooperation between the striking balls 48 and the second scraper 46 can reduce the residue on the inner wall of the conveying pipe 15, reduce the accumulation of residue that may cause the end of the conveying pipe 15 to narrow or become blocked, and reduce the production interruption caused by the blockage at the end of the conveying pipe 15.
[0030] like Figure 6 and Figure 7As shown, a guide block 5 is fixedly connected to the inner wall of the filling box 11, and two second fixing rods 51 are fixedly connected to the rotating shaft 17. The two second fixing rods 51 are arranged opposite each other and are respectively located at both ends of the rotating shaft 17. Springs 52 are fixedly connected to the ends of the two second fixing rods 51, and a third scraper 53 is fixedly connected between the ends of the two springs 52. The third scraper 53 is in contact with the inner wall of the filling box 11. During operation, as the stirring blade 18 rotates to mix the materials, the rotating shaft 17 drives the two second fixed rods 51 to rotate. The third scraper 53 scrapes away the raw material adhering to the inner wall of the filling box 11. When the third scraper 53 passes the guide block 5, the spring 52 is compressed and contracts by the guide block 5. The third scraper 53 moves along one side of the guide block 5. When the third scraper 53 passes the guide block 5, the elastic return of the spring 52 causes the third scraper 53 to impact the inner wall of the filling box 11 instantaneously. After the collision between the third scraper 53 and the filling box 11, the material scraped off the surface is shaken off. The third scraper 53 continues to rotate, cleaning the inner wall of the filling box 11 in real time. Through this structure, the third scraper 53 can peel off the mixed materials adhering to the inner wall of the filling box 11, achieving real-time cleaning and reducing the problem of uneven mixing caused by excessive accumulation of residue on the inner wall of the filling box 11.
[0031] like Figure 3 As shown, a protective cover 6 is fixed to the outer wall of the conveying pipe 15. The protective cover 6 is located outside the rotating plate 21 and the gear 28. During operation, the protective cover 6 isolates dust and impurities from the external environment. By protecting the gear groove 25 and the gear 28 through the protective cover 6, it can effectively reduce the accumulation and blockage of dust and impurities in the processing workshop by airflow, thereby reducing the problem of running jams and maintaining smooth rotation.
[0032] like Figure 1 and Figure 6 As shown, an observation plate 7, made of transparent glass, is fixedly connected to the middle of the filling tank 11. During operation, the mixing of the material inside the filling tank 11 can be observed in real time through the observation plate 7. This allows the operator to directly observe the dynamics of the material during the filling process and to observe whether the material inside the filling station 1 crystallizes or separates due to changes in temperature or pressure. This enables timely adjustment of parameters and reduces the problem of product defects.
[0033] The working principle of this molecular iodine mixing and filling equipment is as follows:
[0034] The raw material to be filled enters the filling box 11 through the conveying pipe 15. First, when the raw material passes through the middle of the conveying pipe 15, impurities in the raw material are intercepted by the filter screen 22, allowing pure raw material liquid to enter the filling box 11. The control system turns on the first motor 16, and the output end of the first motor 16 drives the rotating shaft 17 to rotate. Multiple stirring blades 18 uniformly mix the material inside the filling box 11. The dispensing container is placed on the conveyor belt 10, and the drive system drives the conveyor belt 10 to rotate. When the dispensing container moves to below the filling head 13, the infrared receiver disconnects the electrical signal, causing the conveyor belt 10 to stop. A certain amount of material is discharged through the filling head 13 under the control of the quantitative module 12, and the material enters the container below, thus filling it. When the material is no longer fed into the filling box 11 from the conveying pipe 15, the control system turns on the second motor 29. The output of the second motor 29 drives the gear 28 to rotate. The gear 28 simultaneously drives the rotating plate 21 to rotate through the tooth groove 25. During the rotation of the rotating plate 21, the material intercepted in the filter screen 22 is scraped off by the first scraper 202. When the first discharge port 23 and the second discharge port 24 coincide, the scraped impurities are discharged to the outside and collected in the collection box 203. When the limiting plate 26 rotates to the side of the stop block 27, it is limited by the stop block 27. The output of the second motor 29 rotates in the opposite direction to reset the rotating plate 21. Sealing strips are provided at the edges of the first discharge port 23 and the second discharge port 24. The sealing strips seal the rotating plate 21 and the conveying pipe 15. Two sealing rings 20 seal the end of the rotating plate 21 and the conveying pipe 15 to reduce material leakage. According to the size of the bottle opening of the dispensing container, the end of the filling head 13 is adjusted. When the bottle opening is small, the threaded sleeve 35 is rotated. The rotating threaded sleeve 35 moves upward in the middle of the filling head 13. The rotating seat 34 rotates at the end of the threaded sleeve 35. The threaded sleeve 35 drives the rotating seat 34 to move upward. Multiple adjusting rods 33 push one end of the arc-shaped baffle 31. The adjusting rod 33 rotates in the middle of the rotating seat 34 and the connecting shaft 32. One end of the arc-shaped baffle 31 moves towards the center position with the end of the adjusting rod 33, thereby adjusting the amount of material discharged. As the material is discharged into the filling box 11 through the end of the conveying pipe 15, the material splashes onto the inner wall of the end of the conveying pipe 15 due to the impact of the multiple stirring blades 18 as they rotate. This material is prone to leaving residue on the inner wall of the conveying pipe 15. The third motor 41 is then turned on, and its output drives the rotating rod 42 to rotate inside the conveying pipe 15. During the rotation of the rotating rod 42, the nut 44 moves in the middle of the bidirectional threaded groove 43. At this time, the second scraper 46 scrapes off the residue at the end of the conveying pipe 15 through the connecting rod 45, and the remaining material falls back into the filling box 11. As the nut 44 continues to move upward, the two striking balls 48 collide with the inner wall of the conveying pipe 15. This causes a slight vibration in the side wall of the conveying pipe 15, shaking off some of the material adhering to the inner wall of the conveying pipe 15, thus keeping the inner wall of the end of the conveying pipe 15 clean.During the mixing process of the stirring blade 18, the rotating shaft 17 drives the two second fixed rods 51 to rotate. The third scraper 53 scrapes off the raw material attached to the inner wall of the filling box 11. When the third scraper 53 passes the guide block 5, the spring 52 is squeezed and contracted by the guide block 5. The third scraper 53 moves with one side of the guide block 5. When the third scraper 53 passes the guide block 5, the elastic return of the spring 52 causes the third scraper 53 to impact the inner wall of the filling box 11 instantly. After the third scraper 53 collides with the filling box 11, the material scraped off the surface is shaken off. The third scraper 53 continues to rotate, cleaning the inner wall of the filling box 11 in real time. The protective cover 6 isolates dust and impurities in the external environment. The protective cover 6 protects the tooth groove 25 and gear 28. During the filling process of molecular iodine material, the mixing of materials inside the filling box 11 is observed in real time through the observation plate 7.
[0035] 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. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A molecular iodine mixing and filling apparatus comprising a filling station (1), characterized in that: A conveyor belt (10) is installed in the middle of the filling platform (1); a filling box (11) is installed on the top of the filling platform (1), a quantitative module (12) is installed at the bottom of the filling box (11), a filling head (13) is fixedly connected to the bottom of the quantitative module (12), and an adjustment component (3) is installed in the middle of the filling head (13); a fixing frame (14) is fixedly connected to the outer wall of the filling box (11), a conveying pipe (15) is fixedly connected to the top of the filling box (11), and the fixing frame (14) is fixedly connected to the middle of the conveying pipe (15); a first motor (16) is installed on the top of the filling box (11), the output end of the first motor (16) passes through the top of the filling box (11), a rotating shaft (17) is fixedly connected to the output end of the first motor (16), and multiple stirring blades (18) are fixedly connected to the middle of the rotating shaft (17); a filter component (2) is installed in the middle of the conveying pipe (15); and an anti-clogging component (4) is installed at the end of the conveying pipe (15).
2. A molecular iodine mixing and filling apparatus according to claim 1, wherein: The filter assembly (2) includes a rotating plate (21), which is rotatably connected to the middle of the conveying pipe (15). One end of the rotating plate (21) passes through the middle of the conveying pipe (15), and a filter screen (22) is fixedly connected to the other end of the rotating plate (21). A first discharge port (23) is provided at the middle end of the rotating plate (21) near the filter screen (22), and a second discharge port (24) is provided at the middle of the conveying pipe (15). The first discharge port (23) and the second discharge port (24) are positioned correspondingly. A toothed groove (25) is provided at the end of the rotating plate (21) located outside the conveying pipe (15), and two sealing rings (20) are fixedly connected to the middle of the conveying pipe (15). The toothed groove (25) is fixed to the side wall of the rotating plate (21); a limit plate (26) is fixed to the side wall of the toothed groove (25); a stop block (27) is fixed to the middle of the conveying pipe (15); a gear (28) is meshed in the middle of the toothed groove (25); the output end of the second motor (29) is fixed to the middle of the gear (28); the second motor (29) is installed on the top of the filling platform (1); a first fixing rod (201) is fixed to the inner side wall of the conveying pipe (15); the first fixing rod (201) is L-shaped; a first scraper (202) is fixed to the middle of the first fixing rod (201); a collection box (203) is installed on the top of the filling platform (1); the collection box (203) is located at the position corresponding to the second discharge port (24).
3. A molecular iodine mixing and filling apparatus according to claim 1, wherein: The adjustment assembly (3) includes multiple arc-shaped baffles (31), which are rotatably connected to the inner wall of the filling head (13) and are equidistantly distributed. A connecting shaft (32) is fixedly connected to the end of the arc-shaped baffle (31), and an adjustment rod (33) is rotatably connected to the middle of the connecting shaft (32). A threaded sleeve (35) is threadedly connected to the end of the filling head (13), and a rotating seat (34) is rotatably connected to the end of the threaded sleeve (35). The end of the adjustment rod (33) is rotatably connected to the middle of the rotating seat (34).
4. The molecular iodine mixing and filling apparatus according to claim 1, wherein: The anti-clogging component (4) includes a third motor (41), which is fixed to the top of the filling station (1). A rotating rod (42) is fixed to the output end of the third motor (41). The rotating rod (42) penetrates the wall of the conveying pipe (15) and extends into the middle of the conveying pipe (15). The lower part of the rotating rod (42) is provided with a bidirectional threaded groove (43). A nut (44) is threadedly connected to the middle of the bidirectional threaded groove (43). Two connecting rods (45) are fixed to the middle of the nut (44). The two connecting rods (45) are arranged in a mirror image. A second scraper (46) is fixed to the end of the two connecting rods (45). The side wall of the second scraper (46) is in contact with the conveying pipe (15). An elastic rod (47) is fixed to the middle of the connecting rod (45). A striking ball (48) is fixed to the end of the elastic rod (47).
5. The molecular iodine mixing and filling apparatus according to claim 1, wherein: A guide block (5) is fixed to the inner wall of the filling box (11); two second fixing rods (51) are fixed to the rotating shaft (17), the two second fixing rods (51) are arranged opposite to each other, and the two second fixing rods (51) are respectively arranged at both ends of the rotating shaft (17); springs (52) are fixed to the ends of the two second fixing rods (51), and a third scraper (53) is fixed between the ends of the two springs (52), and the third scraper (53) is in contact with the inner wall of the filling box (11).
6. A molecular iodine mixing and filling apparatus as claimed in claim 1, wherein: A protective cover (6) is fixed to the outer wall of the conveying pipe (15), and the protective cover (6) is located outside the rotating plate (21) and the gear (28).
7. A molecular iodine mixing and filling apparatus as claimed in claim 1, wherein: An observation plate (7) is fixedly connected to the middle of the filling box (11), and the observation plate (7) is made of transparent glass.