A buffer positioning type conveying track structure of glass vinegar bottles

By combining a buffer positioning conveyor track structure with a high-temperature sterilizer, the problems of glass vinegar bottles deviating from the track and colliding during the conveying process are solved, achieving stable conveying and thorough sterilization. It is adaptable to various bottle types and improves the safety and hygiene of the conveying process.

CN224466717UActive Publication Date: 2026-07-07SHANGHAI BEAU IDEAL FERMENTATION CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI BEAU IDEAL FERMENTATION CO LTD
Filing Date
2025-07-14
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Glass vinegar bottles are prone to deviating from the track due to inertia during transportation, which increases the risk of collisions between bottles. Furthermore, the existing conveyor track makes it difficult to precisely control the speed, affecting production capacity and bottle integrity.

Method used

The system employs a buffer positioning conveyor track structure, which uses a combination of a second gear, rack, clamping plate, and suction cup to ensure that the glass vinegar bottle remains in the correct position during transport. It also incorporates a high-temperature sterilizer and an infrared sensor to achieve secondary sterilization.

Benefits of technology

It improves the stability and safety of glass vinegar bottle transportation, adapts to various bottle types, and ensures bottle hygiene and safety through high-temperature sterilization and disinfection.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224466717U_ABST
    Figure CN224466717U_ABST
Patent Text Reader

Abstract

The application relates to a buffer positioning type conveying track structure of a glass vinegar bottle and relates to the technical field of glass bottle conveying, which comprises a conveyor main body, a plurality of mounting frames are fixedly connected to the middle part of a conveying belt on the outer wall of the conveyor main body, a second gear is rotationally connected to the top of each of the mounting frames, two second racks in opposite directions are slidingly connected to the upper surfaces of the mounting frames respectively, wherein the two opposite second racks are engaged with the second gear, a clamping piece is fixedly connected to one end of each of the second racks, a bolt is slidingly connected to one side of each of the mounting frames, and a cylindrical rod is fixedly connected to the top and middle part of each of the second gears. The application has the purpose of ensuring that the bottles keep correct positions in the conveying process, the glass vinegar bottles are more stable after being placed, the stability of the conveying process is improved, and the device can adapt to bottles of various sizes and types for the purpose of transportation.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application relates to glass bottle conveying, specifically a buffer positioning conveying track structure for glass vinegar bottles. Background Technology

[0002] Glass vinegar bottles are brittle and have poor impact resistance. Compared to other packaging containers such as plastic bottles, glass is more prone to breakage when subjected to external impact. In the manufacturing process of glass vinegar bottles, the conveying stage is a crucial link. Currently, conventional conveyor tracks can cause even small impacts to crack or shatter glass vinegar bottles. Furthermore, the speed of the conveyor track is often difficult to control precisely. Too high a speed can cause the bottles to wobble and collide due to inertia; too low a speed will affect production capacity. Additionally, the small spacing between bottles on the track increases the risk of collisions. Even a slight collision between two adjacent bottles due to speed differences can cause a tiny crack in one bottle. This crack may widen during subsequent filling and sealing processes, rendering the bottle unusable. Therefore, developing a buffer-positioning conveyor track structure for glass vinegar bottles is urgently needed.

[0003] Currently, when transporting glass vinegar bottles, the bottles are prone to shaking due to inertia during transportation, which can cause them to deviate from the track during transport, thus increasing the risk of collisions between the bottles. Utility Model Content

[0004] In view of the above-mentioned related technologies, the purpose of this application is to provide a buffer positioning conveying track structure for glass vinegar bottles, which ensures that the bottles always remain in the correct position during the conveying process, and solves the problem that glass vinegar bottles may deviate from the track during the conveying process, thereby increasing the risk of collision between bottles.

[0005] The buffer positioning conveyor track structure for a glass vinegar bottle provided in this application adopts the following technical solution: it includes a conveyor body, and multiple mounting brackets are fixedly connected to the middle of the outer wall of the conveyor belt of the conveyor body. The top of each of the multiple mounting brackets is rotatably connected to a second gear. Two second racks facing opposite directions are slidably connected to the upper surface of each of the multiple mounting brackets, wherein the two opposing second racks mesh with the second gear. A clamping piece is fixedly connected to one end of each of the multiple second racks. A pin is slidably connected to one side of each of the multiple mounting brackets. A cylindrical rod is fixedly connected to the middle of the top of each of the multiple second gears. Multiple grooves arranged in a circular array are opened on the outer wall of each of the multiple cylindrical rods, and the pins can be engaged with the grooves. A placement tray is fixedly connected to the top of each of the multiple cylindrical rods. A support pad is fixedly connected to the middle of the top of each of the multiple placement trays. Multiple suction cups arranged in a circular array are fixedly connected to the top of each of the multiple placement trays.

[0006] By adopting the above technical solution, through the setting of the second gear, the second rack, the clamping plate, and the suction cup, the bottom of the glass vinegar bottle can be made to adhere to the pad during use. The bottom of the glass vinegar bottle is then attracted to the suction cup. Subsequently, the worker holds the outer edge of the tray and rotates it, causing the second gear and the second rack to mesh. At this time, the clamping plate at one end of the second rack clamps or releases the glass vinegar bottle, achieving the purpose of ensuring that the bottle maintains the correct position during transportation. Moreover, the glass vinegar bottle is placed more stably, thereby improving the stability of the transportation process. At the same time, this device can adapt to the transportation of bottles of various sizes and types.

[0007] Preferably, side plates are fixedly connected to both sides of the main body of the transport machine, and a common high-temperature sterilizer is fixedly connected to the top center of the two side plates.

[0008] By adopting the above technical solution, the glass vinegar bottles are sterilized a second time using high temperature, achieving the goal of spraying disinfectant on the outer wall of each glass vinegar bottle and performing a second high-temperature sterilization.

[0009] Preferably, a mounting plate is fixedly connected to the top of the outer wall of the high-temperature sterilizer, and an electric reciprocating telescopic rod is fixedly connected to the middle of one side of the mounting plate. A first rack is fixedly connected to the output end of the electric reciprocating telescopic rod.

[0010] By adopting the above technical solution, the electric reciprocating telescopic rod reciprocates on one side, then the first rack and the first gear mesh, and then the sterilization nozzle twists its angle to make the disinfectant spray more evenly on the outer wall of the glass vinegar bottle.

[0011] Preferably, a first gear is rotatably connected to the middle of the upper surface of the mounting plate, and two symmetrical sterilization nozzles are rotatably connected to the middle of the lower surface of the mounting plate. The sterilization nozzles and the first gear are fixedly connected by a rod.

[0012] By adopting the above technical solution, the sterilization nozzle and the first gear can achieve synchronous rotation.

[0013] Preferably, the first gear meshes with the first rack, and a liquid storage tank is fixedly connected to the top of one side of each of the two side plates.

[0014] By adopting the above technical solution, the storage of disinfectant solution is made more convenient to use.

[0015] Preferably, a pump body is fixedly connected to one side of each of the two liquid storage tanks, and the output end of each of the two pump bodies is connected to a soft water pipe.

[0016] By adopting the above technical solution, the flexible water pipe can adapt to the twisting of the sterilization nozzle when spraying disinfectant.

[0017] Preferably, the two ends of the soft water pipes are respectively connected to the liquid storage tank and the sterilization nozzle, and the two side plates are fixedly connected to opposite sides with symmetrical infrared sensors. The infrared sensors are electrically connected to the pump body and the electric reciprocating telescopic rod.

[0018] By adopting the above technical solution, when the infrared sensor scans and detects a glass vinegar bottle passing by, the electric reciprocating telescopic rod and pump body are activated, thereby providing power support for the device.

[0019] In summary, this application includes at least one of the following beneficial technical effects:

[0020] This buffer positioning conveyor track structure for glass vinegar bottles, through the arrangement of a second gear, a second rack, a clamping plate, and a suction cup, allows the bottom of the glass vinegar bottle to adhere to the support pad during use. The bottom of the bottle adheres to the suction cup, and then the worker holds the outer edge of the tray and rotates it, causing the second gear and second rack to mesh. At this point, the clamping plate at one end of the second rack clamps or releases the glass vinegar bottle, ensuring the bottle maintains the correct position during transport and making the bottle more stable, thus improving the stability of the transport process. Furthermore, this device can accommodate various bottle sizes and types for transport.

[0021] This buffer positioning conveyor track structure for glass vinegar bottles, through the setup of a high-temperature sterilizer, infrared sensor, pump, and sterilization nozzle, activates the electric reciprocating telescopic rod and pump when the infrared sensor detects a glass vinegar bottle passing by. During the few seconds the pump is activated, disinfectant solution is drawn from the storage tank and introduced into the sterilization nozzle through a flexible water pipe, causing the nozzle to spray forward. Simultaneously, the electric reciprocating telescopic rod reciprocates on one side, engaging the first rack and first gear, causing the sterilization nozzle to rotate. As the glass vinegar bottle continues to be transported past the high-temperature sterilizer, the sterilizer bakes the bottle, accelerating the drying of the disinfectant solution and achieving secondary sterilization using high temperature. This ensures that the outer wall of each passing glass vinegar bottle is sprayed with disinfectant solution and undergoes secondary high-temperature sterilization, making the sterilization of the glass vinegar bottles more thorough and ensuring health during subsequent use. Attached Figure Description

[0022] Figure 1 This is a frontal view illustration of the present application;

[0023] Figure 2 This is a side view diagram of this application;

[0024] Figure 3 This is a cross-sectional view of this application;

[0025] Figure 4 This is a schematic diagram of the layout for this application;

[0026] Figure 5 For this application Figure 1 Diagram A in the middle.

[0027] In the picture:

[0028] 1. Conveyor body; 2. Side plate; 3. High-temperature sterilizer; 4. Mounting plate; 5. Electric reciprocating telescopic rod; 6. First rack; 7. First gear; 8. Sterilization nozzle; 9. Storage tank; 10. Pump body; 11. Soft water pipe; 12. Infrared sensor; 13. Mounting bracket; 14. Second gear; 15. Second rack; 16. Pin; 17. Placement tray; 18. Pad; 19. Suction cup; 20. Clamping plate; 21. Cylindrical rod. Detailed Implementation

[0029] The following is in conjunction with the appendix Figure 1 -Appendix Figure 5 This application will be described in further detail below.

[0030] Example 1: A buffer positioning conveyor track structure for a glass vinegar bottle, referring to... Figure 1 , Figure 4 , Figure 5The system includes a transport aircraft body 1. Multiple mounting brackets 13 are fixedly connected to the middle of the transmission belt on the outer wall of the transport aircraft body 1. A second gear 14 is rotatably connected to the top of each mounting bracket 13. Two second racks 15 facing opposite directions are slidably connected to the upper surface of each mounting bracket 13, with the two opposing second racks 15 meshing with the second gear 14. A clamping piece 20 is fixedly connected to one end of each second rack 15. A pin 16 is slidably connected to one side of each mounting bracket 13. A cylindrical rod 21 is fixedly connected to the middle of the top of each second gear 14. Multiple grooves arranged in a circular array are opened on the outer wall of each cylindrical rod 21, and the pins 16 can engage with the grooves. A placement tray 17 is fixedly connected to the top of each cylindrical rod 21. Each of the top and center sections is fixedly connected to a support pad 18. Multiple suction cups 19 arranged in a circular array are fixedly connected to the top of multiple placement trays 17. Through the arrangement of the second gear 14, the second rack 15, the clamping plate 20, and the suction cups 19, the bottom of the glass vinegar bottle can be made to adhere to the support pad 18 during use, with the bottom of the glass vinegar bottle adsorbed to the suction cups 19. Then, the worker holds the outer edge of the placement tray 17 and rotates it, causing the second gear 14 and the second rack 15 to mesh. At this time, the clamping plate 20 at one end of the second rack 15 clamps or releases the glass vinegar bottle, achieving the purpose of ensuring that the bottle maintains the correct position during transportation. Moreover, the glass vinegar bottle is placed more stably, thereby improving the stability of the transportation process. At the same time, this device can adapt to the transportation of various sizes and types of bottles.

[0031] Example 2: A buffer positioning conveyor track structure for a glass vinegar bottle, referring to... Figure 1 , Figure 2 , Figure 3The conveyor body 1 has side plates 2 fixedly connected to both sides. A common high-temperature sterilizer 3 is fixedly connected to the top center of the two side plates 2. A mounting plate 4 is fixedly connected to the top of the outer wall of the high-temperature sterilizer 3. An electric reciprocating telescopic rod 5 is fixedly connected to the center of one side of the mounting plate 4. A first rack 6 is fixedly connected to the output end of the electric reciprocating telescopic rod 5. A first gear 7 is rotatably connected to the center of the upper surface of the mounting plate 4. Two symmetrical sterilization nozzles are rotatably connected to the center of the lower surface of the mounting plate 4. 8. The sterilization nozzle 8 and the first gear 7 are fixedly connected by a rod. The first gear 7 meshes with the first rack 6. A liquid storage tank 9 is fixedly connected to the top of one side of each of the two side plates 2. A pump body 10 is fixedly connected to one side of each of the two liquid storage tanks 9. The output ends of each of the two pump bodies 10 are connected to a flexible water pipe 11. The two ends of the two flexible water pipes 11 are respectively connected to the liquid storage tank 9 and the sterilization nozzle 8. A symmetrical infrared sensor 12 is fixedly connected to the opposite sides of each of the two side plates 2. The infrared sensor 12 is connected to the pump... The body 10 and the electric reciprocating telescopic rod 5 are electrically connected. Through the setup of the high-temperature sterilizer 3, infrared sensor 12, pump body 10, and sterilization nozzle 8, during use, when the infrared sensor 12 detects a glass vinegar bottle passing by, the electric reciprocating telescopic rod 5 and pump body 10 are activated. During the few seconds that the pump body 10 is activated, it draws disinfectant from the storage tank 9 and introduces it into the sterilization nozzle 8 through the flexible water pipe 11, causing the sterilization nozzle 8 to spray forward. Simultaneously, the electric reciprocating telescopic rod 5 moves to one side... The retraction and extension cause the first rack 6 and the first gear 7 to mesh. Then, the sterilization nozzle 8 twists its angle. As the glass vinegar bottle continues to be transported through the high-temperature sterilizer 3, the high-temperature sterilizer 3 bakes the glass vinegar bottle to accelerate the drying of the disinfectant solution and achieves secondary sterilization of the glass vinegar bottle using high temperature. This ensures that the outer wall of each glass vinegar bottle is sprayed with disinfectant solution and subjected to secondary high-temperature sterilization, making the sterilization of the glass vinegar bottle more thorough and ensuring health when using the glass vinegar bottle in the future.

[0032] The implementation principle of this application embodiment is as follows: First, disinfectant is placed inside the storage tank 9, and the main body of the conveyor 1 is turned on. Then, the worker quickly places the glass vinegar bottle into multiple placement trays 17, ensuring that the bottom of the glass vinegar bottle is in contact with the pad 18, where the bottom of the glass vinegar bottle is attracted to the suction cup 19. Subsequently, the worker holds the outer edge of the placement tray 17 and rotates it, causing the second gear 14 and the second rack 15 to mesh. At this time, the clamping piece 20 at one end of the second rack 15 clamps or releases the glass vinegar bottle, while the pin 16 is inserted into the groove on the outer wall of the cylindrical rod 21, completing the clamping and locking of the glass vinegar bottle. This adapts to various sizes and types of glass vinegar bottles and ensures stability during transportation. Then, the high-temperature sterilizer 3 and the infrared sensor 12 are turned on, allowing the infrared light to penetrate the glass vinegar bottle. Sensor 12 scans the passing glass vinegar bottles. When the infrared sensor 12 detects a glass vinegar bottle passing by, it activates the electric reciprocating telescopic rod 5 and the pump body 10. During the few seconds that the pump body 10 is activated, it draws out the disinfectant from the storage tank 9 and introduces it into the sterilization nozzle 8 through the soft water pipe 11, causing the sterilization nozzle 8 to spray forward. At the same time, the electric reciprocating telescopic rod 5 reciprocates on one side, causing the first rack 6 and the first gear 7 to mesh. Subsequently, the sterilization nozzle 8 twists its angle, making the disinfectant sprayed on the outer wall of the glass vinegar bottle more even. As the glass vinegar bottle continues to be transported through the high-temperature sterilizer 3, the high-temperature sterilizer 3 bakes the glass vinegar bottle to accelerate the drying of the disinfectant and achieves the effect of secondary sterilization of the glass vinegar bottle using high temperature.

[0033] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be covered within the scope of protection of this application.

Claims

1. A buffer positioning conveyor track structure for glass vinegar bottles, comprising a conveyor body (1), characterized in that: Multiple mounting brackets (13) are fixedly connected to the middle of the transmission belt on the outer wall of the main body (1) of the transport machine. A second gear (14) is rotatably connected to the top of each of the mounting brackets (13). Two second racks (15) facing opposite directions are slidably connected to the upper surfaces of the mounting brackets (13). The two opposing second racks (15) mesh with the second gears (14). A clamping piece (20) is fixedly connected to one end of each of the second racks (15). One side of each of the mounting brackets (13) is slidably connected to the second gear (14). A pin (16) is connected to the top center of a plurality of second gears (14), and a cylindrical rod (21) is fixedly connected to the top center of each of the plurality of cylindrical rods (21). The outer wall of the plurality of cylindrical rods (21) has a plurality of grooves arranged in a ring array, and the pin (16) can be fitted into the grooves. A placement tray (17) is fixedly connected to the top of each of the plurality of cylindrical rods (21), and a support pad (18) is fixedly connected to the top center of each of the plurality of placement trays (17). A plurality of suction cups (19) arranged in a ring array are fixedly connected to the top of the plurality of placement trays (17).

2. The buffer positioning conveyor track structure for a glass vinegar bottle according to claim 1, characterized in that: Both sides of the main body (1) of the transport aircraft are fixedly connected to side plates (2), and a common high-temperature sterilizer (3) is fixedly connected to the top center of the two side plates (2).

3. The buffer positioning conveyor track structure for a glass vinegar bottle according to claim 2, characterized in that: The high-temperature sterilizer (3) has an installation plate (4) fixedly connected to the top of its outer wall. An electric reciprocating telescopic rod (5) is fixedly connected to the middle of one side of the installation plate (4). A first rack (6) is fixedly connected to the output end of the electric reciprocating telescopic rod (5).

4. The buffer positioning conveyor track structure for a glass vinegar bottle according to claim 3, characterized in that: The upper surface of the mounting plate (4) is rotatably connected to a first gear (7), and the lower surface of the mounting plate (4) is rotatably connected to two symmetrical sterilization nozzles (8). The sterilization nozzles (8) and the first gear (7) are fixedly connected by a rod.

5. The buffer positioning conveyor track structure for a glass vinegar bottle according to claim 4, characterized in that: The first gear (7) meshes with the first rack (6), and a liquid storage tank (9) is fixedly connected to the top of one side of each of the two side plates (2).

6. The buffer positioning conveyor track structure for a glass vinegar bottle according to claim 5, characterized in that: A pump body (10) is fixedly connected to one side of each of the two liquid storage tanks (9), and the output end of each of the two pump bodies (10) is connected to a soft water pipe (11).

7. The buffer positioning conveyor track structure for a glass vinegar bottle according to claim 6, characterized in that: The two soft water pipes (11) are connected to the storage tank (9) and the sterilization nozzle (8) at both ends respectively. The two side plates (2) are fixedly connected to the opposite sides with symmetrical infrared sensors (12). The infrared sensors (12) are electrically connected to the pump body (10) and the electric reciprocating telescopic rod (5).