A metal tube transfer rack
By designing a metal tube transfer rack and using lifting and pressure components to limit the movement of the metal tubes, the problems of rolling and collision during metal tube transportation are solved, achieving stable transportation and simplifying unloading operations, thereby reducing costs and workload.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- DINGZHOU JIFENG METAL PROD CO LTD
- Filing Date
- 2025-07-15
- Publication Date
- 2026-06-30
AI Technical Summary
Metal tubes are prone to rolling and colliding with each other during transportation. Existing technology solves this problem by wrapping them in cardboard boxes, but this increases costs and workload.
Design a metal tube transfer rack, comprising a base plate, mounting plate, support frame and top plate, using lifting and pressure components to limit the metal tubes, ensuring their stability during transportation and reducing operational complexity during unloading.
This method ensures the stability of metal pipes during transportation, preventing rolling and collisions, while also simplifying the unloading process and reducing transportation costs and workload.
Smart Images

Figure CN224428404U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of metal pipe transfer technology, and in particular to a metal pipe transfer rack. Background Technology
[0002] Metal tubular structures are commonly used in various industries, but due to their tubular shape, they are prone to rolling during transportation, which can lead to collisions and potentially affect their quality. Current technology typically involves wrapping the metal tubes in cardboard boxes, which reduces collisions and rolling during transport, but increases manufacturing costs. Furthermore, the packaging needs to be removed before use, increasing workload. Therefore, there is an urgent need for a metal tube transport rack that provides stable transport without requiring cardboard boxes. Utility Model Content
[0003] The purpose of this invention is to provide a metal tube transfer rack to solve the problems existing in the prior art.
[0004] To achieve the above objectives, this utility model provides the following solution: This utility model provides a metal tube transfer frame, including a base plate, a mounting plate fixedly connected to the base plate, several support frames symmetrically fixedly connected to both sides of the mounting plate, a top plate fixedly connected to the mounting plate corresponding to the support frames, the top plate being located above the support frames, several metal tube bodies being arranged between the support frames and the base plate, a pressure component for applying pressure to the metal tube bodies being installed inside the top plate; and a lifting component for lifting the metal tube bodies being installed inside the support frames.
[0005] Preferably, the pressure assembly includes a through groove formed in the top plate, a pressure plate slidably connected in the through groove, a first arc-shaped groove adapted to the top of the metal tube body on the bottom surface of the pressure plate, and a plurality of pressure springs fixedly connected between the top surface of the pressure plate and the inner wall of the top plate.
[0006] Preferably, the lifting assembly includes a lifting plate that slides with the support frame. The support frame includes two parallel vertical plates spaced apart. The lifting plate slides between the two vertical plates. The top surface of the lifting plate has a second arc-shaped groove that matches the bottom of the metal tube body. The lowest point of the second arc-shaped groove is higher than the top surface of the vertical plates. The mounting assembly is equipped with a control component that drives the lifting plate to move up and down.
[0007] Preferably, the control component includes a receiving groove formed in the mounting plate, a plurality of sliders are slidably connected in the receiving groove, the sliders are correspondingly arranged with the lifting plate, a connecting plate is fixedly connected between the corresponding slider and the lifting plate, a sliding groove is formed on the mounting plate corresponding to the connecting plate, the connecting plate is slidably located in the sliding groove, and a threaded column is rotatably connected in the receiving groove, the threaded column passing through the plurality of sliders and being threadedly connected to the sliders.
[0008] Preferably, a control groove is provided in the base plate, the bottom end of the threaded column passes through the base plate and is located in the control groove, a mating gear is fixedly connected to the bottom end of the threaded column, a drive gear is rotatably connected in the control groove, the drive gear meshes with the mating gear, a control disk is rotatably connected to the base plate, the control disk is coaxially fixed with the drive gear, and an internal hexagonal hole is provided on the top surface of the control disk.
[0009] Preferably, a limiting rod is fixedly connected to the top surface of the pressure plate, the top end of the limiting rod slides through the top plate, and a limiting block is fixedly connected to the top end of the limiting rod.
[0010] This utility model discloses the following technical effects: In use, the height of the metal tube body is controlled by the lifting component. When raised, it works in conjunction with the pressure component to limit the metal tube body, preventing rolling and collisions during transport, thus ensuring stability. When the lifting component lowers, the metal tube body contacts the support frame, reducing the pressure of the pressure component and facilitating easy and quick removal of the metal tube body along the support frame. This utility model has a simple structure, is easy to operate, provides stable limiting of the metal tube body, ensures stable transport, and facilitates the removal of the metal tube body. Attached Figure Description
[0011] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0012] Figure 1 This is a schematic diagram of the metal tube transfer frame structure of this utility model;
[0013] The components include: 1. Base plate; 2. Mounting plate; 3. Support frame; 4. Top plate; 5. Metal tube body; 6. Through groove; 7. Pressure plate; 8. Pressure spring; 9. Lifting plate; 10. Receiving groove; 11. Sliding block; 12. Connecting plate; 13. Slide groove; 14. Threaded column; 15. Control groove; 16. Matching gear; 17. Drive gear; 18. Control panel; 19. Limiting rod; 20. Limiting block. Detailed Implementation
[0014] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0015] To make the above-mentioned objectives, features and advantages of this utility model more apparent and understandable, the utility model will be further described in detail below with reference to the accompanying drawings and specific embodiments.
[0016] Reference Figure 1 This utility model provides a metal tube transfer frame, including a base plate 1, a mounting plate 2 fixedly connected to the base plate 1, several support frames 3 symmetrically fixedly connected to both sides of the mounting plate 2, and a top plate 4 fixedly connected to the mounting plate 2 corresponding to the support frames 3. The top plate 4 is located above the support frames 3, and several metal tube bodies 5 are arranged between the support frames 3 and the base plate 1. A pressure component that applies pressure to the metal tube bodies 5 is installed inside the top plate 4; a lifting component that lifts the metal tube bodies 5 is installed inside the support frames 3. The height of the metal tube bodies 5 is controlled by the lifting component. When raised, it can cooperate with the pressure component to limit the movement of the metal tube bodies 5, preventing them from rolling or colliding during transport, thus ensuring stability during transport. When the lifting component is lowered, the metal tube bodies 5 contact the support frames 3, at which point the pressure of the pressure component also decreases, making it convenient and quick to remove the metal tube bodies 5 along the support frames 3.
[0017] A further optimized design includes a pressure assembly comprising a through groove 6 formed within the top plate 4, a pressure plate 7 slidably connected within the through groove 6, and a first arc-shaped groove on the bottom surface of the pressure plate 7 that matches the top of the metal tube body 5. Several pressure springs 8 are fixedly connected between the top surface of the pressure plate 7 and the inner wall of the top plate 4. The pressure plate 7 applies pressure to the metal tube body 5 via the pressure springs 8, cooperating with the lifting assembly to limit the movement of the metal tube body 5 and ensure its stability during transport.
[0018] The design is further optimized by adding a lifting plate 9 that slides with the support frame 3. The support frame 3 includes two parallel vertical plates spaced apart. The lifting plate 9 slides between the two vertical plates. A second arc-shaped groove, adapted to the bottom of the metal tube body 5, is formed on the top surface of the lifting plate 9. The lowest point of the second arc-shaped groove is higher than the top surface of the vertical plates. A control component is installed inside the lifting plate 9 to move it up and down. By controlling the lifting plate 9 to move up and down, the metal tube body 5 can be moved upwards. The second arc-shaped groove, in conjunction with the first arc-shaped groove, limits the movement of the metal tube body 5. Simultaneously, it compresses the pressure component, increasing the pressure exerted by the pressure component on the metal tube body 5 and ensuring stability during transport.
[0019] A further optimized scheme includes a receiving groove 10 within the mounting plate 2. Several sliders 11 are slidably connected within the receiving groove 10, corresponding to the lifting plate 9. A connecting plate 12 is fixedly connected between each slider 11 and the lifting plate 9. A sliding groove 13 is provided on the mounting plate 2 corresponding to the connecting plate 12, and the connecting plate 12 slides within the sliding groove 13. A threaded post 14 is rotatably connected within the receiving groove 10, passing through and threadedly connected to the sliders 11. By controlling the rotation of the threaded post 14, the sliders 11 move up and down, which in turn drives the lifting plate 9 up and down via the connecting plate 12, thus controlling the lifting plate 9. The sliding groove 13 provides sliding space for the connecting plate 12 while preventing the sliders 11 from rotating with the threaded post 14, ensuring they can only slide vertically up and down.
[0020] The design is further optimized by incorporating a control groove 15 within the base plate 1. A threaded post 14, with its bottom end penetrating the base plate 1 and located within the control groove 15, is fixedly connected to a mating gear 16. A drive gear 17 is rotatably connected within the control groove 15, meshing with the mating gear 16. A control disk 18 is rotatably connected to the base plate 1, coaxially fixed with the drive gear 17. The top surface of the control disk 18 has an internal hexagonal hole. Rotation of the control disk 18 via a power tool or manual operation drives the drive gear 17, which in turn drives the threaded post 14 through the mating gear 16, thus controlling the threaded post 14.
[0021] The design is further optimized by fixing a limiting rod 19 to the top surface of the pressure plate 7. The top end of the limiting rod 19 slides through the top plate 4, and a limiting block 20 is fixedly connected to the top end of the limiting rod 19. The limiting rod 19 and the limiting block 20 ensure that the pressure plate 7 can slide vertically up and down within the through groove 6, while limiting the downward movement distance of the pressure plate 7. This prevents the pressure plate 7 from contacting the support frame 3 under gravity after the metal tube body 5 is removed, which would make it inconvenient to reinstall the metal tube body 5.
[0022] The working process of this utility model is as follows: During installation, the control panel 18 is rotated manually or with an electric tool. The control panel 18 drives the drive gear 17 to rotate, which in turn drives the threaded column 14 to rotate through the cooperating gear 16. During the rotation of the threaded column 14, several lifting plates 9 move downward through the slider 11, moving it below the top surface of the support frame 3. At this time, the metal tube body 5 is placed between the top plate 4 and the support frame 3, and the metal tube body 5 moves into the first arc-shaped groove. Then, the control panel 18 drives the lifting plates 9 to move upward, lifting the metal tube body 5 and positioning it in the area between the first and second arc-shaped grooves. During the upward movement, the pressure spring 8 is compressed, applying pressure to the metal tube body 5 to maintain its stability during transportation. When it is necessary to remove the metal tube body 5, simply rotate the control panel 18 to drive the lifting plates 9 downward. The lifting plates 9 move to below the support frame 3 and separate from the metal tube body 5. At this time, the pressure of the pressure spring 8 is relatively small, allowing the metal tube body 5 to be removed.
[0023] In the description of this utility model, it should be understood that the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0024] The embodiments described above are merely preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model. Various modifications and improvements made to the technical solutions of the present utility model by those skilled in the art without departing from the spirit of the present utility model should fall within the protection scope defined by the claims of the present utility model.
Claims
1. A metal pipe transfer stand, characterized by: The system includes a base plate (1), on which a mounting plate (2) is fixedly connected. Several support frames (3) are symmetrically fixedly connected on both sides of the mounting plate (2). A top plate (4) is fixedly connected to the mounting plate (2) corresponding to the support frames (3). The top plate (4) is located above the support frames (3). Several metal tube bodies (5) are arranged between the support frames (3) and the base plate (1). A pressure component that applies pressure to the metal tube bodies (5) is installed in the top plate (4). A lifting component that lifts the metal tube bodies (5) is installed in the support frames (3).
2. The metal pipe transfer stand according to claim 1, wherein: The pressure assembly includes a through groove (6) opened in the top plate (4), a pressure plate (7) is slidably connected in the through groove (6), the bottom surface of the pressure plate (7) is provided with a first arc-shaped groove that is adapted to the top of the metal tube body (5), and a plurality of pressure springs (8) are fixedly connected between the top surface of the pressure plate (7) and the inner wall of the top plate (4).
3. The metal pipe transfer stand of claim 1, wherein: The lifting assembly includes a lifting plate (9) that slides with the support frame (3). The support frame (3) includes two parallel vertical plates that are spaced apart. The lifting plate (9) slides between the two vertical plates. The top surface of the lifting plate (9) is provided with a second arc-shaped groove that matches the bottom of the metal tube body (5). The lowest point of the second arc-shaped groove is higher than the top surface of the vertical plate. The assembly is equipped with a control component that drives the lifting plate (9) to rise and fall.
4. The metal pipe transfer stand according to claim 3, wherein: The control component includes a receiving groove (10) opened in the mounting plate (2), a plurality of sliders (11) are slidably connected in the receiving groove (10), the sliders (11) are correspondingly arranged with the lifting plate (9), and a connecting plate (12) is fixedly connected between the corresponding sliders (11) and the lifting plate (9). A sliding groove (13) is opened on the mounting plate (2) corresponding to the connecting plate (12), the connecting plate (12) is slidably located in the sliding groove (13), and a threaded column (14) is rotatably connected in the receiving groove (10). The threaded column (14) passes through the plurality of sliders (11) and is threadedly connected to the sliders (11).
5. A metal tube transfer rack according to claim 4, characterized in that: A control groove (15) is provided in the base plate (1). The bottom end of the threaded column (14) passes through the base plate (1) and is located in the control groove (15). A mating gear (16) is fixedly connected to the bottom end of the threaded column (14). A drive gear (17) is rotatably connected in the control groove (15). The drive gear (17) meshes with the mating gear (16). A control disk (18) is rotatably connected on the base plate (1). The control disk (18) is coaxially fixed with the drive gear (17). An internal hexagonal hole is provided on the top surface of the control disk (18).
6. A metal tube transfer rack according to claim 2, characterized in that: The top surface of the pressure plate (7) is fixedly connected to a limiting rod (19), the top end of the limiting rod (19) is slidably connected through the top plate (4), and the top end of the limiting rod (19) is fixedly connected to a limiting block (20).