Blister tray base with integrated non-slip tread
By integrating anti-slip and stacking components into the blister tray, the problem of slippage caused by the smooth surface of the blister tray is solved, achieving stable stacking and precise positioning of the tray, thus improving the stability and efficiency of transportation and warehousing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GRAND MAX ENTERPRISE CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-07-07
AI Technical Summary
The existing blister trays have smooth surfaces, which makes them easy to slip off and difficult to stack, thus affecting the product packaging process.
It adopts a combination structure of anti-slip elements and stacking elements, including anti-slip frames and cross-shaped anti-slip strips, to enhance the coefficient of friction, and ensures stacking stability through the coordinated layout of arrayed stacking elements and anti-slip frames.
It significantly increases the friction of the pallet, prevents horizontal displacement, ensures stacking stability, provides a precise positioning benchmark, and solves the problems of slippage and tilting of traditional blister pallets during transportation and storage. It has a compact structure and strong practicality.
Smart Images

Figure CN224466384U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of thermoforming product technology, specifically a thermoforming tray base with integrated anti-slip texture. Background Technology
[0002] Blister trays, also known as plastic inner trays, are made by forming a plastic sheet into a specific groove using a blister forming process. Products are placed inside the groove to protect and enhance their appearance. There are also transport-type tray packaging options.
[0003] However, the smooth surface of existing ordinary blister trays makes them easy to slip off, making them inconvenient to stack and hindering product packaging. Utility Model Content
[0004] To address the aforementioned issues, this utility model provides a blister tray base with integrated anti-slip texture, which solves the problem that the smooth surface of existing ordinary blister trays makes them prone to slipping, making it inconvenient to stack blister trays and hindering product packaging.
[0005] The technical solution adopted by this utility model is as follows: it includes a base, an anti-slip element, and a stacking element; the anti-slip element is disposed on the base, and the stacking element is disposed inside the base close to the anti-slip element. Multiple stacking elements are disposed, and the multiple stacking elements are arranged in an array on the base and are stacked in an anti-slip manner through the anti-slip element.
[0006] The anti-slip element includes an anti-slip frame and anti-slip strips; multiple anti-slip strips are provided, and the multiple anti-slip strips are arranged in a star-shaped pattern inside the anti-slip frame, and the anti-slip frame is located on the upper surface of the base near the stacking element.
[0007] A further improvement to the above solution is that a baffle is provided at the edge of the base, and one end of the baffle surrounds the base to form an assembly area.
[0008] A further improvement to the above scheme is that the inner wall surface of the baffle is an inclined surface.
[0009] A further improvement to the above scheme is that the anti-slip element and the stacking element are arranged sequentially in the assembly area.
[0010] A further improvement to the above solution is that the base, anti-slip element, and stacking element are integrally injection molded.
[0011] A further improvement to the above solution is that an anti-slip platform is provided on the anti-slip frame near the anti-slip strip, and four sets of anti-slip platforms are provided, with the four sets of anti-slip platforms respectively located at opposite corners of the anti-slip frame.
[0012] A further improvement to the above solution is that the anti-slip platform is a triangular anti-slip platform.
[0013] A further improvement to the above solution is that the anti-slip frame includes a strip frame and a front frame, the strip frame is disposed between the two sets of stacked elements, and the front frame is located on the side closer to the stacked elements.
[0014] A further improvement to the above scheme is that a positioning element is provided between the frame and the main frame, and the positioning element is used for positioning the stacked elements.
[0015] A further improvement to the above scheme is that the stacking element is a stacking slot, and the stacking slot is a T-shaped slot.
[0016] The beneficial effects of this utility model are:
[0017] Compared to existing blister trays, this invention uses the tray as the basic load-bearing component, which together with anti-slip elements and stacking elements forms a complete anti-slip stacking mechanism. The anti-slip elements adopt a combination structure of anti-slip frames and cross-shaped anti-slip strips, which significantly increases the friction coefficient of the contact surface. When multiple trays are stacked on top of each other, the cross-shaped anti-slip strips can effectively prevent horizontal displacement and ensure stacking stability. Through the coordinated layout of multiple stacking elements arranged in an array with the anti-slip frame, it not only ensures the uniformity of load-bearing on a single layer of trays, but also provides a precise positioning benchmark for multi-layer stacking. This effectively solves the problems of easy sliding and stacking tilting of traditional blister trays during transportation and storage. The structure is compact and highly practical. Attached Figure Description
[0018] Figure 1 This is a perspective view of the blister tray base with integrated anti-slip texture of this utility model;
[0019] Figure 2 This is a top view of the blister tray base with integrated anti-slip texture according to this utility model.
[0020] Explanation of reference numerals in the attached drawings: base 10, baffle 11;
[0021] Anti-slip element 20, anti-slip frame 21, anti-slip strip 22, anti-slip platform 23, strip frame 24, main frame 25, positioning element 26;
[0022] Stacked components 30. Detailed Implementation
[0023] To facilitate understanding of this utility model, a more complete description will be given below with reference to the accompanying drawings. Preferred embodiments of this utility model are shown in the drawings. However, this utility model can be implemented in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided to provide a more thorough and complete understanding of the disclosure of this utility model.
[0024] It should be noted that when a component is said to be "fixed to" another component, it can be directly attached to the other component or there may be an intervening component. When a component is said to be "connected to" another component, it can be directly connected to the other component or there may be an intervening component.
[0025] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention pertains. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.
[0026] like Figures 1-2 As shown in the embodiment of this utility model, a blister tray base with integrated anti-slip texture includes: a base 10, anti-slip elements 20, and stacking elements 30; the anti-slip elements 20 are disposed on the base 10, and the stacking elements 30 are disposed inside the base 10 near the anti-slip elements 20. Multiple stacking elements 30 are arranged in an array on the base 10 and are stacked for anti-slip purposes through the anti-slip elements 20; the anti-slip elements 20 include an anti-slip frame 21 and anti-slip strips 22; multiple anti-slip strips 22 are disposed in a cross shape inside the anti-slip frame 21, and the anti-slip frame 21 is disposed on the upper surface of the base 10 near the stacking elements 30. In this embodiment, the base 10 serves as the basic load-bearing component, forming a complete anti-slip stacking structure together with the anti-slip element 20 and the stacking element 30. The anti-slip element 20 adopts a combination structure of anti-slip frame 21 and anti-slip strips 22 arranged in a star pattern, which significantly increases the friction coefficient of the contact surface. When multiple pallets are stacked on top of each other, the star-shaped anti-slip strips 22 can effectively prevent horizontal displacement and ensure stacking stability. Through the coordinated layout of multiple stacking elements 30 arranged in an array and anti-slip frame 21, the uniformity of load-bearing of a single-layer pallet is ensured, and a precise positioning benchmark is provided for multi-layer stacking. This effectively solves the problem of traditional blister pallets being prone to sliding and tilting during transportation and storage. The structure is compact and highly practical.
[0027] In the above embodiments, the anti-slip element 20 is composed of the anti-slip frame 21, the anti-slip strip 22, and the anti-slip platform 23, forming an irregular anti-slip texture.
[0028] like Figure 1 As shown, a baffle 11 is provided at the edge of the base 10, and one end of the baffle 11 surrounds the base 10 to form an assembly area. In this embodiment, the assembly area formed by the baffle 11 surrounding the base 10 effectively improves the structural stability of the tray; it can prevent items from slipping off the edge and also provide a clear positioning area for subsequent assembly processes.
[0029] The inner wall of the baffle 11 is inclined. In this embodiment, the inclined structure makes the inner wall of the tray a natural guide surface, which facilitates the picking and placing of items; at the same time, the tilt angle can effectively disperse lateral pressure and enhance the overall structural stability.
[0030] Anti-slip elements 20 and stacking elements 30 are sequentially arranged in the assembly area. In this embodiment, the anti-slip elements 20 effectively increase the friction between the pallet and the carried items, preventing the items from sliding or shifting during transportation or handling, and ensuring product stability. Meanwhile, the reasonable layout of the stacking elements 30 allows multiple pallets to be stably stacked vertically, saving storage space and avoiding the risk of tipping over due to unstable stacking. Furthermore, the sequential arrangement of the anti-slip elements 20 and stacking elements 30 in the assembly area facilitates unified management and optimized layout.
[0031] like Figure 2 As shown, the base 10, anti-slip element 20, and stacking element 30 are integrally injection molded. In this embodiment, the integral molding process eliminates the traditional assembly process, significantly improving production efficiency and reducing manufacturing costs, and effectively enhancing the stability of goods during transportation.
[0032] Anti-slip platforms 23 are provided on the anti-slip frame 21 near the anti-slip strip 22. Four sets of anti-slip platforms 23 are provided, each set located diagonally across the anti-slip frame 21. In this embodiment, the four sets of anti-slip platforms 23 located diagonally across the anti-slip frame 21 improve the anti-slip performance of the blister tray base 10. Furthermore, the symmetrical layout of the anti-slip platforms 23 ensures a more even distribution of force, effectively enhancing the stability of the tray during transportation and stacking.
[0033] The anti-slip platform 23 is a triangular anti-slip platform 23. In this embodiment, the triangular anti-slip platform 23 structure can effectively enhance the anti-slip performance of the blister tray bottom support 10; during the stacking or transportation of the tray, the bottom anti-slip texture forms multi-point friction with the contact surface, significantly reducing the risk of sliding; compared with traditional flat anti-slip texture, the triangular layout can provide a larger effective contact area under inclined conditions, and its edge structure can also play a directional limiting role.
[0034] The anti-slip frame 21 includes a strip frame 24 and a front frame 25. The strip frame 24 is disposed between the two sets of stacking elements 30, and the front frame 25 is located on the side closer to the stacking element 30. In this embodiment, the anti-slip performance of the blister tray base 10 is effectively improved through the cooperative design of the strip frame 24 and the front frame 25. The strip frame 24, disposed between the two sets of stacking elements 30, can form a physical barrier during stacking to prevent the upper tray from sliding laterally; the front frame 25 is close to the side of the stacking element 30, further enhancing longitudinal stability.
[0035] A positioning element 26 is provided between the frame 24 and the main frame 25, and the positioning element 26 is used for positioning the stacked elements 30. In this embodiment, by setting the positioning element 26 between the frame 24 and the main frame 25, the precise positioning function of the stacked elements 30 is realized. The setting of the positioning element 26 effectively solves the problem that traditional blister trays are prone to displacement and misalignment during stacking, and significantly improves the stability and neatness of tray stacking. When used with the blister tray base 10 with integrated anti-slip texture, a dual positioning guarantee is formed: the anti-slip texture provides basic friction, while the positioning element 26 achieves mechanical precision alignment. The overall structure is simple and practical, and significantly improves the performance and reliability of the product without increasing costs too much.
[0036] The stacking element 30 is a stacking slot, which is a T-shaped slot. In this embodiment, the T-shaped stacking slot structure design reduces the risk of product damage caused by sliding, and helps to improve the utilization rate of storage space and the efficiency of loading and unloading operations.
[0037] A blister tray base with integrated anti-slip texture includes: a base 10, anti-slip elements 20, and stacking elements 30; the anti-slip elements 20 are disposed on the base 10, and the stacking elements 30 are disposed within the base 10 near the anti-slip elements 20. Multiple stacking elements 30 are arranged in an array on the base 10 and are stacked anti-sliply through the anti-slip elements 20; the anti-slip elements 20 include an anti-slip frame 21 and anti-slip strips 22; multiple anti-slip strips 22 are disposed in a star-shaped arrangement within the anti-slip frame 21, and the anti-slip frame 21 is disposed on the upper surface of the base 10 near the stacking elements 30. In this embodiment, the base 10 serves as the basic load-bearing component, forming a complete anti-slip stacking structure together with the anti-slip element 20 and the stacking element 30. The anti-slip element 20 adopts a combination structure of anti-slip frame 21 and anti-slip strips 22 arranged in a star pattern, which significantly increases the friction coefficient of the contact surface. When multiple pallets are stacked on top of each other, the star-shaped anti-slip strips 22 can effectively prevent horizontal displacement and ensure stacking stability. Through the coordinated layout of multiple stacking elements 30 arranged in an array and anti-slip frame 21, the uniformity of load-bearing of a single-layer pallet is ensured, and a precise positioning benchmark is provided for multi-layer stacking. This effectively solves the problem of traditional blister pallets being prone to sliding and tilting during transportation and storage. The structure is compact and highly practical.
[0038] The above embodiments only illustrate several implementation methods of this utility model, and their descriptions are relatively specific and detailed, but they should not be construed as limiting the scope of this utility model patent. It should be noted that those skilled in the art can make various modifications and improvements without departing from the concept of this utility model, and these all fall within the protection scope of this utility model. Therefore, the protection scope of this utility model patent should be determined by the appended claims.
Claims
1. A blister tray base with integrated anti-slip texture, characterized in that, include: Base, anti-slip components, and stacking components; The anti-slip element is disposed on the base, and the stacking element is disposed inside the base near the anti-slip element. Multiple stacking elements are disposed, and the multiple stacking elements are arranged in an array on the base and are stacked for anti-slip purposes through the anti-slip element. The anti-slip element includes an anti-slip frame and anti-slip strips; multiple anti-slip strips are provided, and the multiple anti-slip strips are arranged in a star-shaped pattern inside the anti-slip frame, and the anti-slip frame is located on the upper surface of the base near the stacking element.
2. The blister tray base with integrated anti-slip texture according to claim 1, characterized in that: A baffle is provided at the edge of the base, and one end of the baffle surrounds the base to form an assembly area.
3. The blister tray base with integrated anti-slip texture according to claim 2, characterized in that: The inner wall of the baffle is inclined.
4. The blister tray base with integrated anti-slip texture according to claim 3, characterized in that: The anti-slip elements and stacking elements are arranged sequentially in the assembly area.
5. The blister tray base with integrated anti-slip texture according to claim 1, characterized in that: The base, anti-slip elements, and stacking elements are integrally injection molded.
6. The blister tray base with integrated anti-slip texture according to claim 5, characterized in that: The anti-slip frame is provided with an anti-slip platform near the anti-slip strip. There are four sets of anti-slip platforms, which are respectively located at opposite corners of the anti-slip frame.
7. The blister tray base with integrated anti-slip texture according to claim 6, characterized in that: The anti-slip platform is a triangular anti-slip platform.
8. The blister tray base with integrated anti-slip texture according to claim 1, characterized in that: The anti-slip frame includes a strip frame and a front frame. The strip frame is disposed between the two sets of stacked elements, and the front frame is located on the side closer to the stacked elements.
9. The blister tray base with integrated anti-slip texture according to claim 8, characterized in that: A positioning element is provided between the frame and the main frame, and the positioning element is used to position the stacked elements.
10. The blister tray base with integrated anti-slip texture according to claim 9, characterized in that: The stacking element is a stacking slot, and the stacking slot is a T-shaped slot.