A transfer device for finished product packaging of medicine boxes

By designing a finished medicine box packaging transfer device, which adopts a dynamic lifting partition plate and a modular insert shaft structure, the problems of low stacking efficiency and poor process coordination during the transfer of finished medicine box packaging are solved, realizing efficient and automated transfer and sealing, and adapting to the needs of multi-specification packaging.

CN224409802UActive Publication Date: 2026-06-26ZHONGMEI HUAYI (HEBEI) PHARM CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHONGMEI HUAYI (HEBEI) PHARM CO LTD
Filing Date
2025-08-22
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

In the current process of transporting finished drug box packaging, the stacking efficiency is low and the process coordination is poor, making it difficult to meet the flexible production needs of multi-specification packaging, and there is also the problem of loose stacks caused by manual operation.

Method used

A transfer device for finished medicine box packaging was designed, including a conveying mechanism, a stacking mechanism, and a sealing mechanism. It adopts a dynamic lifting partition system and a modular insert shaft-insertion structure to realize continuous automatic stacking and seamless sealing of packaging boxes, adapting to packaging needs of different specifications.

Benefits of technology

It enables efficient and automated transfer and sealing of medicine boxes, improves production efficiency, reduces the labor intensity of operators, adapts to the needs of multi-specification packaging, reduces box scratches and shock damage, and provides an integrated and efficient solution.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of transport equipment of medicine box finished product packaging, belong to transport equipment technical field, including sequentially arranged conveying mechanism, stacking mechanism and film sealing mechanism;The stacking mechanism includes guide plate and the shaft plate slidingly connected with the guide plate by guide rail, the shaft plate is connected with spacer plate by clamping, and the second telescopic link is arranged below the shaft plate.The guide plate is arranged at the both sides of the spacer plate, and the guide rail is longitudinally penetrated on the guide plate.The spacer plate is provided with the ball that is conducive to packaging movement, and the side of the spacer plate away from the shaft plate is provided as slope face.The utility model solves the problem of low stacking efficiency and poor process synergy in the prior art by the above structure, integrated design, self-adapting stacking, improve production efficiency.
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Description

Technical Field

[0001] This utility model relates to the field of transfer equipment technology, and in particular to a transfer device for finished medicine box packaging. Background Technology

[0002] Boxed medicines are typically stacked into several boxes before being sealed in plastic and transported. However, the current process for transporting finished drug packaging faces the following problems: insufficient stacking efficiency and flexibility; traditional methods rely on manual palletizing or fixed partition equipment, which are slow and time-consuming to changeover and adjust, making it difficult to meet the flexible production needs of multi-specification packaging; poor process coordination, as stacked packages need to be manually transferred to an independent sealing station, which can easily lead to loose stacks. While existing automation solutions (such as robotic arm palletizing) have improved efficiency to some extent, they are still limited by high costs and adaptability. There is an urgent need for an integrated device that combines dynamic stacking, low-loss transport, and seamless sealing.

[0003] To solve the above problems, a transfer device for finished drug box packaging is needed. Utility Model Content

[0004] The purpose of this invention is to provide a transfer device for finished medicine box packaging, which solves the problems of low stacking efficiency and poor process coordination in the prior art. It features an integrated design, adaptive stacking, and improved production efficiency.

[0005] To achieve the above objectives, this utility model provides a transfer device for finished drug box packaging, including a conveying mechanism, a stacking mechanism, and a sealing mechanism arranged in sequence; the stacking mechanism includes a guide plate and a shaft plate slidably connected to the guide plate via a guide rail, a partition plate is snapped onto the shaft plate, and a second telescopic rod is provided below the shaft plate.

[0006] Preferably, the conveying mechanism includes a conveyor belt, a roller conveyor belt, drive wheels, and a push rod. The roller conveyor belt is located at the tail end of the conveyor belt, the drive wheels are located above the roller conveyor belt, and there are several drive wheels that rotate at the same speed. The push rod is connected to a first telescopic rod.

[0007] Preferably, the guide plate is disposed on both sides of the partition plate, and the guide rail extends longitudinally through the guide plate.

[0008] Preferably, the partition plate is provided with rolling balls that facilitate packaging movement, and the side of the partition plate away from the shaft plate is sloped.

[0009] Preferably, the tail end of the partition plate is provided with a insertion shaft, and the shaft plate is provided with a plurality of insertion holes, the diameter of which matches the diameter of the insertion shaft.

[0010] Therefore, the above-mentioned transfer equipment for finished medicine box packaging has the following beneficial effects:

[0011] 1. This utility model employs a dynamically lifting partition system to achieve continuous automatic stacking of packaging boxes. Through a modular shaft-hole structure, the partition spacing can be adjusted quickly, perfectly adapting to various packaging sizes. The partition integrates a ball bearing and a sloped guide design, reducing box scratches and drug damage, ensuring seamless collaboration throughout the entire process. The stacked packages are directly pushed into the existing sealing mechanism by a push rod, providing an integrated and efficient solution.

[0012] 2. The device has a compact and simple structure, occupies little space, and is easy to install and use. At the same time, the device is simple and convenient to operate, reducing the labor intensity of operators, improving production efficiency, and can be connected to other equipment on the production line to achieve automated control, further improving production efficiency and the reliability of the device.

[0013] The technical solution of this utility model will be further described in detail below with reference to the accompanying drawings and embodiments. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the structure of a transfer device for finished medicine box packaging according to the present invention;

[0015] Figure 2 This is a schematic diagram of the stacking mechanism of a transfer device for finished medicine box packaging according to the present invention;

[0016] Labeling instructions

[0017] 1. Conveyor belt; 2. Drive motor; 3. Drive wheel; 4. Roller conveyor belt; 5. First telescopic rod; 6. Push rod; 7. Guide plate; 8. Insert shaft; 9. Separator plate; 10. Ball; 11. Second telescopic rod; 12. Sealing mechanism; 13. Guide rail; 14. Shaft plate; 15. Insertion hole. Detailed Implementation

[0018] The technical solution of this utility model will be further described below with reference to the accompanying drawings and embodiments.

[0019] Unless otherwise defined, the technical or scientific terms used in this utility model shall have the ordinary meaning understood by one of ordinary skill in the art to which this utility model pertains. The terms "first," "second," and similar terms used in this utility model do not indicate any order, quantity, or importance, but are merely used to distinguish different components. Terms such as "comprising" or "including" mean that the element or object preceding the word encompasses the elements or objects listed following the word and their equivalents, without excluding other elements or objects. Terms such as "connected" or "linked" are not limited to physical or mechanical connections, but can include electrical connections, whether direct or indirect. Terms such as "upper," "lower," "left," and "right" are used only to indicate relative positional relationships; when the absolute position of the described object changes, the relative positional relationship may also change accordingly.

[0020] The specific connection methods for each component all adopt conventional methods such as bolts, rivets, and welding, which are mature technologies in the existing field. The machinery, parts, and equipment all adopt conventional models in the existing technology. In addition, the circuit connections adopt conventional connection methods in the existing technology, which will not be described in detail here. The component models mentioned in this article are all common models in the existing technology and can be replaced according to actual needs.

[0021] As per the instruction manual Figure 1-2 As shown, this utility model provides a transfer device for finished medicine box packaging, including a conveying mechanism, a stacking mechanism, and a sealing mechanism 12 arranged in sequence. The sealing mechanism 12 is equipped with existing vertical sealing machines, strapping sealing machines, and mechanical automatic strapping machines, which can automatically complete continuous or single strapping operations without manual strapping.

[0022] The stacking mechanism includes a guide plate 7 and a shaft plate 14 slidably connected to the guide plate 7 via a guide rail 13. A partition plate 9 is snapped onto the shaft plate 14, and a second telescopic rod 11 is located below the shaft plate 14. The guide plate 7 is a vertically shaped metal plate in the shape of a "∏" and is distributed on both sides of the partition plate 9 to form a symmetrical guide structure. A guide rail 13 with grooves and rollers is longitudinally arranged inside, allowing the shaft plate 14 to move linearly along the guide rail 13 without deviation during movement. The partition plate 9 is used to separate the plate-shaped components of the stacked packaging boxes and is made of lightweight composite material to ensure alignment of the packaging boxes during stacking. The second telescopic rod 11 is the actuator that drives the shaft plate 14 to rise and fall. It can be implemented using a cylinder or an electric push rod. Its telescopic end is fixedly connected to the bottom of the shaft plate 14, and the height of each rise and fall is adjusted according to the height of the medicine box, which is the height of a single medicine box plus the thickness of the partition plate 9.

[0023] The divider 9 is equipped with rolling balls 10 that facilitate packaging movement. The side of the divider 9 away from the shaft plate 14 is sloped. The rolling balls 10 are omnidirectional ball bearings embedded in the surface of the divider 9, with a diameter of 1mm, which reduce the frictional resistance between the packaging box and the divider 9 through rolling contact. The sloped surface is an inclined guide surface at the edge of the divider 9, guiding the box to slide naturally into the stacking area and avoiding jamming or displacement caused by right-angled edges.

[0024] The separator plate 9 has a shaft 8 at its tail end, and the shaft plate 14 has several insertion holes 15. The diameter of the insertion holes 15 and the outer diameter of the shaft 8 form a clearance fit, allowing the shaft 8 to be quickly inserted or removed and achieving a stable fit. The separator plate 9 and the shaft plate 14 are combined through the connection of the shaft 8 and the insertion holes 15. The separator plate 9 achieves modular installation through the cooperation of the shaft 8 and the insertion holes 15, so that the spacing of the separator plate 9 can be adjusted without disassembling the entire structure. Only by changing the insertion position of the shaft 8 into the insertion hole 15 can the fit be completed. The insertion holes 15 are distributed at fixed intervals on the shaft plate 14 to form standardized adjustment units. When replacing or maintaining the separator plate 9, there is no need to disassemble the guide rail 13 or the guide plate 7. Only by disconnecting the connection between the shaft 8 and the insertion hole 15 can the separator plate 9 be removed individually, which significantly shortens the changeover and machine adjustment time and can adapt to the stacking of medicine boxes of different specifications.

[0025] The conveying mechanism, used to transfer packaging boxes from the upstream process to the stacking station, includes a conveyor belt 1, a roller conveyor belt, drive wheels 3, and a push rod 6. The conveyor belt 1 is rotated by a drive motor 2. The roller conveyor belt is located at the tail end of the conveyor belt 1, and several drive wheels 3 are located above the roller conveyor belt, rotating at the same speed. The push rod 6 is connected to a first telescopic rod 5. The roller conveyor belt is a conveying device composed of multiple parallel rolling cylinders, used to connect the conveyor belt 1 and the stacking mechanism for material transfer. The drive wheels 3 apply uniform downward pressure to the packaging boxes to prevent them from shifting. The push rod 6 and the first telescopic rod 5 are used to push the packaging boxes at the end of the roller conveyor belt into the gaps of the partition plates 9 of the stacking mechanism.

[0026] Specifically, the operator inserts the partition plate 9 and shaft 8 into the corresponding insertion hole 15 to adjust the spacing. The conveyor mechanism transports the packaging boxes to the stacking area. The second telescopic rod 11 pushes the shaft plate 14 up along the guide plate 7 and guide rail 13 to the height of a single packaging box, allowing the single packaging box to enter the position of the first partition plate 9. Then, the first telescopic rod 5 continues to rise to the height of a single packaging box, and subsequent packaging boxes enter the corresponding partition plates 9 in sequence. Guided by the roller ball 10, the packaging boxes slide down the slope into the stacking station. After being grouped, the first telescopic rod 5 drives the push rod 6 to move forward, and the medicine boxes slide forward along the partition plate 9, pushing the entire stack of products into the sealing mechanism 12. After sealing, the entire stack of products is horizontally removed and stacked on the subsequent platform of the sealing mechanism 12. The first telescopic rod 5 drives the push rod 6 to return to the starting position, and the second telescopic rod 11 moves downward until the unit formed by the two top partition plates 9 is at the same horizontal height as the roller conveyor belt 4.

[0027] Therefore, the present invention provides a transfer device for finished drug box packaging with the above-mentioned structure, which solves the problems of low stacking efficiency and poor process coordination in the prior art. The integrated design and adaptive stacking improve production efficiency.

[0028] Finally, it should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and not to limit it. Although the utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can still be made to the technical solution of this utility model, and these modifications or equivalent substitutions cannot cause the modified technical solution to deviate from the spirit and scope of the technical solution of this utility model.

Claims

1. A transfer device for finished medicine box packaging, characterized in that: It includes a conveying mechanism, a stacking mechanism, and a sealing mechanism arranged in sequence; the stacking mechanism includes a guide plate and a shaft plate slidably connected to the guide plate via a guide rail, a partition plate is snapped onto the shaft plate, and a second telescopic rod is provided below the shaft plate.

2. The transfer device for finished drug box packaging according to claim 1, characterized in that: The conveying mechanism includes a conveyor belt, a roller conveyor belt, drive wheels, and a push rod. The roller conveyor belt is located at the tail end of the conveyor belt, and the drive wheels are located above the roller conveyor belt. There are several drive wheels, and the several drive wheels rotate at the same speed. The push rod is connected to a first telescopic rod.

3. The transfer device for finished drug box packaging according to claim 1, characterized in that: The guide plate is disposed on both sides of the partition plate, and the guide rail runs longitudinally through the guide plate.

4. The transfer device for finished drug box packaging according to claim 1, characterized in that: The partition plate is equipped with rolling balls that facilitate packaging movement, and the side of the partition plate away from the shaft plate is sloped.

5. The transfer device for finished drug box packaging according to claim 1, characterized in that: The partition plate is provided with a shaft at its tail end, and the shaft plate is provided with a plurality of insertion holes, the diameter of which matches the diameter of the shaft.