A multi-layer insulation storage rack

By using a bidirectional conveyor belt system and placement component design, automated storage and retrieval of insulating components is achieved, solving the problems of low efficiency, high labor intensity, and safety hazards of existing storage racks, and improving storage efficiency and stability.

CN224466600UActive Publication Date: 2026-07-07BEIJING FRIEND CHEM CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BEIJING FRIEND CHEM CO LTD
Filing Date
2025-07-28
Publication Date
2026-07-07

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Abstract

The utility model belongs to the technical field of storage frame, concretely relates to a multilayer insulating part storage frame, including conveying piece and placing piece, conveying piece includes conveying frame, and both sides of the upper and lower ends of conveying frame are rotatably connected with conveying wheel, and the conveying wheel of conveying frame both sides upper and lower ends is all tensioned to be connected with conveying belt on, the outer end surface of conveying belt is evenly horizontal and is provided with a plurality of placing pieces, and placing piece includes screen and pressure piece, and the screen horizontal fixed is on the outer end surface of conveying belt, and the top surface of screen is vertically fixed with sliding frame, and the sliding frame is vertically provided with pressure piece in, and pressure piece includes sliding plate and rod seat, and the sliding plate horizontal setting is in the sliding frame, and the both ends of sliding plate are provided with the sliding slot of sliding cooperation with sliding frame, and the rod seat is horizontally arranged below the sliding plate. The utility model utilizes the bidirectional motion of conveying belt, drives a plurality of placing pieces to move vertically in turn, and the placing piece is placed or takes the insulating piece conveniently, improves the convenience of insulating piece taking and placing.
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Description

Technical Field

[0001] This utility model belongs to the field of storage rack technology, and specifically relates to a multi-layer insulating storage rack. Background Technology

[0002] In current insulation component storage technologies, especially for products such as insulation boards and profiles, temporary storage is usually required after molding or machining. Existing insulation component storage racks mostly rely on manual placement of insulation components one by one. This method is not only inefficient but also increases the labor intensity of workers. Furthermore, due to the instability of manual operation, it often leads to confusion or damage during storage, failing to meet the needs for efficient and convenient use.

[0003] Some existing insulation component storage racks, such as the one described in patent CN221317229U, employ a structure of a base, support frame, and multi-layer storage plates. A lifting storage device adjusts the storage height, and a conveyor motor drives a conveyor belt to move the components, thus achieving automated storage. This design improves storage efficiency while reducing manual labor intensity. However, when it's necessary to remove insulation components from higher storage plates later, the problem of inconvenient retrieval remains. Due to the lack of auxiliary retrieval components, operators often need to climb to higher positions to manually retrieve the components, significantly increasing the difficulty and safety hazards, and resulting in low efficiency.

[0004] Furthermore, most existing conveyor belt systems only operate in one direction, making them inflexible in handling the storage and retrieval requirements of insulating components of different levels and sizes. For multi-level items, storage rack structures are complex and inflexible, especially when vertical adjustment and precise placement are required; existing technologies often fail to provide sufficient support and convenience. Utility Model Content

[0005] In view of the problems existing in the prior art, the purpose of this utility model is to provide a multi-layer insulating storage rack, which can effectively improve storage efficiency and convenience, and solve the inconvenience and safety problems of existing storage racks in high-level storage and retrieval operations.

[0006] To achieve the above objectives, this utility model provides the following technical solution:

[0007] A multi-layer insulating component storage rack includes a conveying component and a placement component. The conveying component includes a conveyor frame, with conveyor wheels rotatably connected to both the upper and lower ends of the conveyor frame. Conveyor belts are tensioned and connected to the conveyor wheels at both the upper and lower ends of the conveyor frame. Multiple placement components are evenly and horizontally arranged on the outer end face of the conveyor belt. Each placement component includes a mesh sheet and a pressing component. The mesh sheet is horizontally fixed to the outer end face of the conveyor belt, and a sliding frame is vertically fixed to the top surface of the mesh sheet. A pressing component is vertically arranged in the sliding frame. The pressing component includes a sliding plate and a rod seat. The sliding plate is horizontally arranged in the sliding frame, and the two ends of the sliding plate have sliding grooves that slide with the sliding frame. A rod seat is horizontally arranged below the sliding plate.

[0008] Furthermore, springs are vertically fixed at both ends of the top surface of the skateboard, and the top of the springs is fixed to the top surface inside the slide frame.

[0009] Furthermore, a through hole is vertically opened on the skateboard, and a sliding rod is vertically fixed on the top surface of the rod seat, with the sliding rod on the rod seat vertically sliding through the through hole of the skateboard.

[0010] Furthermore, a soft pad is horizontally fixed to the bottom surface of the rod holder.

[0011] Furthermore, multiple elastic frames are horizontally and vertically fixed on the top surface of the pole seat, and the top surfaces of the multiple elastic frames are fixed to the bottom surface of the skateboard.

[0012] Furthermore, both sides of the bottom of the conveyor frame are vertically fixed with brackets, and the bottom of the brackets are locked with fixing screws. A rotating rod is horizontally fixed between the conveyor wheels on both sides of the top of the conveyor frame, and a pulley is fixed on the rotating rod of the conveyor frame.

[0013] Furthermore, a conveyor motor is horizontally fixed to the top of the conveyor frame, and a belt is tensioned and connected to the output end of the conveyor motor, and the belt is tensioned and connected to the pulley on the rotating rod of the conveyor frame.

[0014] Compared with the prior art, the beneficial effects of this utility model are:

[0015] Firstly, this invention employs a bidirectional conveyor belt system. A conveyor motor drives the conveyor belt in both forward and reverse directions, enabling the automatic storage and retrieval of insulating components. Compared to existing technologies that rely on manual labor or unidirectional conveying systems, this invention significantly improves the automation level of the storage process, solves the problem of excessive reliance on manual labor in traditional storage racks, reduces the workload of workers, and avoids storage errors and damage caused by improper manual operation.

[0016] Secondly, the placement components include a mesh panel and a pressure-retaining component. The mesh panel is fixed to the outer end face of the conveyor belt, ensuring the stability of the insulating components during storage. Through the precise design of the pressure-retaining component in the sliding frame, the position and pressure of the placement components can be automatically adjusted to ensure that the insulating components do not shift or collide during storage, further improving the safety and reliability of the storage rack. This design effectively solves the problem of unstable stacking or collision of insulating components in existing storage systems, ensuring the safety of items during storage.

[0017] In the design of the pressure-retaining component, the sliding plate, in cooperation with the sliding frame via a spring, provides appropriate reverse pressure, allowing the pressure-retaining component to slide freely during storage and retrieval. This structure not only improves the stability of the equipment but also reduces friction and wear, extending its service life. Simultaneously, the selection and configuration of the springs ensure the stability of the equipment during long-term use, avoiding performance degradation caused by elastic fatigue.

[0018] This invention combines a multi-layer structure design with an automated conveying system, incorporating existing multi-layer storage panels and lifting devices while avoiding the inconveniences associated with high-altitude storage and retrieval. By adjusting the height of the placement components, the position of each insulating component can be precisely controlled, eliminating the safety hazards of manual climbing and high-altitude operations required by traditional storage racks, thus ensuring both convenience and safety in operation.

[0019] Furthermore, the structural design of the conveyor rack ensures the stability and load-bearing capacity of the entire equipment. The support frame firmly fixes the equipment to the ground with fixing screws, ensuring that the equipment will not tilt or shift during operation. This design solves the technical problem of instability that may occur in existing storage racks due to unstable support, and improves the adaptability and reliability of the equipment in various working environments. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0021] Figure 2 This is a schematic diagram of the overall structure of this utility model in an disassembled state;

[0022] Figure 3 This is a schematic diagram of the conveying component of this utility model in its disassembled state;

[0023] Figure 4 This is a schematic diagram of the structure of the placement component of this utility model in an disassembled state;

[0024] Figure 5 This is a schematic diagram of the structure of the pressing component of this utility model in its disassembled state.

[0025] The attached diagram lists the components represented by each number as follows:

[0026] 1. Conveying component; 11. Conveying frame; 12. Conveying wheel; 13. Conveying belt; 14. Conveying motor; 15. Bracket; 151. Fixing screw; 16. Pulley; 17. Belt; 2. Placement component; 21. Mesh; 22. Sliding frame; 23. Pressing component; 231. Slide plate; 232. Rod base; 233. Soft pad; 234. Elastic frame; 235. Through hole; 236. Spring. Detailed Implementation

[0027] To make the objectives and advantages of this utility model clearer, the following detailed description is provided in conjunction with embodiments. It should be understood that the following text is merely used to describe one or more specific embodiments of this utility model and does not strictly limit the scope of protection specifically claimed by this utility model.

[0028] refer to Figures 1-5 As shown, a multi-layer insulating component storage rack includes a conveying component 1 and placement components 2. The conveying component 1 includes a conveying frame 11, with conveying wheels 12 rotatably connected to both the upper and lower ends of the conveying frame 11. Conveyor belts 13 are tensioned and connected to the conveying wheels 12 at both the upper and lower ends of the conveying frame 11. Multiple placement components 2 are evenly and horizontally arranged on the outer end face of the conveyor belts 13. Each placement component 2 includes a mesh 21 and a pressing component 23. The mesh 21 is horizontally fixed to the outer end face of the conveyor belts 13, and a sliding frame 22 is vertically fixed to the top surface of the mesh 21. A pressing component 23 is vertically arranged in the sliding frame 22. The pressing component 23 includes a sliding plate 231 and a rod seat 232. The sliding plate 231 is horizontally arranged in the sliding frame 22, and its two ends have grooves that slide in cooperation with the sliding frame 22. A rod seat 232 is horizontally arranged below the sliding plate 231.

[0029] In existing technologies, common insulation component storage racks rely on manual operation to place insulation components one by one, resulting in low efficiency and high labor intensity. This invention, however, significantly improves automation through the bidirectional movement of the placement component 2 on the conveyor belt 13. Operators only need to start the conveyor motor 14 to efficiently complete the storage and retrieval of insulation components, avoiding the tedious manual handling. The mesh 21 is fixed to the conveyor belt 13 and moves synchronously with it, ensuring good stability of the insulation components during storage.

[0030] refer to Figure 4 and Figure 5As shown, springs 236 are vertically fixed at both ends of the top surface of the slide plate 231, and the top of the springs 236 is fixed to the inner top surface of the slide frame 22. The function of the springs 236 is to provide a certain reverse pressure, allowing the slide plate 231 to slide freely within the slide frame 22. The vertical movement of the pressing member 23 within the slide frame 22 effectively ensures that the insulating members stored on the mesh 21 do not shift during storage. In addition, the springs 236 are designed using stainless steel or high-strength alloy materials, ensuring the elastic stability and durability of the springs, allowing for long-term use without failure.

[0031] refer to Figure 3 and Figure 4 As shown, a through hole 235 is vertically through the slide plate 231, and a sliding rod is vertically fixed on the top surface of the rod base 232. The sliding rod on the rod base 232 is vertically slidably installed through the through hole 235 of the slide plate 231. This design allows for precise adjustment of the pressure member 23, enabling the rod base 232 to be adjusted to a suitable height position as needed, thereby better adapting to the placement requirements of insulation components of different specifications. In addition, the sliding rod is made of high-hardness alloy steel and has undergone surface hardening treatment to reduce sliding friction and ensure smooth sliding and long-term stability.

[0032] refer to Figure 3 and Figure 4 As shown, a soft pad 233 is horizontally fixed on the bottom surface of the rod base 232. The soft pad 233 is made of high-density rubber or flexible foam material, which has excellent compressive strength and elasticity. It can provide good support when the insulating parts are placed, reduce damage that may be caused by vibration or impact, and thus effectively protect the integrity of the insulating parts.

[0033] refer to Figure 4 As shown, multiple elastic frames 234 are horizontally and vertically fixed on the top surface of the rod base 232, and the top surfaces of the multiple elastic frames 234 are fixed to the bottom surface of the slide plate 231. The function of the elastic frames 234 is to provide additional support force to ensure that the insulating components on the mesh 21 will not be displaced or misaligned due to external forces when storing multi-layer insulating components, thereby improving the stability and adaptability of the storage rack.

[0034] refer to Figure 4 As shown, both sides of the bottom of the conveyor frame 11 are vertically fixed with brackets 15, and the bottom of the brackets 15 are locked in place by fixing screws 151. The brackets 15 are made of high-strength steel or aluminum alloy, which has strong load-bearing capacity and corrosion resistance, ensuring the stability of the entire conveyor frame. The fixing screws 151 at the bottom of the brackets 15 allow the brackets 15 to be firmly installed on the ground or in the production environment, preventing displacement or tilting of the equipment during operation.

[0035] A rotating rod is horizontally fixed between the conveyor wheels 12 on both sides of the top of the conveyor frame 11, and a pulley 16 is fixed on the rotating rod of the conveyor frame 11. The pulley 16 and the tensioning system of the conveyor belt 13 work together to ensure the smooth operation of the conveyor belt 13 and prevent the conveyor belt from slipping or becoming excessively loose. The pulley 16 is made of high-strength engineering plastic and has undergone wear-resistant treatment to improve its service life.

[0036] refer to Figure 4 and Figure 5 As shown, a conveyor motor 14 is horizontally fixed to the top of the conveyor frame 11, and a belt 17 is tensioned and connected to the output end of the conveyor motor 14. The belt 17 is tensioned and connected to the pulley 16 on the rotating rod of the conveyor frame 11. The power of the conveyor motor 14 is 1.5kW to 3kW, suitable for long-term operation under heavy loads. The belt 17 is made of wear-resistant rubber material, which has good tensile strength and durability, and can ensure stable operation under high-frequency use.

[0037] The working principle of this utility model is as follows: When storing the finished insulating parts, the conveyor motor 14 is started to rotate forward, driving the conveyor wheel 12 on the conveyor frame 11 to rotate forward, which in turn drives the tensioned conveyor belt 13 to move forward. This causes multiple placement pieces 2 on the outer wall of the conveyor belt 13 to be placed at the designated height in sequence, allowing the insulating parts to be placed on the mesh 21. After placement, the forward movement of the conveyor belt 13 causes the mesh 21 containing the insulating parts to move upward in sequence. Then, the insulating parts are placed on the multiple placement pieces 2 in sequence. When retrieving the insulating parts from the mesh 21, the conveyor motor 14 is started to rotate in reverse, driving the conveyor wheel 12 on the conveyor frame 11 to rotate in reverse, which in turn drives the tensioned conveyor belt 13 to move in reverse. This causes multiple placement pieces 2 on the outer wall of the conveyor belt 13 to be placed at the designated retrieval height in sequence, allowing the insulating parts to be retrieved from the mesh 21. Thus, the bidirectional movement of the conveyor belt 13 causes multiple placement pieces 2 to move vertically in sequence, facilitating the vertical adjustment of the placement pieces 2 for placing or retrieving the insulating parts, thereby improving the convenience of placing and retrieving the insulating parts.

[0038] Depending on the usage, to ensure the stability of the insulating component on the mesh 21, the slide plate 231 in the sliding frame 22 is pulled vertically upwards, compressing the spring 236 to deform and place the insulating component on the mesh 21. When the slide plate 231 is released, under the deformation force of the spring 236, the slide plate 231 is pushed to slide in the sliding frame 22, causing the bottom surface of the rod seat 232 to press against the insulating component on the mesh 21 to maintain stability.

[0039] The above description is merely a preferred embodiment of this utility model. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of this utility model, and these improvements and modifications should also be considered within the scope of protection of this utility model. Structures, devices, and operating methods not specifically described or explained in this utility model, unless otherwise specified or limited, shall be implemented using conventional methods in the field.

Claims

1. A multi-layer insulating storage rack, characterized in that, The system includes a conveyor (1) and a placement component (2). The conveyor (1) includes a conveyor frame (11). Conveyor wheels (12) are rotatably connected to both the upper and lower ends of the conveyor frame (11), and conveyor belts (13) are tensioned and connected to the conveyor wheels (12) on both the upper and lower ends of the conveyor frame (11). Multiple placement components (2) are evenly and horizontally arranged on the outer end face of the conveyor belt (13). Each placement component (2) includes a mesh (21) and a pressing component (23). The mesh (21) is water-resistant. A sliding frame (22) is fixedly fixed on the outer end face of the conveyor belt (13) and vertically fixed on the top surface of the mesh (21). The pressing member (23) is vertically arranged in the sliding frame (22). The pressing member (23) includes a sliding plate (231) and a rod seat (232). The sliding plate (231) is horizontally arranged in the sliding frame (22), and the two ends of the sliding plate (231) are provided with sliding grooves that slide with the sliding frame (22). The rod seat (232) is horizontally arranged below the sliding plate (231).

2. The multi-layer insulating storage rack according to claim 1, characterized in that: Springs (236) are vertically fixed at both ends of the top surface of the slide plate (231), and the top of the springs (236) is fixed on the top surface inside the slide frame (22).

3. A multi-layer insulating storage rack according to claim 2, characterized in that: The slide plate (231) has a through hole (235) vertically through it, and a sliding rod is vertically fixed on the top surface of the rod seat (232), and the sliding rod on the rod seat (232) is vertically slidably installed in the through hole (235) of the slide plate (231).

4. A multi-layer insulating storage rack according to claim 3, characterized in that: A soft pad (233) is horizontally fixed on the bottom surface of the rod seat (232).

5. A multi-layer insulating storage rack according to claim 3, characterized in that: Multiple elastic frames (234) are fixed horizontally and vertically on the top surface of the rod base (232), and the top surfaces of the multiple elastic frames (234) are fixed on the bottom surface of the slide plate (231).

6. A multi-layer insulating storage rack according to claim 1, characterized in that: The bottom of both sides of the conveyor frame (11) is vertically fixed with brackets (15), and the bottom of the brackets (15) is locked and fixed by fixing screws (151). A rotating rod is horizontally fixed between the conveyor wheels (12) on both sides of the top of the conveyor frame (11), and a pulley (16) is fixed on the rotating rod of the conveyor frame (11).

7. A multi-layer insulating storage rack according to claim 5, characterized in that: A conveyor motor (14) is horizontally fixed at the top of the conveyor frame (11), and a belt (17) is tensioned at the output end of the conveyor motor (14), and the belt (17) is tensioned on the pulley (16) on the rotating rod of the conveyor frame (11).