A rapidly deployable antenna support
By using a rotating handle and a pressing block linkage mechanism to expand and embed the reinforcing plate into the soil, combined with magnet fixation, the stability problem of the antenna support during rapid deployment is solved, improving the overall stability and wind resistance of the device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUNNYWAY TECH (CHINA) CO LTD
- Filing Date
- 2025-05-29
- Publication Date
- 2026-06-19
AI Technical Summary
Existing antenna supports suffer from problems such as asynchronous movement of components, swaying, offset, or uneven force during rapid deployment, affecting stability and deployment reliability.
The device employs a linkage reinforcement mechanism consisting of a rotating handle, a rotating cylinder, an extrusion block, a reinforcing plate, and a tension spring. The rotating handle drives the rotating cylinder and the extrusion block to rotate synchronously, causing the reinforcing plate to expand along the inclined groove and embed into the soil, thereby enhancing the connection strength between the device and the ground. Magnets and reinforcing rods are used to achieve rapid fixation.
It significantly improves the wind resistance and overall stability of the antenna support, ensuring safe and reliable operation in complex environments.
Smart Images

Figure CN224384505U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of communication technology, and in particular to an antenna support that can be quickly deployed and retracted. Background Technology
[0002] An antenna bracket is a structural device specifically designed to support and fix an antenna. It ensures that the antenna can be correctly installed in a specific position and remain stable to achieve the best signal transmission effect.
[0003] While existing antenna supports can be rapidly deployed through hinged structures, they still have certain shortcomings during the deployment process. For example, during rapid deployment, the movement of the various components of the support is not synchronized, which can easily lead to swaying, displacement, or uneven force, affecting the overall stability and deployment reliability of the structure.
[0004] To address the existing problems, there is a need to provide a stable antenna support that can be quickly deployed and retracted. Utility Model Content
[0005] To overcome the drawback of poor stability during deployment, this invention provides an antenna support that can be quickly deployed and retracted.
[0006] The technical implementation scheme of this utility model is as follows: an antenna support for rapid deployment and retraction includes a base, a connecting rod, a guide rod, a sliding frame, a hinged bracket, an electric push rod, a rotating cylinder, a rotating handle, a mounting cylinder, rotating rings, tension springs, reinforcing plates, and pressing blocks. Multiple pins are evenly spaced on the base. A connecting rod is connected to the base, and a guide rod is connected to the connecting rod. A sliding frame is slidably connected to the guide rod. A hinged bracket is rotatably connected to the connecting rod. The hinged bracket is rotatably connected to the sliding frame. Electric push rods are symmetrically installed inside the connecting rod, and both electric telescopic ends are connected to the sliding frame. A rotating cylinder is rotatably connected inside the base, and a rotating handle is connected to the rotating cylinder. A mounting cylinder is installed at the bottom of the base. Multiple rotating rings are rotatably connected to the rotating cylinder, and multiple tension springs are connected to each of the multiple rotating rings. Reinforcing plates are connected to each pair of adjacent tension springs. The multiple reinforcing plates are slidably fitted with the mounting cylinder, and each of the multiple reinforcing plates has an inclined groove. Multiple pressing blocks are connected to the rotating cylinder.
[0007] Furthermore, it also includes docking frames and reinforcing rods. The base has multiple placement slots, in which docking frames are placed, and reinforcing rods are connected to each docking frame.
[0008] Furthermore, it also includes magnets, with multiple magnets connected to multiple placement slots, and the multiple magnets are magnetically attracted to the docking frame at the corresponding position.
[0009] Furthermore, it also includes reinforcing rings, with reinforcing rings connected to multiple pins.
[0010] Furthermore, it also includes pull frames, with pull frames connected to multiple docking frames.
[0011] Furthermore, it also includes anti-slip sleeves, which are fitted onto the sliding frame.
[0012] Furthermore, it also includes reinforcing blocks, with multiple reinforcing blocks connected to the base.
[0013] Furthermore, the base has multiple mounting holes.
[0014] The beneficial effects of this utility model are as follows: This device, by setting up a linkage reinforcement mechanism consisting of a rotating handle, a rotating cylinder, an extrusion block, a reinforcing plate, and a tension spring, allows the entire unit to be inserted into the soil during installation, with auxiliary fixation using the mounting holes on the base. Before commencing operation, the operator rotates the handle, causing the rotating cylinder and extrusion block to rotate synchronously. This causes the extrusion block to apply radial thrust to the inclined groove on the reinforcing plate, thereby driving multiple reinforcing plates to expand outward and penetrate deeper into the soil synchronously along the inclined groove direction, enhancing the connection strength between the device and the ground. This structure significantly improves the wind resistance and overall stability of the antenna support during use, ensuring its safe and reliable operation in complex environments. Attached Figure Description
[0015] Figure 1 This is a three-dimensional structural diagram of the present invention.
[0016] Figure 2 This is an exploded view of the base and connecting rod of this utility model.
[0017] Figure 3 This is a cross-sectional view of the connecting rod of this utility model.
[0018] Figure 4 This is an exploded view of the docking frame and placement groove of this utility model.
[0019] Figure 5 This is a cross-sectional view of the base of this utility model.
[0020] Figure 6 This is a cross-sectional view of the reinforcing plate of this utility model.
[0021] Figure 7 This is a three-dimensional structural diagram of the reinforcing plate, tension spring, and inclined groove of this utility model.
[0022] In the attached diagrams: 1: Base; 101: Pin rod; 2: Connecting rod; 3: Guide rod; 4: Sliding frame; 5: Hinge bracket; 6: Electric push rod; 7: Rotating cylinder; 8: Rotating handle; 9: Mounting cylinder; 10: Rotating ring; 11: Tension spring; 12: Reinforcing plate; 13: Inclined groove; 14: Extrusion block; 15: Placement groove; 16: Connecting frame; 17: Reinforcing rod; 18: Magnet; 19: Reinforcing ring; 20: Pull frame; 21: Anti-slip sleeve; 22: Reinforcing block. Detailed Implementation
[0023] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings. It should be understood that these descriptions are merely exemplary and not intended to limit the scope of this utility model. Furthermore, descriptions of well-known structures and technologies are omitted in the following description to avoid unnecessarily obscuring the concept of this utility model.
[0024] Example: A rapidly deployable antenna support, such as... Figures 1-7As shown, the system includes a base 1, a connecting rod 2, a guide rod 3, a sliding frame 4, a hinged bracket 5, an electric push rod 6, a rotating cylinder 7, a rotating handle 8, a mounting cylinder 9, a rotating ring 10, a tension spring 11, a reinforcing plate 12, a pressing block 14, a docking frame 16, a reinforcing rod 17, a magnet 18, a reinforcing ring 19, a pulling frame 20, an anti-slip sleeve 21, and a reinforcing block 22. The base 1 has multiple mounting holes for auxiliary installation. Multiple pins 101 are evenly spaced on the base 1. A connecting rod 2 is connected to the base 1. A guide rod 3 is connected to the connecting rod 2, and a sliding frame 4 is slidably connected to the guide rod 3. A hinged bracket 5 is rotatably connected to the connecting rod 2 for mounting the antenna. The hinged bracket is rotatably connected to the sliding frame 4. Electric push rods 6 are symmetrically installed inside the connecting rod 2, which are the power devices that drive the sliding frame 4 to move up and down. The symmetrical arrangement improves the balance and stability of the movement. Both electric telescopic ends are connected to the sliding frame 4. A rotating cylinder 7 is rotatably connected inside the base 1, and a rotating handle 8 is connected to the rotating cylinder 7. An installation cylinder 9 is installed at the bottom of the base 1. Multiple rotating rings 10 are rotatably connected, and multiple tension springs 11 are connected to each of the multiple rotating rings 10. Reinforcing plates 12 are connected to each pair of adjacent tension springs 11. The reinforcing plates 12 are slidably fitted with the mounting cylinder 9. Each reinforcing plate 12 has an inclined groove 13. Multiple pressing blocks 14 are connected to the rotating cylinder 7. Multiple placement slots 15 are provided on the base 1. A docking frame 16 is placed in each of the placement slots 15. Reinforcing rods 17 are connected to each of the docking frames 16 for reinforcing the base 1. Reinforcing rods 17 are connected to each of the placement slots 15. Multiple magnets 18 are attached, and the magnets 18 are magnetically attracted to the corresponding docking frame 16 to reinforce the docking frame 16. Reinforcing rings 19 are connected to multiple pin rods 101 to increase the area between the pin rods 101 and the soil. Pull frames 20 are connected to multiple docking frames 16 to facilitate the movement of the docking frame 16. Anti-slip sleeves 21 are fitted on the sliding frame 4 to prevent slipping when the staff pushes it manually. Multiple reinforcing blocks 22 are connected to the base 1 to enhance the mechanical strength of key parts of the base 1 and improve the overall structural durability.
[0025] When this device is needed, the operator first inserts the three docking brackets 16 into the corresponding placement slots 15. After the docking brackets 16 are inserted into place, the magnets 18 set in the placement slots 15 magnetically attract them, thereby quickly fixing the docking brackets 16. Then, the entire device is placed in the designated position, and its lower part is inserted into the ground for initial positioning. After insertion, the operator rotates the rotating handle 8, which drives the rotating cylinder 7 and the multiple extrusion blocks 14 connected to it to rotate synchronously. During the rotation, the extrusion blocks 14 apply a pushing force to the inclined grooves 13 on the reinforcing plates 12, causing the multiple reinforcing plates 12 to move along the inclined grooves 13. The device expands outward in three directions, while the tension spring 11 is stretched. This action further embeds the reinforcing plate 12 into the soil, enhancing the overall stability and support effect of the device. When the rotating handle 8 is rotated to the set angle, it stops rotating and the device is further fixed and installed through the mounting holes on the base 1. After installation, the two electric push rods 6 are activated, and their telescopic ends drive the sliding frame 4 to move upward along the guide rod 3. During the upward movement of the sliding frame 4, the hinge bracket 5 automatically unfolds and expands the structure. When the hinge bracket 5 is fully unfolded, the electric push rods 6 are turned off, thus completing the rapid unfolding and support operation of the antenna bracket.
[0026] The above embodiments are merely preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model. Therefore, all equivalent changes made based on the content described in the claims of the present utility model should be included within the scope of the claims of the present utility model.
Claims
1. A rapidly deployable antenna support, characterized in that, The system includes a base (1), a connecting rod (2), a guide rod (3), a sliding frame (4), a hinge bracket (5), an electric push rod (6), a rotating cylinder (7), a rotating handle (8), a mounting cylinder (9), a rotating ring (10), a tension spring (11), a reinforcing plate (12), and an extrusion block (14). Four evenly spaced pins (101) are connected to the base (1). A connecting rod (2) is fixedly connected to the top of the base (1). A guide rod (3) is fixedly connected to the top of the connecting rod (2). A sliding frame (4) is slidably connected to the guide rod (3). A hinge bracket (5) is rotatably connected to the upper part of the connecting rod (2). The hinge bracket and the sliding frame (4) are rotatably connected. The connecting rod (2) has an internal... Electric push rods (6) are installed symmetrically on the left and right sides. Both electric telescopic ends are fixedly connected to the sliding frame (4). A rotating cylinder (7) is rotatably connected inside the base (1). A rotating handle (8) is fixedly connected to the outer ring of the rotating cylinder (7). An installation cylinder (9) is installed at the bottom of the base (1). Four rotating rings (10) are rotatably connected on the rotating cylinder (7). Two tension springs (11) are connected to each of the four rotating rings (10). Reinforcing plates (12) are connected to each of the two adjacent tension springs (11). The four reinforcing plates (12) are slidably engaged with the installation cylinder (9). Inclined grooves (13) are opened on each of the four reinforcing plates (12). Four extrusion blocks (14) are connected to the rotating cylinder (7).
2. The antenna support for rapid deployment and retraction according to claim 1, characterized in that, It also includes a docking frame (16) and a reinforcing rod (17). The base (1) has three placement slots (15), in which the docking frame (16) is placed, and the reinforcing rod (17) is connected to each of the three docking frames (16).
3. The antenna support for rapid deployment and retraction according to claim 2, characterized in that, It also includes magnets (18), with six magnets (18) installed in each of the three placement slots (15), and the six magnets (18) are magnetically attracted to the corresponding docking frame (16).
4. A rapidly deployable antenna support according to claim 3, characterized in that, It also includes a reinforcing ring (19), and each of the four pins (101) is connected to a reinforcing ring (19).
5. A rapidly deployable antenna support according to claim 4, characterized in that, It also includes a pull frame (20), and the pull frame (20) is fixedly connected to each of the three docking frames (16).
6. A rapidly deployable antenna support according to claim 5, characterized in that, It also includes an anti-slip sleeve (21), and the sliding frame (4) is fitted with an anti-slip sleeve (21).
7. A rapidly deployable antenna support according to claim 6, characterized in that, It also includes a reinforcing block (22), and multiple reinforcing blocks (22) are connected to the base (1).
8. A rapidly deployable antenna support according to claim 7, characterized in that, The base (1) has multiple mounting holes.