A standardized fast-built fabricated building

CN224412865UActive Publication Date: 2026-06-26GUANGDONG YUECHI CONSTR TECH GRP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG YUECHI CONSTR TECH GRP CO LTD
Filing Date
2025-06-18
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

In existing prefabricated buildings, the position of the walls is prone to deviation during installation, and effective fine-tuning is not possible, resulting in poor installation results.

Method used

By employing adjustment and clamping components, the angle and position of the wall panel are synchronously adjusted through the coordinated movement of the sliding plate, telescopic support rod, and U-shaped plate. This is achieved using a motor, enabling synchronous control of the wall panel. The system includes an adjustment screw, linkage components, and clamping components, with the motor driving the fine-tuning and fixing of the wall panel.

Benefits of technology

It enables accurate installation of wall panels, improves installation efficiency, avoids damage to wall panels, and simplifies the installation process.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a kind of standardization quick build's fabricated building, it is related to fabricated building field, including: bottom plate and the wallboard being set on bottom plate, the top of bottom plate is fixed with support plate, the top of support plate is slidably equipped with two sliding plates, a kind of standardization quick build's fabricated building based on the embodiment of the application, under the telescopic movement of telescopic support rod, the rotation of wallboard is driven, the angle of wallboard is adjusted, if the deviation of the placement position of wallboard occurs, under the movement of adjusting assembly, the synchronous movement of two sliding plates is driven, two sliding plates drive the synchronous movement of two first connecting seats, two first connecting seats drive the synchronous movement of two telescopic support rods, two telescopic support rods are driven synchronous movement of two second connecting seats, to drive the synchronous movement of two U-shaped plates, two U-shaped plates can promote the movement of wallboard, the position of wallboard is fine-tuned, to facilitate the accurate installation of wallboard, improve the installation effect of wallboard.
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Description

Technical Field

[0001] This utility model relates to the field of prefabricated buildings, and in particular to a standardized and rapidly assembled prefabricated building. Background Technology

[0002] Prefabricated buildings are constructed by assembling prefabricated components on-site. This method transfers a large amount of on-site work from traditional construction to factories. Building components and accessories (such as floor slabs, wall panels, stairs, balconies, etc.) are processed and manufactured in factories, transported to the construction site, and assembled and installed on-site using reliable connection methods.

[0003] The related technology includes prefabricated building transverse walls, prefabricated building longitudinal walls, and node connecting hinges. The angle between the first and second hinges can be adjusted according to the installation angle requirements of the prefabricated building wall, allowing them to be attached to the wall surface. A triangular support rod is hinged between the first and second hinges. Based on the rotation angle of the first and second hinges, a fixing plate at one end of the triangular support rod presses against the first hinge and is reinforced with fastening bolts. This creates a triangular structural system connecting the first hinge, the triangular support rod, and the second hinge, providing excellent connection and support for the prefabricated building transverse and longitudinal walls. It is also easy to install and disassemble, causes no drilling damage to the prefabricated building wall, and is reusable.

[0004] Although the wall can be angled and supported by the cooperation of the first hinge, the triangular support rod and the second hinge, the initial position of the wall is often inaccurate during actual installation. This makes it easy for the wall to be misaligned during installation. This technology can only adjust the angle of the wall, but cannot fine-tune the position of the wall. This makes it difficult to install the wall accurately and reduces the installation effect.

[0005] Therefore, it is necessary to provide a standardized and rapidly assembled prefabricated building to solve the above-mentioned technical problems. Utility Model Content

[0006] To solve the above-mentioned technical problems, this utility model provides a standardized and rapidly assembled prefabricated building.

[0007] This utility model provides a standardized and rapidly assembled prefabricated building, comprising: a base plate and wall panels disposed on the base plate. A support plate is fixed to the top of the base plate, and two sliding plates are slidably disposed on the top of the support plate. A first connecting seat is fixed to the top of each of the two sliding plates, and a telescopic support rod is disposed at the top of each of the two first connecting seats. Two U-shaped plates are engaged with the top of the wall panels, and a second connecting seat connected to the telescopic support rod is fixed to one side of each of the two U-shaped plates.

[0008] An adjustment assembly, located at the top of the support plate, is connected to two sliding plates respectively and is used to drive the movement of the sliding plates.

[0009] Preferably, the adjustment assembly includes a first slider fixedly disposed at the bottom ends of two slide plates, a first groove for sliding the first slider is provided at the top end of the support plate, an adjustment screw threadedly connected to the first slider is rotatably connected in the first groove, and a first drive motor fixed to the adjustment screw is fixed on one side of the support plate.

[0010] Preferably, the telescopic support rod includes a first support rod rotatably mounted on a first connecting seat, a second support rod rotatably mounted on the top end of the first support rod and connected to the second connecting seat, a telescopic screw threadedly connected to the second support rod and rotatably mounted inside the first support rod, and a linkage component for driving the telescopic screw to move is provided on one side of the first support rod.

[0011] Preferably, the linkage assembly includes a rotating rod rotatably disposed between two first support rods, two first bevel gears sleeved on the outer wall of the rotating rod, and a second bevel gear meshing with the first bevel gears fixed at the bottom ends of the two telescopic screws, and a second drive motor fixed to the rotating rod on one side of the first support rod.

[0012] Preferably, the U-shaped plate is provided with two slidable clamping plates, and the U-shaped plate is provided with a clamping assembly that drives the clamping plates to move. Anti-wear plates are fixed on opposite sides of the two clamping plates, and multiple anti-slip protrusions are fixed on opposite sides of the two anti-wear plates.

[0013] Preferably, the clamping assembly includes a second slider fixedly disposed at the top of the two clamping plates, a second groove for sliding the second slider is provided at the top of the inner wall of the U-shaped plate, a bidirectional lead screw threadedly connected to the second slider is rotatably connected in the second groove, and a third drive motor fixed to the bidirectional lead screw is fixed on one side of the U-shaped plate.

[0014] Compared with related technologies, the standardized and rapidly assembled prefabricated building provided by this utility model has the following beneficial effects:

[0015] 1. A standardized and rapidly assembled prefabricated building based on an embodiment of this application involves first fixing a support plate to the base plate with bolts when installing wall panels, and then fixing a U-shaped plate to the wall panel. The extension and retraction of the telescopic support rods causes the wall panel to rotate, adjusting its angle. If the wall panel's placement deviates, the movement of the adjustment component causes two sliding plates to move synchronously. These two sliding plates then cause two first connecting seats to move synchronously, which in turn cause two telescopic support rods to move synchronously. These telescopic support rods, in turn, cause two second connecting seats to move synchronously, thereby causing the two U-shaped plates to move synchronously. The two U-shaped plates then push the wall panel to move, fine-tuning its position and facilitating accurate installation, thus improving the wall panel's installation effect.

[0016] 2. A standardized and rapidly assembled prefabricated building based on an embodiment of this application, wherein when the U-shaped plate is clamped onto the wall panel, the movement of the clamping components drives the two clamping plates to move towards each other, and the two clamping plates drive the two anti-wear plates to move towards each other, so that the anti-slip protrusions on the anti-wear plates come into contact with the wall panel. In this way, with the cooperation of the clamping plates, anti-wear plates and anti-slip protrusions, the U-shaped plate can be clamped and fixed onto the wall panel, which facilitates the rapid installation and fixing of the U-shaped plate, avoids damage to the wall panel caused by bolts or other means, facilitates the installation of the U-shaped plate, and improves the installation efficiency of the U-shaped plate. Attached Figure Description

[0017] Figure 1 A schematic diagram of a preferred embodiment of this utility model;

[0018] Figure 2 A cross-sectional structural diagram of a telescopic support rod according to a preferred embodiment of this utility model;

[0019] Figure 3 A preferred embodiment of the present invention is provided. Figure 2 A magnified view of the structure at point A in the middle;

[0020] Figure 4 A schematic diagram of the cross-sectional structure of a U-shaped plate according to a preferred embodiment of this utility model.

[0021] The following are the labeling elements in the diagram: 1. Base plate; 2. Wall panel; 3. Support plate; 4. Slide plate; 5. First connecting seat; 6. Telescopic support rod; 61. First support rod; 62. Second support rod; 63. Telescopic lead screw; 7. U-shaped plate; 8. Second connecting seat; 9. Adjustment assembly; 91. First slider; 92. First slide groove; 93. Adjustment lead screw; 94. First drive motor; 10. Linkage assembly; 101. Rotating rod; 102. First bevel gear; 103. Second bevel gear; 104. Second drive motor; 11. Clamping plate; 12. Clamping assembly; 121. Second slider; 122. Second slide groove; 123. Bidirectional lead screw; 124. Third drive motor; 13. Wear-resistant plate; 14. Anti-slip protrusion. Detailed Implementation

[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0023] Please refer to the following: Figures 1 to 4 A standardized and rapidly assembled prefabricated building includes: a base plate 1 and wall panels 2 set on the base plate 1. A support plate 3 is fixed to the top of the base plate 1. Two sliding plates 4 are slidably provided on the top of the support plate 3. A first connecting seat 5 is fixed to the top of each of the two sliding plates 4. A telescopic support rod 6 is provided at the top of each of the two first connecting seats 5. Two U-shaped plates 7 are engaged and connected to the top of the wall panels 2. A second connecting seat 8 connected to the telescopic support rod 6 is fixed on one side of each of the two U-shaped plates 7.

[0024] Adjustment component 9 is located at the top of support plate 3. Adjustment component 9 is connected to two slide plates 4 respectively and is used to drive the movement of slide plates 4.

[0025] In this embodiment, when installing wall panel 2 on base plate 1, support plate 3 is first fixed to base plate 1 with bolts, etc., and then U-shaped plate 7 is fixed to wall panel 2. In this way, the extension and retraction of telescopic support rod 6 can drive the rotation of wall panel 2 and adjust the angle of wall panel 2. If the placement position of wall panel 2 is deviated, the movement of adjustment component 9 drives the synchronous movement of two sliding plates 4. The two sliding plates 4 drive the synchronous movement of two first connecting seats 5. The two first connecting seats 5 drive the synchronous movement of two telescopic support rods 6. The two telescopic support rods 6 drive the synchronous movement of two second connecting seats 8, thereby driving the synchronous movement of two U-shaped plates 7. The two U-shaped plates 7 can push the movement of wall panel 2 and make fine adjustments to the position of wall panel 2, thereby facilitating the accurate installation of wall panel 2 and improving the installation effect of wall panel 2. In addition, in order to facilitate the movement of wall panel 2, rollers or other mechanisms can be added to the bottom of wall panel 2 to facilitate the pushing of wall panel 2. Then, the above operation can be repeated to install and fix other wall panels 2.

[0026] In a further embodiment, such as Figure 2As shown, the adjustment assembly 9 includes a first slider 91 fixedly disposed at the bottom of the two slide plates 4 respectively, a first groove 92 for the first slider 91 to slide on the top of the support plate 3, an adjustment screw 93 rotatably connected to the first slider 91 in the first groove 92, and a first drive motor 94 fixed to the adjustment screw 93 on one side of the support plate 3.

[0027] In this embodiment, when the wall panel 2 needs to be fine-tuned, the first drive motor 94 drives the adjustment screw 93 to rotate. The adjustment screw 93 drives the two first sliders 91 to move synchronously. The two first sliders 91 drive the two slide plates 4 to move synchronously. The two slide plates 4 can drive the two telescopic support rods 6 to move synchronously. The two telescopic support rods 6 can drive the two U-shaped plates 7 to move synchronously, thereby pushing the wall panel 2 to move and fine-tune the position of the wall panel 2, which facilitates the adjustment of the position of the wall panel 2.

[0028] In a further embodiment, such as Figure 2-3 As shown, the telescopic support rod 6 includes a first support rod 61 rotatably mounted on the first connecting seat 5. A second support rod 62, which rotates with the second connecting seat 8, is inserted through the top of the first support rod 61. A telescopic screw 63, which is threadedly connected to the second support rod 62, is rotatably connected inside the first support rod 61. A linkage assembly 10, which drives the telescopic screw 63, is provided on one side of the first support rod 61. The linkage assembly 10 includes a rotating rod 101 rotatably mounted between the two first support rods 61. Two first bevel gears 102 are sleeved on the outer wall of the rotating rod 101. The bottom ends of the two telescopic screws 63 are each fixed with a second bevel gear 103 that meshes with the first bevel gear 102. A second drive motor 104, which is fixed to the rotating rod 101, is fixed on one side of the first support rod 61.

[0029] In this embodiment, the second drive motor 104 drives the rotating rod 101 to rotate. The rotating rod 101 drives the two first bevel gears 102 to rotate synchronously. The two first bevel gears 102 drive the two second bevel gears 103 to rotate synchronously. The two second bevel gears 103 drive the two telescopic screw rods 63 to rotate synchronously. As the two telescopic screw rods 63 rotate, they can drive the two second support rods 62 to move synchronously, thereby adjusting the length of the two telescopic support rods 6 synchronously. During the length adjustment of the telescopic support rods 6, the wall panel 2 can be pulled to move, and the angle of the wall panel 2 can be adjusted to facilitate the vertical installation of the wall panel 2.

[0030] In a further embodiment, such as Figure 4 As shown, two clamping plates 11 are slidably provided inside the U-shaped plate 7. A clamping assembly 12 is provided inside the U-shaped plate 7 to drive the clamping plates 11 to move. Anti-wear plates 13 are fixed on opposite sides of the two clamping plates 11, and multiple anti-slip protrusions 14 are fixed on opposite sides of the two anti-wear plates 13.

[0031] In this embodiment, when the U-shaped plate 7 is clamped on the wall panel 2, the movement of the clamping assembly 12 drives the two clamping plates 11 to move towards each other. The two clamping plates 11 drive the two anti-wear plates 13 to move towards each other, so that the anti-slip protrusions 14 on the anti-wear plates 13 come into contact with the wall panel 2. In this way, with the cooperation of the clamping plates 11, the anti-wear plates 13 and the anti-slip protrusions 14, the U-shaped plate 7 can be clamped and fixed on the wall panel 2, which facilitates the quick installation and fixing of the U-shaped plate 7, avoids damage to the wall panel 2 caused by bolts or other means, facilitates the installation of the U-shaped plate 7, and improves the installation efficiency of the U-shaped plate 7.

[0032] In a further embodiment, such as Figure 4 As shown, the clamping assembly 12 includes a second slider 121 fixedly disposed at the top of the two clamping plates 11 respectively. A second groove 122 for sliding the second slider 121 is provided at the top of the inner wall of the U-shaped plate 7. A bidirectional lead screw 123 threadedly connected to the second slider 121 is rotatably connected in the second groove 122. A third drive motor 124 fixed to the bidirectional lead screw 123 is fixed on one side of the U-shaped plate 7.

[0033] In this embodiment, the third drive motor 124 drives the bidirectional lead screw 123 to rotate, and the bidirectional lead screw 123 drives the two second sliders 121 to move in opposite directions. The two second sliders 121 drive the two clamping plates 11 to move in opposite directions, which facilitates the clamping and fixing of the wall panel 2, thereby facilitating the installation and fixing of the U-shaped plate 7.

[0034] The working principle of this standardized and rapid-assembly prefabricated building provided by this utility model is as follows: When installing the wall panel 2 on the base plate 1, first fix the support plate 3 to the base plate 1 with bolts, etc., and then clamp the U-shaped plate 7 onto the wall panel 2. Under the movement of the third drive motor 124, the bidirectional lead screw 123 is driven to rotate. The bidirectional lead screw 123 drives the two second sliders 121 to move in opposite directions. The two second sliders 121 drive the two clamping plates 11 to move in opposite directions. The two clamping plates 11 drive the two... The anti-wear plates 13 move towards each other, causing the anti-slip protrusions 14 on the anti-wear plates 13 to contact the wall panel 2. With the cooperation of the clamping plate 11, the anti-wear plates 13, and the anti-slip protrusions 14, the U-shaped plate 7 can be clamped and fixed onto the wall panel 2, facilitating the quick installation and fixing of the U-shaped plate 7 and avoiding damage to the wall panel 2 caused by bolts or other methods. This improves the installation efficiency of the U-shaped plate 7. Under the movement of the second drive motor 104, the rotating rod 101 is driven to rotate, and the rotating rod 101 drives the two first... The synchronous rotation of the bevel gears 102 drives the synchronous rotation of the two second bevel gears 103, which in turn drives the synchronous rotation of the two telescopic screw rods 63. The rotation of the two telescopic screw rods 63 drives the synchronous interlacing movement of the two second support rods 62, thereby synchronously adjusting the length of the two telescopic support rods 6. This length adjustment pulls the wall panel 2, adjusting its angle. If the wall panel 2 is misaligned, the first drive motor 94 rotates the adjusting screw rod 93, which in turn drives the synchronous movement of the two first sliders 91. The two first sliders 91 then drive the synchronous movement of the two sliding plates 4, which in turn drives the synchronous movement of the two telescopic support rods 6. The two telescopic support rods 6 then drive the synchronous movement of the two U-shaped plates 7, thus propelling the wall panel 2 and fine-tuning its position. This facilitates accurate installation of the wall panel 2 and improves its installation effect.

[0035] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the content of this utility model specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.

Claims

1. A standardized, rapidly assembled prefabricated building, characterized in that, include: The base plate (1) and the wall panel (2) set on the base plate (1) are provided. The top of the base plate (1) is fixed with a support plate (3). The top of the support plate (3) is slidably provided with two sliding plates (4). The top of each of the two sliding plates (4) is fixed with a first connecting seat (5). The top of each of the two first connecting seats (5) is provided with a telescopic support rod (6). The top of the wall panel (2) is engaged with two U-shaped plates (7). One side of each of the two U-shaped plates (7) is fixed with a second connecting seat (8) connected to the telescopic support rod (6). An adjustment component (9) is disposed at the top of the support plate (3). The adjustment component (9) is connected to two slide plates (4) respectively and is used to drive the movement of the slide plates (4).

2. The standardized and rapidly assembled prefabricated building according to claim 1, characterized in that, The adjustment assembly (9) includes a first slider (91) fixedly disposed at the bottom of the two slide plates (4). The top of the support plate (3) is provided with a first groove (92) for the first slider (91) to slide. An adjustment screw (93) threadedly connected to the first slider (91) is rotatably connected in the first groove (92). A first drive motor (94) fixed to the adjustment screw (93) is fixed on one side of the support plate (3).

3. A standardized, rapidly assembled prefabricated building according to claim 2, characterized in that, The telescopic support rod (6) includes a first support rod (61) rotatably mounted on the first connecting seat (5), a second support rod (62) rotatably mounted on the second connecting seat (8) is inserted at the top of the first support rod (61), a telescopic screw (63) threadedly connected to the second support rod (62) is rotatably mounted inside the first support rod (61), and a linkage assembly (10) for driving the telescopic screw (63) to move is provided on one side of the first support rod (61).

4. A standardized, rapidly assembled prefabricated building according to claim 3, characterized in that, The linkage assembly (10) includes a rotating rod (101) rotatably disposed between two first support rods (61). Two first bevel gears (102) are sleeved on the outer wall of the rotating rod (101). The bottom ends of the two telescopic screws (63) are each fixed with a second bevel gear (103) that meshes with the first bevel gear (102). A second drive motor (104) that is fixed to the rotating rod (101) is fixed on one side of the first support rod (61).

5. A standardized, rapidly assembled prefabricated building according to claim 1, characterized in that, The U-shaped plate (7) is provided with two slidable clamping plates (11). The U-shaped plate (7) is provided with a clamping assembly (12) that drives the clamping plates (11) to move. Abrasion-resistant plates (13) are fixed on opposite sides of the two clamping plates (11). Multiple anti-slip protrusions (14) are fixed on opposite sides of the two anti-slip plates (13).

6. A standardized, rapidly assembled prefabricated building according to claim 5, characterized in that, The clamping assembly (12) includes a second slider (121) fixedly disposed at the top of the two clamping plates (11). The top of the inner wall of the U-shaped plate (7) is provided with a second slide groove (122) for the second slider (121) to slide. A bidirectional lead screw (123) threadedly connected to the second slider (121) is rotatably connected in the second slide groove (122). A third drive motor (124) fixed to the bidirectional lead screw (123) is fixed on one side of the U-shaped plate (7).