Detachable triangular inclined bracing quick-mounting structure for assembled suspended building
The detachable triangular bracing quick-assembly structure solves the problem of non-reusability of welding fixation in existing technologies, enabling rapid installation and convenient disassembly of prefabricated suspended buildings, thus improving construction efficiency and structural stability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANDONG XINXIA CONSTR CO LTD
- Filing Date
- 2025-06-17
- Publication Date
- 2026-07-14
AI Technical Summary
In existing prefabricated suspended buildings, triangular bracing structures are fixed by welding or chemical anchors, which require high-altitude operations and cannot be reused. This results in high skill requirements for personnel, great susceptibility to weather conditions, and the high temperature of welding affecting structural stability.
It adopts a detachable triangular bracing quick-installation structure, including a sloping wall, fixing block, fixing mechanism, adjustment mechanism and limiting component. It can be quickly installed and disassembled through components such as rotating rod, rotating plate and threaded rod to adapt to different construction needs.
It enables rapid installation and convenient disassembly of triangular bracing, improving construction efficiency, reducing labor costs and material waste, and enhancing structural stability and flexibility.
Smart Images

Figure CN224495840U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of building construction structure technology, and in particular to a detachable triangular bracing quick-assembly structure for prefabricated suspended buildings. Background Technology
[0002] Prefabricated suspended buildings utilize prefabricated construction technology, transporting factory-prefabricated building components to the construction site for assembly via reliable connections. These buildings lack traditional ground support and exhibit a suspended form. The use of a detachable triangular bracing quick-assembly structure addresses challenges in construction and use, including structural stability, construction efficiency, and cost control. Leveraging the stability of triangles, this structure allows for rapid erection of reliable temporary supports during construction, ensuring the stability of suspended components. After completion, it can be disassembled and reused, improving construction efficiency, reducing material costs and resource waste, and minimizing construction debris. This aligns with green construction principles and effectively guarantees the safe construction and sustainable development of prefabricated suspended buildings.
[0003] The detachable triangular bracing quick-assembly structure for prefabricated suspended buildings mainly consists of a triangular frame body made of high-strength steel, a locking connector for quickly connecting the building body to the bracing frame, an adjustable telescopic adjustment component to adapt to different construction needs, stiffening ribs to enhance overall stability, and a positioning pin and positioning hole system to ensure installation accuracy. All parts work together to achieve the functions of rapid installation, flexible adjustment, stable support, and convenient disassembly.
[0004] In existing technologies, the triangular braces in some quick-assembly triangular bracing structures are fixed by welding or chemical anchors, which require high-altitude operations and cannot be reused. However, welding requires professional welders to perform high-altitude operations, which not only requires high skill levels but is also greatly affected by weather and other factors. The high temperature generated during welding can easily change the local properties of the bracing steel, reducing the overall stability of the structure. Therefore, a detachable quick-assembly triangular bracing structure for prefabricated suspended buildings is proposed to solve the above problems. Utility Model Content
[0005] The purpose of this application is to provide a detachable triangular bracing quick-assembly structure for prefabricated suspended buildings. The aim is to improve the problem that triangular bracing is usually fixed by welding or chemical anchors, which requires high-altitude work and cannot be reused. Welding requires professional welders to perform high-altitude work, which not only requires high skill levels but is also greatly affected by weather and other factors. The high temperature generated during the welding process can easily change the local properties of the bracing steel, reducing the overall stability of the structure.
[0006] The detachable triangular bracing quick-assembly structure for prefabricated suspended buildings provided in this application adopts the following technical solution:
[0007] Through the above technical solution: a detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings, including a sloping wall, the bottom of which is fixedly connected to a fixing block, the outside of which is fixedly connected to a fixing mechanism, and the bottom of which is fixedly connected to an adjustment mechanism;
[0008] The fixing mechanism includes a housing. The right side of the housing is fixedly connected to the left side of the fixing block one. Two fixing blocks two are fixedly connected to the inner wall of the housing. A rotating rod is rotatably connected to the adjacent side of each of the two fixing blocks two. A rotating plate is fixedly connected to the outside of the rotating rod. A force-bearing plate is rotatably connected to the bottom of the rotating rod. A limit block is rotatably connected to the distant side of each of the two rotating plates. A guide plate is fixedly connected to the bottom of the housing. Two moving blocks are slidably connected to the top of the guide plate. A limiting component for limiting the movement of the fixing component is fixedly connected to the front side of the moving blocks.
[0009] Preferably, the sloping wall is the foundation of the entire equipment, the triangular bracket brace stabilizes it, the fixing block is a combination of two horizontal bars to form the triangular bracket brace, the fixing mechanism is to fix the triangular bracket to the sloping wall to stabilize it, and the adjustment mechanism allows the triangular bracket to be folded.
[0010] By adopting the above technical solution, the adjusting mechanism includes a crossbar, the top of which is fixedly connected to the bottom of the fixing mechanism, a movable shell is slidably connected inside the crossbar, a telescopic rod is fixedly connected to the right side of the movable shell, a spring is provided on the outside of the telescopic rod, a telescopic rod is fixedly connected to the inner wall of the movable shell, a spring is provided on the outside of the telescopic rod, a limit plate is slidably connected to the outside of the movable shell, and a groove plate is fixedly connected to the bottom of the movable shell;
[0011] Preferably, the crossbar allows the internal movable shell to move under the action of the limiting plate. The limiting plate moves within the groove on the surface of the crossbar, thereby limiting the movable shell and causing the first spring and the first telescopic rod to be stretched, storing elastic force to pull the movable shell back. The second telescopic rod and the second spring provide a downward pushing force to the limiting rod.
[0012] By adopting the above technical solution, the limiting component includes a force-applying plate, the rear side of which is fixedly connected to the front side of the moving block, a threaded rod is threadedly connected to the inside of the force-applying plate, a fixed plate is slidably connected to the outside of the threaded rod, and a nut is threadedly connected to the bottom of the threaded rod.
[0013] Preferably, the force-applying plate is limited by the threaded rod and the fixing plate, and the nut further stabilizes and fixes the force-applying plate.
[0014] By adopting the above technical solution, the two limiting blocks are externally rotatably connected to the inner wall of the inclined wall, and the adjacent sides of the two moving blocks are fixedly connected to the distant sides of the two force-bearing plates.
[0015] Preferably, the limiting block rotates inside the inclined wall under the action of the rotating plate, and the moving block moves, thereby driving the force plate to move.
[0016] By adopting the above technical solution, the bottom of the force-bearing plate is slidably connected to the top of the guide plate, and a slot is provided on the top of the outer shell;
[0017] Preferably, the fixed plate allows the motor to stably transmit electricity, while the push rod receives the driving force of the motor, thus enabling movement.
[0018] By adopting the above technical solution, the right side of the telescopic rod is fixedly connected to the right inner wall of the crossbar, and the bottom of the groove plate is rotatably connected to the inclined rod;
[0019] Preferably, the telescopic rod receives the moving force of the movable shell, thereby limiting its position within the crossbar, and the diagonal rod makes the included angle of the two crossbars form a right angle.
[0020] By adopting the above technical solution, the top of the limiting plate is fixedly connected to the bottom of the telescopic rod 2, and the outside of the limiting plate is slidably connected to the front and rear sides of the crossbar.
[0021] Preferably, the limiting plate receives the pushing force of the telescopic rod II, thereby stably limiting the moving shell, and the limiting plate moves linearly under the slot of the crossbar.
[0022] By adopting the above technical solution, the bottom of the force-applying plate contacts the top of the nut, and the top of the force-applying plate contacts the bottom of the fixing plate;
[0023] Preferably, the force-applying plate is brought into contact with the nut at the bottom and with the fixed plate at the top by the threaded rod.
[0024] In summary, this application includes at least one of the following beneficial technical effects:
[0025] 1. In this utility model, the force-applying plate causes the moving block to move and collide with the force-receiving plate, causing the top rotating plate to rotate and the limiting block to be limited, thereby connecting the outer shell with the inclined wall. Under the action of the screw and nut, the force-applying rod is fixed, thus realizing the rapid installation of the triangular inclined brace. In addition, it can significantly shorten the construction time of prefabricated suspended buildings, improve the overall construction efficiency, and is easy to install and operate, thereby reducing labor costs and construction difficulty, and adapting to the needs of high-efficiency construction.
[0026] 2. In this utility model, the operator pushes the limiting plate to move it, which in turn moves the movable shell. This causes the first telescopic rod and the first spring to press against each other. Under the action of the second telescopic rod and the second spring, the limiting plate moves, which limits the movable shell, thereby fixing the triangular diagonal brace. In addition, it can improve the installation efficiency of prefabricated suspended buildings, shorten the construction cycle, facilitate disassembly and reuse, reduce material loss and cost, and enhance the flexibility of structural application. Attached Figure Description
[0027] Figure 1 This is a three-dimensional schematic diagram of the detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings proposed in this utility model;
[0028] Figure 2 This is a structural schematic diagram of the fixing block of the detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings proposed in this utility model.
[0029] Figure 3 This is a schematic diagram of the guide plate of the detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings proposed in this utility model.
[0030] Figure 4 This is a schematic diagram of the fixing plate of the detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings proposed in this utility model.
[0031] Figure 5 This is a schematic diagram of the movable shell of the detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings proposed in this utility model.
[0032] Explanation of reference numerals in the attached drawings: 1. Sloping wall; 2. Fixing block one; 3. Fixing mechanism; 31. Outer shell; 32. Fixing block two; 33. Rotating plate; 34. Limiting block; 35. Force-bearing plate; 36. Guide plate; 37. Moving block; 4. Adjusting mechanism; 41. Crossbar; 42. Moving shell; 43. Telescopic rod one; 44. Spring one; 45. Limiting plate; 46. Telescopic rod two; 47. Spring two; 48. Groove plate; 5. Sloping rod; 6. Limiting assembly; 61. Force-applying plate; 62. Threaded rod; 63. Fixing plate; 64. Nut. Detailed Implementation
[0033] The following is in conjunction with the appendix Figure 1 -Appendix Figure 5 This application will be described in further detail below.
[0034] Example: Refer to Figures 2 to 4This utility model provides an embodiment of a detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings, including a sloping wall 1, which is the place where the triangular diagonal brace needs to be supported. The bottom of the sloping wall 1 is fixedly connected to a fixing block 2, which allows one of the diagonal rods 5 of the triangular diagonal brace to rotate. The fixing block 2 is externally fixedly connected to a fixing mechanism 3, and the bottom of the fixing mechanism 3 is fixedly connected to an adjusting mechanism 4. The fixing mechanism 3 fixes the triangular diagonal brace to the sloping wall 1, and the adjusting mechanism adjusts the position of the diagonal rod 5, and also allows the triangular brace to be folded.
[0035] Specifically, the tripod brace is fixed to the inclined wall 1 by the fixing mechanism 3, and the diagonal rod 5 is adjusted by the adjusting mechanism. Under the action of the adjusting mechanism 4 and the fixing block 2, the tripod brace is folded to stabilize it.
[0036] The fixing mechanism 3 includes a housing 31. The right side of the housing 31 is fixedly connected to the left side of the fixing block 2. The housing 31 protects the internal fixing components, ensuring their stable movement and preventing external damage. Two fixing blocks 32 are fixedly connected to the inner wall of the housing 31. A rotating rod is rotatably connected to the adjacent side of each fixing block 32. The fixing blocks 32 are fixed inside the fixing mechanism 3, allowing the rotating rod in the middle to rotate. A rotating plate 33 is fixedly connected to the outside of the rotating rod. A force-bearing plate 35 is rotatably connected to the bottom of the rotating rod. Limiting blocks 34 are rotatably connected to the distant side of each of the two rotating plates 33. A guide plate 36 is fixedly connected to the bottom of the housing 31. Two moving blocks 37 are slidably connected to the top of the guide plate 36. The moving blocks 37 receive external force, thereby applying force to the force-bearing plate 35, causing the rotating plate 33 to rotate, which in turn causes the limiting blocks 34 to move, allowing the inclined wall 1 to contact the housing 31. A limiting component 6 for limiting the movement of the fixing components is fixedly connected to the front side of the moving blocks 37.
[0037] Specifically, under the action of the moving block 37, the force plate 35 receives force, which causes the rotating plate 33 to rotate, thereby causing the limiting block 34 to limit the movement. Under the action of the limiting block 34, the inclined wall 1 and the outer shell 31 come into contact, thereby fixing the triangular brace to the inclined wall 1.
[0038] The limiting component 6 includes a force-applying plate 61, the rear side of which is fixedly connected to the front side of the movable block 37. The force-applying plate 61 receives the pushing force from the operator, thereby moving the movable block 37. A threaded rod 62 is threadedly connected inside the force-applying plate 61, and a fixed plate 63 is slidably connected to the outside of the threaded rod 62. A nut 64 is threadedly connected to the bottom of the threaded rod 62. Both the threaded rod 62 and the nut 64 limit the force-applying plate 61, preventing it from applying force to the movable block 37.
[0039] Specifically, under the operator's action, the force-applying plate 61 moves the movable block 37, and under the action of the threaded rod 62 and nut 64, it fixes the force-applying plate 61. This, in turn, fixes the limiting assembly 6, thus stabilizing the device.
[0040] Reference Figure 2 and Figure 5 The adjusting mechanism 4 includes a crossbar 41, the top of which is fixedly connected to the bottom of the fixing mechanism 3. The crossbar 41 is part of a triangular brace, thus stabilizing it. A movable shell 42 is slidably connected inside the crossbar 41, and the movable shell 42 moves within the crossbar 41 to stabilize it. A telescopic rod 43 is fixedly connected to the right side of the movable shell 42, and a spring 44 is provided on the outside of the telescopic rod 43. The telescopic rod 43 and the spring 44 receive the pushing force of the movable shell 42, thereby stretching and storing elastic force. A telescopic mechanism is fixedly connected to the inner wall of the movable shell 42. The telescopic rod 46 has a spring 47 on its outside. The movable shell 42 is slidably connected to a limit plate 45. The bottom of the movable shell 42 is fixedly connected to a grooved plate 48. The telescopic rod 46 and the spring 47 receive the pushing force of the limit plate 45, thereby compressing and storing elastic force. The limit plate 45 moves outside the movable shell 42, thus limiting the movable shell 42 and preventing it from moving. The grooved plate 48 moves with the movable shell 42 and also provides rotational assistance for other components.
[0041] Specifically, the crossbar 41 provides a moving force to the movable shell 42, causing it to move in a straight line. The movable shell 42 then moves the groove plate 48. The movement of the movable shell 42 causes the telescopic rod 43 and spring 44 to stretch under the action of the movable shell 42, thus storing elastic force. This allows the movable shell 42 to be pulled back to its original position. The movable shell 42 is then limited by the limiting plate 45, which moves downward under the elastic force of the spring 47 and the telescopic rod.
[0042] Reference Figures 1 to 3Two limiting blocks 34 are externally rotatably connected to the inner wall of the inclined wall 1. The limiting blocks 34 receive the rotational force of the rotating plate 33, thus moving. The adjacent sides of the two moving blocks 37 are fixedly connected to the distant sides of the two force plates 35. The moving blocks 37 receive the pushing force of the force plate 61, thus driving the force plate 35 to move. The bottom of the force plate 35 is slidably connected to the top of the guide plate 36. The force plate 35 receives the pushing force, thus sliding on the top of the guide plate 36. The top of the outer shell 31 has a slot, which allows the rotating plate 33 to rotate here and stabilize it. The right side of the telescopic rod 43 is fixedly connected to the right inner wall of the crossbar 41. The telescopic rod receives the tensile force of the moving shell 42, thus storing elastic force inside the crossbar 41. The bottom of plate 48 is rotatably connected to a diagonal rod 5, which together with the two crossbars 41 forms a triangular diagonal brace. The top of the limiting plate 45 is fixedly connected to the bottom of the telescopic rod 46. The telescopic rod 46 applies force to the limiting plate 45 under the action of the spring, so that the limiting plate 45 has a pushing force to limit its moving shell 42. The outside of the limiting plate 45 is slidably connected to the front and rear sides of the crossbar 41. The limiting plate 45 moves in the slot opened on the outside of the crossbar 41, so as to facilitate the limiting of the moving shell 42. The bottom of the force-applying plate 61 is in contact with the top of the nut 64, and the top of the force-applying plate 61 is in contact with the bottom of the fixing plate 63. The threaded rod 62 and the nut 64 are threaded, so that the force-applying plate 61 is fixed under the action of the fixing plate 63.
[0043] Specifically, the force-applying plate 61 applies force to the moving block 37, causing the moving block 37 to drive the force-receiving plate 35 to move, causing the rotating plate 33 to rotate under the top slot of the outer shell 31, thereby limiting the limiting block 34 within the inclined wall 1. The inclined rod 5 and the two horizontal rods 41 together form a triangular inclined brace for stability. Under the action of the telescopic rod 46, the limiting plate 45 limits the moving shell 42. The moving shell 42 is limited, allowing the telescopic rod 43 and the spring 44 to store elastic force inside the horizontal rod 41. Under the action of the thread and the continuous rotation of the nut 64, the force-applying plate 61 is fixed together with the fixed plate 63, thus limiting the force-applying plate 61.
[0044] The implementation principle of this application embodiment is as follows: The operator pushes the force-applying plate 61, causing the force-applying plate 61 to move the moving block 37, thereby causing the moving block 37 to hit the force-receiving plate 35, which in turn causes the rotating rod to drive the rotating plate 33 to rotate, causing the limiting block 34 to rotate, thereby causing the limiting block 34 to be stuck in the inclined wall 1. At this time, the operator causes the threaded rod 62 and nut 64 to limit the force-applying plate 61, thereby fixing the force-applying plate 61, thus realizing the rapid installation of the triangular inclined brace. In addition, it can significantly shorten the construction time of prefabricated suspended buildings, improve the overall construction efficiency, and is easy to install and operate, thereby reducing labor costs and construction difficulty, and adapting to the needs of high-efficiency construction.
[0045] The operator pulls the limiting plate 45 upwards, causing the second spring 47 and the second telescopic rod 46 to compress each other. When the limiting plate 45 moves upwards and disengages from the limiting position on the moving shell 42, the first spring 44 and the first telescopic rod 43 operate, causing the moving shell 42 to move and the diagonal rod 5 to rotate. At this time, one of the diagonal rods 5 rotates and comes into contact with the other horizontal rod 41, thus realizing the folding of the triangular diagonal brace and fixing the triangular diagonal brace frame. In addition, it can improve the installation efficiency of prefabricated suspended buildings, shorten the construction cycle, facilitate disassembly and reuse, reduce material waste and costs, and enhance the flexibility of structural application.
[0046] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be covered within the scope of protection of this application.
Claims
1. A detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings, comprising a sloping wall (1), characterized in that: The bottom of the inclined wall (1) is fixedly connected by a fixing block (2), the outside of the fixing block (2) is fixedly connected by a fixing mechanism (3), and the bottom of the fixing mechanism (3) is fixedly connected by an adjustment mechanism (4). The fixing mechanism (3) includes a housing (31), the right side of which is fixedly connected to the left side of the fixing block one (2). Two fixing blocks two (32) are fixedly connected to the inner wall of the housing (31). A rotating rod is rotatably connected to the adjacent side of the two fixing blocks two (32). A rotating plate (33) is fixedly connected to the outside of the rotating rod. A force plate (35) is rotatably connected to the bottom of the rotating rod. A limit block (34) is rotatably connected to the distant side of the two rotating plates (33). A guide plate (36) is fixedly connected to the bottom of the housing (31). Two moving blocks (37) are slidably connected to the top of the guide plate (36). A limit component (6) for limiting the movement of the fixing component is fixedly connected to the front side of the moving block (37).
2. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 1, characterized in that: The adjusting mechanism (4) includes a crossbar (41), the top of which is fixedly connected to the bottom of the fixing mechanism (3). A movable shell (42) is slidably connected inside the crossbar (41). A telescopic rod (43) is fixedly connected to the right side of the movable shell (42). A spring (44) is provided on the outside of the telescopic rod (43). A telescopic rod (46) is fixedly connected to the inner wall of the movable shell (42). A spring (47) is provided on the outside of the telescopic rod (46). A limit plate (45) is slidably connected to the outside of the movable shell (42). A groove plate (48) is fixedly connected to the bottom of the movable shell (42).
3. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 1, characterized in that: The limiting component (6) includes a force-applying plate (61), the rear side of which is fixedly connected to the front side of the moving block (37). The force-applying plate (61) is internally threaded with a threaded rod (62), the threaded rod (62) is externally slidably connected with a fixing plate (63), and the bottom of the threaded rod (62) is threaded with a nut (64).
4. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 1, characterized in that: The two limiting blocks (34) are externally rotatably connected to the inner wall of the inclined wall (1), and the two moving blocks (37) are fixedly connected to the opposite side of the two force plates (35) on their adjacent sides.
5. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 1, characterized in that: The bottom of the force plate (35) is slidably connected to the top of the guide plate (36), and the top of the outer shell (31) is provided with a slot.
6. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 2, characterized in that: The right side of the telescopic rod (43) is fixedly connected to the right inner wall of the crossbar (41), and the bottom of the groove plate (48) is rotatably connected to the inclined rod (5).
7. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 2, characterized in that: The top of the limiting plate (45) is fixedly connected to the bottom of the telescopic rod (46), and the outside of the limiting plate (45) is slidably connected to the front and rear sides of the crossbar (41).
8. The detachable triangular diagonal brace quick-assembly structure for prefabricated suspended buildings according to claim 3, characterized in that: The bottom of the force-applying plate (61) is in contact with the top of the nut (64), and the top of the force-applying plate (61) is in contact with the bottom of the fixing plate (63).