A construction engineering foundation reinforcing device
By using a servo motor-driven gear meshing with a staggered rack and adjusting components, along with a magnetically separated reinforcing nail design, the problems of low efficiency and damage in traditional reinforcement devices are solved, achieving efficient and precise reinforcement and a long-life device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- QINGDAO XINYU HE GEOTECHNICAL ENGINEERING CO LTD
- Filing Date
- 2025-07-11
- Publication Date
- 2026-06-19
Smart Images

Figure CN224378844U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of foundation reinforcement technology, and in particular to a foundation reinforcement device for building engineering. Background Technology
[0002] With the acceleration of urbanization and the increasing complexity of construction projects, efficient and precise reinforcement of the foundation soil is required in the process of soft soil foundation, slope reinforcement and loose geological treatment, which requires the use of reinforcement devices.
[0003] In practical use, similar reinforcement devices still have many defects. For example, traditional reinforcement devices mostly rely on manual or single mechanical structure to adjust the spacing, which is inefficient and easily affected by human operation, resulting in uneven positioning of reinforcement nails and unstable construction quality. At the same time, traditional reinforcement devices separate reinforcement nails by mechanical pulling or rotation, which can easily cause nail deformation or damage to the surface coating, affecting reusability and structural strength. Therefore, it is necessary to design a foundation reinforcement device for building engineering. Utility Model Content
[0004] To solve the above-mentioned technical problems, this utility model provides a foundation reinforcement device for building engineering.
[0005] This utility model is achieved using the following technical solution: a foundation reinforcement device for building engineering, comprising an installation assembly, wherein the installation assembly includes an installation plate, the installation plate has a guide groove inside, and a support plate is fixedly connected to the center of the installation plate, and further comprising:
[0006] An adjustment assembly, comprising a movable block slidably mounted inside a guide groove, wherein a reinforcing pin is placed inside the movable block;
[0007] A drive assembly, comprising a fixing plate fixedly connected to the top of a mounting plate by fixing bolts, wherein a drive gear is rotatably connected to the bottom of the fixing plate.
[0008] As a further improvement to the above solution, the top and bottom of the movable block are fixedly connected to limit plates, and a movable groove is provided at the center of the interior of the movable block, with a force-bearing plate placed inside the movable groove.
[0009] Through the above technical solution, the limiting plate restricts the lateral displacement of the moving block in the guide groove through the fixed connection at the top and bottom, preventing it from tilting or falling off due to external force or vibration, and ensuring the smoothness of the sliding process.
[0010] As a further improvement to the above solution, a first magnet is fixedly connected inside the force-bearing plate, a reinforcing nail is glued to the bottom of the force-bearing plate, and a support rod is fixedly connected to the top of the limiting plate.
[0011] Through the above technical solution, the first magnet is embedded in the force-bearing plate, and the magnetic force cooperates with the second magnet to achieve temporary fixation and controllable separation of the reinforcing nail, avoiding the problem of insufficient stability of glue bonding.
[0012] As a further improvement to the above solution, a cylinder is fixedly connected to the top of the support rod, and a stamping plate is fixedly connected to the output end of the cylinder.
[0013] Through the above technical solution, the cylinder provides a stable linear thrust, driving the stamping plate to rise rapidly, and achieving reliable separation of the load-bearing plate and the reinforcing nail through magnetic force.
[0014] As a further improvement to the above solution, a second magnet is fixedly connected to the bottom of the stamping plate, and the second magnet is matched with the first magnet.
[0015] Through the above technical solution, the polarity matching design of the second magnet and the first magnet ensures that the magnetic strength is much greater than the adhesive force of the glue, thus avoiding separation failure and the resulting residue of the reinforcing nail.
[0016] As a further improvement to the above solution, the mounting plate is internally threaded with fixing bolts, and a fixing plate is threadedly connected to the top of the mounting plate via fixing bolts. A servo motor is fixedly connected to the top of the fixing plate.
[0017] The above technical solution allows for fine-tuning of the position between the mounting plate and the fixing plate, adapting to the installation requirements of different terrains and improving the applicability of the device.
[0018] As a further improvement to the above solution, the output end of the servo motor is fixedly connected to a drive gear through the fixed plate. The drive gear is rotatably connected to the top of the support plate and meshes with the force-bearing rack.
[0019] Through the above technical solution, the staggered racks mesh with the drive gear to achieve synchronous displacement of multiple moving blocks, thus avoiding the unevenness of single rack transmission.
[0020] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0021] This invention uses a servo motor to drive a gear to rotate. The staggered racks on the outer surface of the gear mesh with the moving blocks. Through the limiting effect of the guide groove, the moving blocks are ensured to move synchronously along a straight line. The meshing transmission of the gear and racks enables the synchronous sliding of multiple moving blocks, which can quickly respond to different foundation spacing requirements and significantly improve construction efficiency. The guide groove restricts the offset freedom of the moving blocks, avoiding the shaking or tilting errors common in traditional mechanical adjustment, and ensuring the positioning accuracy of the reinforcement nails. The staggered rack design makes the spacing between the moving blocks uniform and adjustable, adapting to diverse reinforcement schemes under complex geological conditions and enhancing the versatility of the device.
[0022] This invention uses a cylinder to drive the stamping plate upwards. The strong magnetic attraction between the second and first magnets overcomes the low-strength adhesive bond between the load-bearing plate and the reinforcing nail, thus separating them. The gap reserved in the support rod provides operating space for the movable slot, facilitating the addition of new reinforcing nails. Magnetic force replaces mechanical pulling, avoiding direct physical damage to the reinforcing nails, extending tool life and reducing maintenance costs. The deterministic action of magnetic separation ensures a controllable separation process, avoiding the risk of reinforcing nails falling off due to adhesive failure, and guaranteeing the quality of foundation reinforcement. Attached Figure Description
[0023] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0024] Figure 2 This is a schematic diagram of the overall internal structure of this utility model;
[0025] Figure 3 This utility model Figure 2 Enlarged schematic diagram of the structure at point A in the middle;
[0026] Figure 4 This is a schematic diagram of the drive component structure of this utility model;
[0027] Figure 5 This is a schematic diagram of the adjustment component structure of this utility model.
[0028] Explanation of key symbols:
[0029] 1. Mounting components; 101. Mounting plate; 102. Guide groove; 103. Support plate; 2. Adjustment components; 201. Moving block; 202. Limiting plate; 203. Movable groove; 204. Force plate; 205. First magnet; 206. Reinforcing nail; 207. Support rod; 208. Cylinder; 209. Stamping plate; 210. Second magnet; 211. Force rack; 3. Drive components; 301. Fixing bolt; 302. Fixing plate; 303. Servo motor; 304. Drive gear. Detailed Implementation
[0030] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments.
[0031] Example:
[0032] Please combine Figure 1-5This embodiment of a foundation reinforcement device for building engineering includes an installation assembly 1, which includes an installation plate 101. The installation plate 101 has a guide groove 102 inside, and a support plate 103 is fixedly connected to the center of the installation plate 101. The device also includes:
[0033] Adjustment component 2 includes a movable block 201 that is slidably installed inside the guide groove 102, and a reinforcing nail 206 is placed inside the movable block 201;
[0034] The drive assembly 3 includes a fixing plate 302 fixedly connected to the top of the mounting plate 101 by fixing bolts 301, and a drive gear 304 rotatably connected to the bottom of the fixing plate 302.
[0035] The top and bottom of the movable block 201 are fixedly connected to the limiting plate 202, and the movable block 201 has a movable groove 203 in the center position inside, and a force plate 204 is placed inside the movable groove 203.
[0036] The first magnet 205 is fixedly connected inside the force plate 204, the bottom of the force plate 204 is bonded with a reinforcing nail 206, and the top of the limiting plate 202 is fixedly connected with a support rod 207.
[0037] A cylinder 208 is fixedly connected to the top of the support rod 207, and a stamping plate 209 is fixedly connected to the output end of the cylinder 208.
[0038] A second magnet 210 is fixedly connected to the bottom of the stamping plate 209, and the second magnet 210 is matched with the first magnet 205.
[0039] Since the magnetic force is much stronger than the low-strength adhesive bond between the load-bearing plate 204 and the reinforcing nail 206, the load-bearing plate 204 can be peeled off from the reinforcing nail 206. This process uses magnetic force instead of mechanical pulling, thus avoiding direct damage to the reinforcing nail.
[0040] The mounting plate 101 has internal threaded connections with fixing bolts 301. The top of the mounting plate 101 is threadedly connected to a fixing plate 302 via fixing bolts 301. A servo motor 303 is fixedly connected to the top of the fixing plate 302.
[0041] The output end of the servo motor 303 is fixedly connected to the drive gear 304 through the fixed plate 302. The drive gear 304 is rotatably connected to the top of the support plate 103 and meshes with the force-bearing rack 211.
[0042] The four moving blocks 201 are simultaneously driven to slide along the guide groove 102, so as to achieve precise synchronous displacement of multiple moving blocks 201 and quickly adjust the spacing to adapt to different foundation reinforcement needs.
[0043] The implementation principle of a foundation reinforcement device for building engineering in this application embodiment is as follows: the servo motor 303 drives the drive gear 304 to rotate on the top of the support plate 103. The four staggered force racks 211 evenly distributed on the outer surface of the gear synchronously drive the four moving blocks 201 to slide along the guide groove 102, so as to achieve precise synchronous displacement of multiple moving blocks 201, quickly adjust the spacing to adapt to different foundation reinforcement requirements, efficiently complete multi-nailing position collaborative operation, improve construction efficiency, and at the same time restrict the movement direction by the guide groove to ensure the stability of the linear movement of the moving blocks and avoid offset errors.
[0044] Once the moving block 201 is positioned, the cylinder 208 drives the stamping plate 209 to rise. Utilizing the strong magnetic attraction between the second magnet 210 and the first magnet 205, and because the magnetic strength is much higher than the low-strength adhesive bond between the load-bearing plate 204 and the reinforcing nail 206, the load-bearing plate 204 can be peeled off from the reinforcing nail 206. This process uses magnetic force instead of mechanical pulling, avoiding direct damage to the reinforcing nail and ensuring the reliability of the separation action. In addition, the design of the support rod 207 provides sufficient clearance between the limiting plate 202 and the cylinder 208, allowing operators to quickly replenish new reinforcing nails 206 through the movable slot 203, enabling continuous operation. This combination of magnetic separation and modular replenishment significantly reduces maintenance complexity while ensuring the continuity and uniformity of foundation reinforcement.
[0045] The above embodiments are merely preferred embodiments of this utility model and should not be construed as limiting the scope of protection of this utility model. Any non-substantial changes and substitutions made by those skilled in the art based on this utility model shall fall within the scope of protection claimed by this utility model.
Claims
1. A foundation reinforcement device for building engineering, comprising an installation assembly (1), the installation assembly (1) including an installation plate (101), the installation plate (101) having a guide groove (102) inside, and a support plate (103) fixedly connected to the central position inside the installation plate (101), characterized in that, Also includes: Adjustment component (2), the adjustment component (2) includes a movable block (201) slidably mounted inside the guide groove (102), and a reinforcing nail (206) is placed inside the movable block (201); The drive assembly (3) includes a fixing plate (302) fixedly connected to the top of the mounting plate (101) by fixing bolts (301), and a drive gear (304) is rotatably connected to the bottom of the fixing plate (302).
2. The foundation reinforcement device for building engineering as described in claim 1, characterized in that: The top and bottom of the movable block (201) are fixedly connected to a limiting plate (202), and an active groove (203) is provided in the center of the interior of the movable block (201), and a force-bearing plate (204) is placed inside the active groove (203).
3. A construction engineering ground reinforcement device as claimed in claim 2, characterised in that: The first magnet (205) is fixedly connected inside the force plate (204), the bottom of the force plate (204) is bonded with a reinforcing nail (206), and the top of the limiting plate (202) is fixedly connected with a support rod (207).
4. A constructional engineering ground stabilisation apparatus as claimed in claim 3, characterised in that: A cylinder (208) is fixedly connected to the top of the support rod (207), and a stamping plate (209) is fixedly connected to the output end of the cylinder (208).
5. The foundation reinforcement device for building engineering as described in claim 4, characterized in that: The bottom of the stamping plate (209) is fixedly connected to a second magnet (210), which is matched with the first magnet (205).
6. A construction engineering ground reinforcement device as claimed in claim 1, characterised in that: The mounting plate (101) is internally threaded with a fixing bolt (301), and the top of the mounting plate (101) is threadedly connected to a fixing plate (302) via the fixing bolt (301). A servo motor (303) is fixedly connected to the top of the fixing plate (302).
7. The foundation reinforcement device for building engineering as described in claim 6, characterized in that: The output end of the servo motor (303) is fixedly connected to the drive gear (304) through the fixing plate (302). The drive gear (304) is rotatably connected to the top of the support plate (103). The drive gear (304) meshes with the force rack (211).