Stackable non-slip food tray
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HONGHU MINGXIN PLASTIC PRODUCTS CO LTD
- Filing Date
- 2025-06-10
- Publication Date
- 2026-06-26
AI Technical Summary
[0004]在现有的可堆叠防滑食品托盘在堆叠过程中,托盘之间的摩擦力不足,容易导致货物滑落或托盘移位,上下层之间缺乏有效的嵌合机制,容易因外力作用而发生位移,承载能力有限,难以满足现代物流对重型货物运输的需求
[0015]本实用新型,通过橡胶垫初步缓冲,减少硬性碰撞,卡板与上方托盘对应位置配合定位,液压伸缩杆和缓冲弹簧能缓冲冲击力、微调高度和位置,适应震动颠簸,吸收外力能量,防止托盘倾倒、错位,增强了在不同环境下堆叠的稳定性。
Smart Images

Figure CN224409965U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of food tray technology, specifically a stackable non-slip food tray. Background Technology
[0002] Pallets, also known as stacks or pallets, are horizontal platform devices used for assembling, stacking, handling, and transporting goods. Pallets are mostly made of renewable materials, such as plant fibers and polylactic acid, to reduce environmental impact. They are suitable for hotels, restaurants, KTVs, parties, and other occasions, providing safe and reliable food transportation and display solutions. In the food processing and packaging process, pallets can be used for assembling, handling, and storing to ensure food safety and hygiene.
[0003] Existing stackable non-slip food trays have the following main shortcomings:
[0004] In the existing stackable non-slip food pallets, the friction between the pallets is insufficient during the stacking process, which can easily cause goods to slip or the pallets to shift. There is a lack of effective interlocking mechanism between the upper and lower layers, which can easily cause displacement due to external forces. The load-bearing capacity is limited and it is difficult to meet the needs of modern logistics for the transportation of heavy goods. Utility Model Content
[0005] To overcome the above-mentioned defects, this utility model provides a stackable non-slip food tray, which solves the problems in the prior art.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a stackable non-slip food tray, comprising: a tray body, wherein the lower end face of the tray body is provided with a stacking buffer structure;
[0007] The stacking buffer structure includes a rubber pad, which is located at the center of the lower end face of the tray body. The upper end face of the rubber pad and the lower end face of the tray body are provided with four grooves arranged in a rectangle. The center of the lower inner wall of the four grooves at the bottom and the center of the upper inner wall of the four grooves at the rear are provided with a card plate. The eight card plates are arranged in pairs, one above the other. A hydraulic telescopic rod is provided between the four groups of card plates. A buffer spring is sleeved on the outer wall of each of the four hydraulic telescopic rods.
[0008] The upper surface of the pallet body has four stacking structures arranged in a rectangle. A dustproof plate is provided at the center of the upper surface of the pallet body, and a placement structure is provided at the center of the interior of the pallet body.
[0009] As a further embodiment of this utility model: the four stacked structures include four slots, which are arranged in a rectangular pattern on the upper surface of the tray body. Support columns are provided at the center of the front inner wall and the center of the rear inner wall of each of the four slots. Sliding blocks are slidably provided at the center of each of the four slots. Sliding grooves are provided at the lower center of the front and rear surfaces of each of the four sliding blocks.
[0010] As a further embodiment of this utility model: the placement structure includes two fixing slots, which are respectively located at the center of the two inner side walls of the tray body. There is a fixing block at the center of the two fixing slots. A lower groove is provided at the center of the upper end face of the fixing block. A partition block is provided at the center of the upper end face of the fixing slot inside the lower groove. An upper groove is provided at the center of the lower end face of the partition block. Limiting plates are provided at the front and rear of the center of the upper end face of the partition block.
[0011] As a further embodiment of this utility model: bolts are provided at the center of the upper surface of the two limiting plates near both sides, and one end of each of the four bolts passes through the upper surface of the two limiting plates and the upper surface of the pallet body to the inside of the pallet body, and the ends are all threadedly connected to the inside of the pallet body.
[0012] As a further aspect of this utility model, the lower groove and the upper groove are mutually adapted.
[0013] As a further embodiment of this utility model, the eight sliding blocks are respectively slidably connected inside the eight sliding grooves.
[0014] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0015] This invention uses rubber pads for initial cushioning to reduce hard impacts, and the pallet is positioned to correspond with the upper tray. The hydraulic telescopic rod and buffer spring can buffer impact force, fine-tune height and position, adapt to vibration and bumps, absorb external force energy, prevent the tray from tipping over or misaligning, and enhance the stability of stacking in different environments.
[0016] This utility model features a clever design with a slot, a support column, and a sliding block. The slot is used for positioning and stacking, the support column ensures structural stability, and the sliding block can slide within the slot to adapt to pallet deviation and external force shaking, playing a buffering and fine-tuning role, further improving stacking stability and providing more convenience and stability for pallet stacking operations in actual use. Attached Figure Description
[0017] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0018] Figure 2 This is a schematic diagram of the three-dimensional disassembled structure of this utility model;
[0019] Figure 3 for Figure 2 Enlarged view of point A in the middle;
[0020] Figure 4 This is a three-dimensional structural diagram of the main body of the stacking pallet of this utility model.
[0021] In the diagram: 1. Pallet body; 2. Stacking buffer structure; 201. Rubber pad; 202. Pallet plate; 203. Hydraulic telescopic rod; 204. Buffer spring; 205. Groove; 3. Stacking structure; 301. Slot; 302. Support column; 303. Sliding block; 304. Sliding groove; 4. Dustproof plate; 5. Placement structure; 501. Fixing groove; 502. Fixing block; 503. Lower groove; 504. Divider block; 505. Upper groove; 506. Limiting plate. Detailed Implementation
[0022] The technical solution of this patent will be further described in detail below with reference to specific embodiments.
[0023] like Figures 1-4 As shown, this utility model provides a technical solution:
[0024] A stackable, non-slip food tray, comprising:
[0025] Pallet body 1, with a stacking buffer structure 2 on its lower end face. The stacking buffer structure 2 includes a rubber pad 201, which is located at the center of the lower end face of the pallet body 1. The upper end face of the rubber pad 201 and the lower end face of the pallet body 1 both have four rectangular grooves 205. A retaining plate 202 is located at the center of the lower inner wall of the four lower grooves 205 and the center of the upper inner wall of the four rear grooves 205. The eight retaining plates 202 are arranged in pairs, one above the other. A hydraulic telescopic rod 203 is provided between each of the four groups of retaining plates 202. A buffer spring 204 is fitted onto the outer wall of each of the four hydraulic telescopic rods 203. The upper end face of the pallet body 1 has four stacking structures 3 arranged in a rectangular pattern. A dustproof plate 4 is provided at the center, and a placement structure 5 is provided at the center of the pallet body 1. When pallets are stacked, the rubber pad 201 first acts as a buffer to reduce hard collisions between the upper and lower pallets. In addition, the clamping plate 202 will cooperate with the corresponding position of the upper pallet. The hydraulic telescopic rod 203 and the buffer spring 204 can buffer the impact force during stacking, and at the same time play a role in fine adjustment of height and position to ensure accurate stacking of upper and lower pallets. It can also adapt to road bumps and vibrations. When the pallet is subjected to external force due to vibration and bumps, the hydraulic telescopic rod 203 and the buffer spring 204 can absorb some energy to prevent violent collisions and relative displacement between pallets, thereby preventing pallets from tipping over or misaligning due to vibration and bumps.
[0026] The four stacking structures 3 include four slots 301, which are arranged in a rectangular shape on the upper surface of the pallet body 1. Support columns 302 are provided at the center of the front inner wall and the center of the rear inner wall of each slot 301. Sliding blocks 303 slide at the center of each slot 301. Sliding grooves 304 are provided at the lower center of the front and rear faces of each sliding block 303. The eight sliding blocks 303 are slidably connected to the eight sliding grooves 304. The four slots 301 are used to cooperate with the corresponding structure at the bottom of the upper pallet to achieve the purpose of positioning and stacking. The support columns 302 ensure the stability of the slots 301 during stacking. The sliding blocks 303 can slide within the slots 301. When the stacked pallets have a certain deviation or are slightly shaken by external force, the sliding blocks 303 slide within the slots 301 to adjust, ensuring the adaptability of the relative positions of the upper and lower pallets, allowing for smooth stacking. Furthermore, they can play a buffering and fine-tuning role during pallet movement, improving stacking stability.
[0027] The placement structure 5 includes two fixing slots 501, which are respectively located at the center of the two inner side walls of the pallet body 1. A fixing block 502 is located at the center of each fixing slot 501. A lower groove 503 is located at the center of the upper surface of the fixing block 502. A partition block 504 is located at the center of the upper surface of the fixing slot 501 inside the lower groove 503. An upper groove 505 is located at the center of the lower surface of the partition block 504. Limiting plates 506 are located at the front and rear of the center of the upper surface of the partition block 504. Bolts are located at the two sides of the center of the upper surface of the two limiting plates 506. One end of each bolt passes through the upper surface of the two limiting plates 506 and is connected to the pallet body 1. The upper end face of body 1 extends into the interior of tray body 1, and all ends are threaded into the interior of tray body 1. The lower groove 503 and the upper groove 505 are mutually compatible. The divider block 504 can be fixed by two fixing grooves 501 and the internal fixing block 502. The upper groove 505 on the divider block 504 and the lower groove 503 on the fixing block 502 are mutually compatible to divide the internal space of tray body 1, so that different foods can be classified and placed separately. The limiting plate 506 and bolts can limit the divider block 504 on tray body 1 to prevent the divider block 504 from shaking or shifting, thereby ensuring the stability of the placement structure 5 and ensuring that the food is placed securely.
[0028] The working principle of this utility model is as follows:
[0029] Four slots 301 are used to engage with the corresponding structure at the bottom of the upper tray to achieve positioning and stacking. Support columns 302 ensure structural stability of the slots 301 during stacking. Sliding blocks 303 can slide within the slots 301. When the stacked trays have a certain deviation or are slightly shaken by external forces, the sliding blocks 303 slide within the slots 301 to adjust, ensuring the adaptability of the relative positions of the upper and lower trays, allowing for smooth stacking. They also act as a buffer and fine-tuning mechanism during tray movement, improving stacking stability. When the trays are stacked, rubber pads 201... Firstly, it acts as a buffer, reducing hard collisions between the upper and lower pallets. Furthermore, the pallet 202 will cooperate with the corresponding position of the upper pallet. The hydraulic telescopic rod 203 and the buffer spring 204 can buffer the impact force during stacking, and at the same time play a role in fine-tuning the height and position to ensure accurate stacking of the upper and lower pallets. It can also adapt to road bumps and vibrations. When the pallet is subjected to external force due to vibration and bumps, the hydraulic telescopic rod 203 and the buffer spring 204 can absorb some energy to prevent violent collisions and relative displacement between pallets, thereby preventing pallets from tipping over or misaligning due to vibration and bumps.
[0030] In addition, the divider block 504 can be fixed by the two fixing slots 501 and the internal fixing block 502. The upper slot 505 on the divider block 504 and the lower slot 503 on the fixing block 502 are compatible with each other to divide the internal space of the tray body 1 and classify and place different foods. The limiting plate 506 and bolts can limit the divider block 504 on the tray body 1 to prevent the divider block 504 from shaking or shifting, thereby ensuring the stability of the placement structure 5 and ensuring that the food is placed securely.
[0031] The preferred embodiments of the present invention have been described in detail above. However, the present invention is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present invention.
Claims
1. A stackable non-slip food tray characterized by, include: The pallet body (1) has a stacking buffer structure (2) on its lower end face. The stacked buffer structure (2) includes a rubber pad (201). The rubber pad (201) is located at the center of the lower end face of the tray body (1). The upper end face of the rubber pad (201) and the lower end face of the tray body (1) are arranged in a rectangular pattern with four grooves (205). The center of the lower inner wall of the four grooves (205) at the bottom and the center of the upper inner wall of the four grooves (205) at the rear are provided with a card plate (202). The eight card plates (202) are arranged in pairs, one above the other. A hydraulic telescopic rod (203) is provided between the four groups of card plates (202). A buffer spring (204) is sleeved on the outer wall of each of the four hydraulic telescopic rods (203). The upper surface of the pallet body (1) is provided with four stacking structures (3) arranged in a rectangle. A dustproof plate (4) is provided at the center of the upper surface of the pallet body (1). A placement structure (5) is provided at the center of the interior of the pallet body (1).
2. A stackable non-slip food tray according to claim 1, wherein: The four stacking structures (3) include four slots (301). The four slots (301) are arranged in a rectangular shape on the upper surface of the tray body (1). Support columns (302) are provided at the center of the front inner wall and the center of the rear inner wall of the four slots (301). Sliding blocks (303) are slidably provided at the center of the interior of the four slots (301). Sliding grooves (304) are provided at the lower center of the front end face and the lower center of the rear end face of the four sliding blocks (303).
3. The stackable non-slip food tray according to claim 1, characterized in that: The placement structure (5) includes two fixing slots (501), which are respectively located at the center of the two inner side walls of the tray body (1). There is a fixing block (502) at the center of the two fixing slots (501). A lower slot (503) is provided at the center of the upper end face of the fixing block (502). A partition block (504) is provided at the center of the upper end face of the fixing slot (501) inside the lower slot (503). An upper slot (505) is provided at the center of the lower end face of the partition block (504). A limiting plate (506) is provided at the front and rear of the center of the upper end face of the partition block (504).
4. A stackable non-slip food tray according to claim 3, characterized in that: Bolts are provided at the center of the upper surface of the two limiting plates (506) on both sides. One end of each of the four bolts passes through the upper surface of the two limiting plates (506) and the upper surface of the pallet body (1) to the inside of the pallet body (1), and the ends are threaded into the inside of the pallet body (1).
5. A stackable non-slip food tray according to claim 3, characterized in that: The lower groove (503) and the upper groove (505) are mutually compatible.
6. A stackable non-slip food tray according to claim 2, characterized in that: The eight sliding blocks (303) are respectively slidably connected inside the eight sliding grooves (304).