A convenient detection device for verticality of a building main structure
By designing suspension brackets and mounting brackets, and combining tilt sensors and infrared ranging sensors, the problems of inconvenient adjustment and unstable data in high-altitude environments of existing verticality detection devices have been solved. This enables flexible adjustment and high-precision verticality detection, and is suitable for various building shapes.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGXI DINGSHENG ENG QUALITY INSPECTION CO LTD
- Filing Date
- 2025-08-15
- Publication Date
- 2026-06-23
AI Technical Summary
Existing building structure verticality detection devices are inconvenient to adjust in terms of angle and height, and the detection data are easily affected in high-altitude environments. They also lack stability, accuracy, and protection.
The design employs a suspension bracket and mounting bracket, combined with tilt sensors and infrared ranging sensors. The angle of the positioning plate is adjusted by screws and locking nuts. Damping slide rails and guide plates are set for protection. A level bubble is used to determine the levelness, enabling multi-segment detection and resistance to wind and interference.
The device allows for flexible adjustment of the angle and height of the verticality detector, improving the stability and accuracy of the detection data, enhancing its anti-interference capability in harsh environments, and making it suitable for building structures of different shapes.
Smart Images

Figure CN224398655U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of verticality detection technology, specifically to a convenient device for detecting the verticality of a building's main structure. Background Technology
[0002] In the construction and acceptance of building projects, the control of the verticality deviation of the main structure is directly related to structural safety and functionality.
[0003] Typical auxiliary mounting frames for detecting the verticality of the main structure in building construction are not convenient for adjusting the angle of the verticality measuring instrument, nor are they easy to adjust the height of the verticality measuring instrument to suit main structures of different heights. At the same time, it is inconvenient to disassemble and assemble the verticality measuring instrument. Application No. 202322131651.1 discloses an auxiliary mounting frame for detecting the verticality of the main structure of a building project, including a bearing plate, limiting rods, an adjustment mechanism, and a connecting platform. A verticality detector is placed on the upper end of the bearing plate. The limiting rods are evenly nested inside the bearing plate, and the lower end of the limiting rods is threadedly connected to a limiting round cover. The adjustment mechanism is set on the bearing plate and includes a protrusion, a limiting strip, a threaded rod, a mounting plate, and a connecting column. The connecting platform is fixedly connected to the bottom end of the connecting column, and the lower end of the connecting platform is symmetrically rotatably connected to a first connecting shaft. At the same time, the upper center of the first connecting piece is fixedly connected to the first connecting shaft. The mounting plate fixed to the building wall cannot guarantee the verticality of the wall. When the wall surface is rough or the paint is too thick and tilted, the verticality detector connected to the mounting plate will tilt, resulting in insufficient stability and accuracy of the installation and detection. Furthermore, when the verticality detector is installed at different heights on the wall, the detection data of the verticality detector is easily affected by strong winds in high-altitude environments, indicating insufficient protection.
[0004] No effective solutions have yet been proposed to address the problems in the relevant technologies. Utility Model Content
[0005] In view of the problems in the related technologies, this utility model proposes a convenient detection device for the verticality of the main structure of a building, so as to overcome the above-mentioned technical problems existing in the existing related technologies.
[0006] Therefore, the specific technical solution adopted by this utility model is as follows:
[0007] A convenient device for detecting the verticality of a building's main structure includes a suspension bracket and a mounting bracket. The suspension bracket is located on the rear side of the mounting bracket, and fastening components are respectively provided at the four corners of the rear side of the suspension bracket. A base plate is connected to the front side of the mounting bracket, and a protective cover is movably connected to the top of the base plate. The protective cover covers the outside of the mounting bracket. The mounting bracket includes an L-shaped support plate and an inclination sensor body, with the inclination sensor body located on the top of the L-shaped support plate.
[0008] Preferably, the L-shaped support plate has a first screw fixedly connected to each of the four corners at the top, and a positioning plate is fixedly connected to the bottom side of the tilt sensor body. The positioning plate has U-shaped notches cut out on the left and right sides respectively.
[0009] Preferably, the U-shaped notch is movably embedded on the outside of the first screw, and the outer wall of the first screw is symmetrically threaded with a first locking nut, and the opposite side of the first locking nut abuts against the upper and lower parts of the positioning plate respectively.
[0010] Preferably, an infrared ranging sensor is fixedly connected to one side of the top of the positioning plate, and the infrared ranging sensor is located on the left side of the tilt sensor body.
[0011] Preferably, the top of the base plate is symmetrically fitted with damping slide rails, which are fixedly connected to the bottom two sides of the protective cover via movable ends, and the top of the protective cover is provided with connecting grooves.
[0012] Preferably, the connecting groove extends through both the front and rear sides of the protective cover, and the bottom side of the inner wall of the connecting groove and the rear side of the protective cover are respectively provided with connecting openings. The protective cover is fitted onto the outside of the L-shaped support plate through the connecting opening on the rear side, and guide strips are connected at equal intervals at the corners on both sides of the front side of the protective cover.
[0013] Preferably, the suspension bracket includes a base and an L-shaped suspension plate. The top of the base is fixedly connected to the L-shaped suspension plate. A horizontal bubble is embedded and fixed on the front side of the base. A second screw is provided through each of the four corners of the inner wall of the L-shaped suspension plate. A second locking nut is symmetrically threaded on the outer wall of the second screw.
[0014] Preferably, the rear end of the second screw is fitted with an internally threaded positioning tube, the second screw and the internally threaded positioning tube are threadedly connected, and the second locking nut is fixed to the front and rear of the L-shaped suspension plate respectively.
[0015] The beneficial effects of this utility model are as follows: it facilitates flexible adjustment of the left and right tilt angles of the positioning plate, ensuring that the suspended tilt sensor body remains horizontal during installation and use. The infrared ranging sensor can assist the tilt sensor body in detecting the building structure, providing wall surface concavity compensation, real-time distance measurement correction of tilt angle readings, and determination of tilt direction. This avoids the situation where only the angle is known but the tilt direction cannot be determined when using the tilt sensor body alone, further improving the stability of the building structure verticality detection data. Furthermore, it allows for multi-segment detection at the same detection distance and different wall height ranges, making it more suitable for building structures of different shapes, further enhancing its practicality. It ensures stable operation of the tilt sensor body in harsh environments such as strong light, high humidity, and dust. Additionally, the equidistantly spaced guide plates on both sides of the protective cover allow for good wind and interference resistance when performing detection operations at high altitudes on the building structure. It also allows for quick suspension and positioning of the tilt sensor body at different distances from the building structure near the wall, compensating for changes in the wall contour. Attached Figure Description
[0016] 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.
[0017] Figure 1 This is a schematic diagram of the overall structure of a convenient detection device for the verticality of a building's main structure according to an embodiment of the present utility model;
[0018] Figure 2 This is a schematic diagram of the appearance structure of the mounting bracket for a convenient detection device for the verticality of a building's main structure, according to an embodiment of this utility model.
[0019] Figure 3 This is a schematic diagram of the disassembled structure of the protective cover and the base plate of a convenient detection device for the verticality of a building's main structure according to an embodiment of this utility model.
[0020] Figure 4 This is a schematic diagram of the appearance structure of the suspension bracket of a convenient detection device for the verticality of a building's main structure according to an embodiment of the present utility model.
[0021] In the picture:
[0022] 1. Suspension bracket; 2. Mounting bracket; 3. Fastening assembly; 4. Base plate; 5. Protective cover; 6. L-shaped support plate; 7. Tilt sensor body; 8. First screw; 9. Positioning plate; 10. U-shaped notch; 11. First locking nut; 12. Infrared ranging sensor; 13. Damping slide rail; 14. Connecting groove; 15. Connecting port; 16. Guide strip plate; 17. Base; 18. L-shaped suspension plate; 19. Horizontal bubble; 20. Second screw; 21. Second locking nut; 22. Internal thread positioning tube. Detailed Implementation
[0023] To further illustrate the various embodiments, the present invention provides accompanying drawings, which are part of the disclosure of the present invention. These drawings are mainly used to illustrate the embodiments and can be used in conjunction with the relevant descriptions in the specification to explain the operating principles of the embodiments. With reference to these contents, those skilled in the art should be able to understand other possible implementation methods and the advantages of the present invention. The components in the figures are not drawn to scale, and similar component symbols are usually used to represent similar components.
[0024] According to an embodiment of the present invention, a convenient device for detecting the verticality of a building's main structure is provided.
[0025] Example 1
[0026] like Figure 1-4As shown, a convenient detection device for the verticality of a building's main structure according to an embodiment of this utility model includes a suspension bracket 1 and a mounting bracket 2. The suspension bracket 1 is disposed on the rear side of the mounting bracket 2, and fastening components 3 are respectively provided at the four corners of the rear side of the suspension bracket 1. A base plate 4 is connected to the front side of the mounting bracket 2, and a protective cover 5 is movably connected to the top of the base plate 4. The protective cover 5 covers the outside of the mounting bracket 2. The mounting bracket 2 includes an L-shaped support plate 6 and an inclination sensor body 7. The inclination sensor body 7 is disposed on the top of the L-shaped support plate 6, and fastening components 3 are respectively provided at the four corners of the top of the L-shaped support plate 6. A first screw 8 is fixedly connected to the first screw 8. A positioning plate 9 is fixedly connected to the bottom side of the tilt sensor body 7. U-shaped notches 10 are cut on the left and right sides of the positioning plate 9. The U-shaped notches 10 are movably embedded on the outside of the first screw 8. A first locking nut 11 is symmetrically threaded on the outer wall of the first screw 8. The opposite side of the first locking nut 11 abuts against the positioning plate 9. An infrared ranging sensor 12 is fixedly connected to the top side of the positioning plate 9. The infrared ranging sensor 12 is located on the left side of the tilt sensor body 7. By using the U-shaped notches on the positioning plate 9 of the tilt sensor body 7, the sensor can be positioned to move along the left side of the tilt sensor body 7. The openings 10 are respectively sleeved on the outside of the first screw 8. Two first locking nuts 11 are threaded on the outer wall of the first screw 8. The installation height of the positioning plate 9 can be determined by the lower first locking nut 11. Then, the upper first locking nut 11 is screwed on to press and position the four corners of the positioning plate 9. A U-shaped notch 10 is provided to facilitate flexible adjustment of the left and right tilt angle of the positioning plate 9, ensuring that the suspended tilt sensor body 7 remains horizontal during installation and use, and to facilitate the disassembly and assembly of the tilt sensor body 7 on the positioning plate 9. An infrared distance sensor 12 is set on one side of the tilt sensor body 7. The infrared distance sensor 12 can assist the tilt sensor body 7 in detecting the main body of the building, compensate for wall unevenness, correct the tilt angle reading in real time, and determine the tilt direction. This avoids the situation where only the angle is known but the tilt direction cannot be determined when using the tilt sensor body 7 alone. This further improves the stability of the verticality detection data of the main body of the building. Moreover, it can perform multi-segment detection at the same detection distance and different wall height ranges, making it more suitable for building bodies of different shapes and further improving its practicality.
[0027] Example 2
[0028] like Figure 1-4As shown, a convenient detection device for the verticality of a building's main structure according to an embodiment of this utility model includes a suspension bracket 1 and a mounting bracket 2. The suspension bracket 1 is disposed on the rear side of the mounting bracket 2, and fastening components 3 are respectively provided at the four corners of the rear side of the suspension bracket 1. A base plate 4 is connected to the front side of the mounting bracket 2, and a protective cover 5 is movably connected to the top of the base plate 4. The protective cover 5 covers the outside of the mounting bracket 2. The mounting bracket 2 includes an L-shaped support plate 6 and an inclination sensor body 7. The inclination sensor body 7 is disposed on the top of the L-shaped support plate 6. Damping slide rails 13 are symmetrically embedded on the top of the base plate 4. The damping slide rails 13 are fixedly connected to the bottom two edges of the protective cover 5 through movable ends. A connecting groove 14 is carved into the top of the protective cover 5. The connecting groove 14 penetrates the front and rear sides of the protective cover 5, and a connecting opening 1 is respectively provided on the bottom side of the inner wall of the connecting groove 14 and the rear side of the protective cover 5. 5. The protective cover 5 is fitted onto the outside of the L-shaped support plate 6 through the rear connecting port 15. The front corners of the protective cover 5 are equidistantly connected with guide plates 16. After the tilt sensor body 7 is suspended and installed, the protective cover 5 can be pushed backward to irradiate the outside of the L-shaped support plate 6 through the damping slide rail 13. The opening of the connecting groove 14 and the connecting port 15 protects the outside of the tilt sensor body 7 and the infrared ranging sensor 12 without affecting the normal use of the top detection end of the tilt sensor body 7 and the infrared ranging sensor 12. Thus, the tilt sensor body 7 can be stably operated in harsh environments with strong light, high humidity and dust. The guide plates 16 are equidistantly set on both sides of the outer wall of the protective cover 5. When the detection operation is carried out at a high position of the building, the whole device can have good wind resistance and anti-interference effect.
[0029] Example 3
[0030] like Figure 1-4As shown, a convenient detection device for the verticality of a building's main structure according to an embodiment of this utility model includes a suspension bracket 1 and a mounting bracket 2. The suspension bracket 1 is located on the rear side of the mounting bracket 2. Fastening components 3 are respectively provided at the four corners of the rear side of the suspension bracket 1. A base plate 4 is connected to the front side of the mounting bracket 2. A protective cover 5 is movably connected to the top of the base plate 4 and covers the outside of the mounting bracket 2. The mounting bracket 2 includes an L-shaped support plate 6 and an inclination sensor body 7. The inclination sensor body 7 is located on the top of the L-shaped support plate 6. The suspension bracket 1 includes a base 17 and an L-shaped suspension plate 18. The top of the base 17 is fixedly connected to the L-shaped suspension plate 18. A horizontal bubble 19 is embedded and fixed on the front side of the base 17. A second screw 20 is respectively provided through the four corners of the inner wall of the L-shaped suspension plate 18. A second locking nut 21 is symmetrically threaded on the outer wall of the second screw 20. An internally threaded positioning tube 22 is sleeved on the rear end of the second screw 20. The second screw 20 and the internally threaded positioning tube 22 are mated. With threaded connection, the second locking nut 21 is fixed to the L-shaped suspension plate 18 at the front and rear. The horizontal bubble 19 on the base 17 can be used to determine whether the L-shaped suspension plate 18 is placed horizontally. Then, the internal thread positioning tube 22 is passed through the L-shaped suspension plate 18 and fixed inside the wall of the main building structure. Then, the second screw 20 is screwed to the internal thread positioning tube 22 for connection and fixation. This can quickly determine the horizontality of the tilt sensor body 7. Then, the L-shaped suspension plate 18 is sleeved on the outside of the second screw 20, and the second locking nut 21 clamps and positions the four corners of the L-shaped suspension plate 18 at the front and rear. This can quickly suspend and position the tilt sensor body 7 at different distances from the outside of the wall of the main building structure, which can compensate for changes in the wall contour. When the sensor is installed on the wall, the deviation of the wall relative to the gravity reference is calculated by measuring the angle between the sensor itself and the direction of gravity and combining the geometric relationship.
[0031] In summary, with the help of the above-mentioned technical solution of this utility model, when this device is in use, the positioning plate 9 of the tilt sensor body 7 is respectively sleeved on the outside of the first screw 8 through the U-shaped notch 10. Two first locking nuts 11 are threaded on the outer wall of the first screw 8. The installation height of the positioning plate 9 can be determined by the lower first locking nut 11. Then, the upper first locking nut 11 is screwed on so that the first locking nut 11 presses and positions the four corners of the positioning plate 9. The U-shaped notch 10 is provided to facilitate flexible adjustment of the left and right tilt angle of the positioning plate 9, ensuring that the suspended tilt sensor body 7 remains horizontal during installation and use. An infrared ranging sensor 12 is set on one side of the tilt sensor body 7. The infrared ranging sensor 12 can assist the tilt sensor body 7 in detecting the main body of the building, compensate for wall unevenness, measure and correct the tilt angle reading in real time, and determine the tilt direction. After the tilt sensor body 7 is suspended and installed as a whole, the protective cover 5 can be pushed backward to irradiate the outside of the L-shaped support plate 6 through the damping slide rail 13. The opening of the connecting groove 14 While protecting the tilt sensor body 7 and infrared ranging sensor 12 from the outside, the connection port 15 does not affect the normal use of the top detection end of the tilt sensor body 7 and infrared ranging sensor 12. The guide strips 16 are equidistantly set on both sides of the outer wall of the protective cover 5. When the detection operation is carried out at a high position of the building, the whole device can have good wind resistance and anti-interference effect. The horizontal bubble 19 on the base 17 can be used to determine whether the L-shaped suspension plate 18 is placed horizontally. Then, the internal thread positioning tube 22 is passed through the L-shaped suspension plate 18 and fixed inside the wall of the building structure. Then, the second screw 20 is screwed to the internal thread positioning tube 22 for connection and fixation. The horizontality of the tilt sensor body 7 can be quickly determined. Then, the L-shaped suspension plate 18 is sleeved on the outside of the second screw 20, and the second locking nut 21 clamps and positions the four corners of the L-shaped suspension plate 18. The tilt sensor body 7 can be quickly suspended and positioned at different distances from the outside of the building structure.
[0032] The above are merely preferred embodiments of the present utility model and are not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model shall be included within the protection scope of the present utility model.
Claims
1. A convenient device for detecting the verticality of a building's main structure, comprising a suspension bracket (1) and a mounting bracket (2), characterized in that, The suspension bracket (1) is located on the rear side of the mounting bracket (2). Fastening components (3) are provided at the four corners of the rear side of the suspension bracket (1). A base plate (4) is connected to the front side of the mounting bracket (2). A protective cover (5) is movably connected to the top of the base plate (4). The protective cover (5) is placed on the outside of the mounting bracket (2). The mounting bracket (2) includes an L-shaped support plate (6) and an tilt sensor body (7). The tilt sensor body (7) is located on the top of the L-shaped support plate (6).
2. The convenient detection device for the verticality of a building's main structure according to claim 1, characterized in that, The L-shaped support plate (6) has four corners at the top fixed with first screws (8), and the tilt sensor body (7) has a positioning plate (9) fixedly connected to the bottom side. The positioning plate (9) has U-shaped notches (10) cut out on the left and right sides respectively.
3. The convenient detection device for the verticality of a building's main structure according to claim 2, characterized in that, The U-shaped notch (10) is movably embedded on the outside of the first screw (8). The first screw (8) is symmetrically threaded with a first locking nut (11). The opposite side of the first locking nut (11) abuts against the positioning plate (9) from the top and bottom respectively.
4. The convenient detection device for the verticality of a building's main structure according to claim 3, characterized in that, An infrared ranging sensor (12) is fixedly connected to one side of the top of the positioning plate (9), and the infrared ranging sensor (12) is located on the left side of the tilt sensor body (7).
5. The convenient detection device for the verticality of a building's main structure according to claim 4, characterized in that, The bottom plate (4) is symmetrically fitted with damping slide rails (13) at the top. The damping slide rails (13) are fixedly connected to the bottom two sides of the protective cover (5) through the movable end. The protective cover (5) is provided with a connecting groove (14) at the top.
6. The convenient detection device for the verticality of a building's main structure according to claim 5, characterized in that, The connecting groove (14) penetrates the front and rear sides of the protective cover (5), and the bottom side of the inner wall of the connecting groove (14) and the rear side of the protective cover (5) are respectively provided with connecting openings (15). The protective cover (5) is sleeved on the outside of the L-shaped support plate (6) through the connecting opening (15) on the rear side. The front two corners of the protective cover (5) are respectively connected with guide strips (16) at equal intervals.
7. A convenient detection device for the verticality of a building's main structure according to claim 6, characterized in that, The suspension bracket (1) includes a base (17) and an L-shaped suspension plate (18). The top of the base (17) is fixedly connected to the L-shaped suspension plate (18). A horizontal bubble (19) is embedded and fixed on the front side of the base (17). A second screw (20) is provided through the four corners of the inner wall of the L-shaped suspension plate (18). A second locking nut (21) is symmetrically threaded on the outer wall of the second screw (20).
8. A convenient device for detecting the verticality of a building's main structure according to claim 7, characterized in that, The second screw (20) is fitted with an internal threaded positioning tube (22) at its rear end. The second screw (20) and the internal threaded positioning tube (22) are threadedly connected. The second locking nut (21) is fixed to the L-shaped suspension plate (18) at the front and rear respectively.