An assembled vertical prefabricated wallboard component
By combining the design of snap-fit grooves, snap-fit blocks, positioning plates and fastening bolts, the problems of tilting and low assembly/disassembly efficiency of precast wall panel components during the grouting process are solved, achieving rapid assembly and stable connection, and improving the stability and efficiency of use.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SICHUAN HAIJULAI CONSTRUCTION ENGINEERING CO LTD
- Filing Date
- 2025-07-18
- Publication Date
- 2026-06-09
AI Technical Summary
Existing precast wall panel components are prone to tilting during the pouring process, which reduces stability, and they need to be removed as a whole during disassembly, affecting efficiency.
The design employs snap-fit slots and snap-fit blocks to enable rapid assembly. Combined with the fixing method of positioning plates and fastening bolts, it enhances the stability of the connection. Furthermore, the cooperation of movable rods and grounding cones improves the grounding area and anti-slip function.
It enables rapid assembly and disassembly of prefabricated wall panel components, improves connection stability and grouting efficiency, prevents slippage, and enhances stability during use.
Smart Images

Figure CN224338612U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of prefabricated wall panel technology, specifically relating to an assembled vertical prefabricated wall panel component. Background Technology
[0002] Precast wall panels refer to wall components that are prefabricated in a factory. These wall units are quickly assembled and connected on the construction site to form complete building exterior walls or interior partitions. Precast walls are usually made of precast concrete or light steel structures, supplemented by thermal insulation materials, sound insulation materials, waterproof materials, etc., to form a multi-layer structure. Precast wall panels require wall panel components during the pouring process.
[0003] Existing wall panel components involve injecting concrete into the interior of the component during use, allowing it to solidify, and then dismantling the component. However, the impact force generated during the injection process makes the component prone to tilting, reducing its stability. Furthermore, since the components are mostly integrated structures, the entire component must be removed during disassembly and assembly. Therefore, we provide a prefabricated vertical wall panel component. Utility Model Content
[0004] The purpose of this utility model is to provide a prefabricated vertical wall panel component to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a prefabricated vertical wall panel component, comprising a first mold, a second mold, and a positioning plate. A snap-fit block is fixedly connected to one side of the first mold, and a snap-fit groove is provided on one side of the second mold. The snap-fit groove and the snap-fit block are compatible. A set of positioning holes are provided on the first mold and the second mold. A set of fastening bolts is threadedly connected to the positioning plate. The fastening bolts are compatible with the positioning holes. A first movable shaft is fixedly connected to one side of the positioning plate. A movable rod is hinged to the first movable shaft. A second movable shaft is hinged to one end of the movable rod. A base plate is fixedly connected to the bottom of the second movable shaft.
[0006] Using the above method, the snap-fit block on one side of mold No. 1 is inserted into the snap-fit groove on one side of mold No. 2. Utilizing the compatibility between the snap-fit groove and the snap-fit block, rapid assembly is achieved. Next, the positioning plate is attached to the connection between mold No. 1 and mold No. 2, ensuring that the through holes on the positioning plate correspond to the positioning holes. Then, the fastening bolts are screwed into the positioning holes through the through holes on the positioning plate. With the cooperation of the positioning plate, mold No. 1 and mold No. 2 are fixed through the positioning holes, improving the stability of the connection between mold No. 1 and mold No. 2. Similarly, the reverse operation can be performed to quickly remove them, improving the efficiency of wall panel grouting.
[0007] As a preferred embodiment of a prefabricated vertical wall panel component, the positioning plate is provided with a set of through holes, and the positions of the through holes correspond to the positions of the positioning holes.
[0008] By using the above solution and utilizing the through-hole design, the fastening bolts can be quickly screwed into the positioning holes through the positioning plate, making it convenient for users to operate.
[0009] As a preferred embodiment of a prefabricated vertical wall panel component, an I-beam is fixedly connected to the front end of the top of the grounding plate, an installation bolt is threadedly connected to the inner wall of the top of the I-beam, a bearing is movably connected to the bottom of the installation bolt, a movable plate is fixedly connected to the bottom of the bearing, and a set of grounding cones is fixedly connected to the bottom of the movable plate.
[0010] Using the above method, rotating the mounting bolt causes the surface of the mounting bolt and one end to rotate inside the top of the I-beam and the inner ring of the bearing, respectively, which in turn drives the movable plate to move downward. The movable plate then drives the grounding cone to move downward until the grounding cone is inserted into the ground and stops moving, thus preventing the grounding plate from slipping during use.
[0011] As a preferred embodiment of a prefabricated vertical wall panel component, the inner side of the I-frame is provided with a sliding groove, and both sides of the movable plate are fixedly connected with sliders, with one side of the slider slidably connected to the inner wall of the sliding groove.
[0012] By adopting the above solution, the slider is limited by the setting of the slide groove, which helps the movable plate move downward and prevents the movable plate from rotating during use and becoming unable to move downward.
[0013] As a preferred embodiment of a prefabricated vertical wall panel component, the inner wall of the positioning hole is provided with an internal thread, which is adapted to the external thread on the surface of the fastening bolt.
[0014] By adopting the above solution, the compatibility between the threads is utilized to prevent the fastening bolt from getting stuck during rotation, thus improving the smoothness of the fastening bolt rotation.
[0015] In a preferred embodiment of a prefabricated vertical wall panel component, four anti-slip pads are adhered to all four sides of the bottom of the floor.
[0016] By adopting the above solution, the friction between the flooring and the ground is increased by setting up anti-slip mats, thus giving the flooring an anti-slip function.
[0017] Compared with the prior art, the beneficial effects of this utility model are:
[0018] 1. This utility model inserts the snap-fit block on one side of mold No. 1 into the snap-fit groove on one side of mold No. 2. By utilizing the compatibility of the snap-fit groove and the snap-fit block, rapid assembly is achieved. Next, the positioning plate is attached to the connection between mold No. 1 and mold No. 2, and the through hole on the positioning plate corresponds to the positioning hole. Then, the fastening bolt is screwed into the positioning hole through the through hole on the positioning plate. With the cooperation of the positioning plate, mold No. 1 and mold No. 2 are fixed through the positioning hole, which improves the stability of mold No. 1 and mold No. 2 after connection. Similarly, the reverse operation can be used to quickly remove them, which improves the efficiency of wall panel grouting.
[0019] 2. This utility model increases the grounding area of the component and improves the stability of the component during use by changing the angle of the movable rod, which drives the second movable shaft to move through one end of the movable rod, and the second movable shaft drives the grounding plate to move until the grounding plate contacts the ground and the movement stops.
[0020] 3. This utility model rotates the mounting bolt, causing the surface of the mounting bolt and one end to rotate inside the top of the I-beam frame and the inner ring of the bearing, respectively. This rotation drives the movable plate to move downwards, which in turn drives the grounding cone downwards until the grounding cone is inserted into the ground and stops moving. This prevents the grounding plate from slipping during use. Attached Figure Description
[0021] Figure 1 This is a schematic diagram of the structure of this utility model;
[0022] Figure 2 This is a second-view schematic diagram of the present invention;
[0023] Figure 3 This is a schematic diagram showing the connection between mold No. 1 and mold No. 2 of this utility model.
[0024] In the diagram: 1. Mold No. 1; 2. Mold No. 2; 3. Snap-fit groove; 4. Snap-fit block; 5. Positioning hole; 6. Positioning plate; 7. Fastening bolt; 8. Movable shaft No. 1; 9. Movable rod; 10. Movable shaft No. 2; 11. Grounding plate; 12. I-beam frame; 13. Movable plate; 14. Bearing; 15. Mounting bolt; 16. Grounding cone. Detailed Implementation
[0025] Please see Figure 1-3A prefabricated vertical wall panel component includes a first mold 1, a second mold 2, and a positioning plate 6. A snap-fit block 4 is fixedly connected to one side of the first mold 1. A snap-fit groove 3 is formed on one side of the second mold 2, and the snap-fit groove 3 and the snap-fit block 4 are compatible. A set of positioning holes 5 are formed on the first mold 1 and the second mold 2. A set of fastening bolts 7 are threaded onto the positioning plate 6, and the fastening bolts 7 are compatible with the positioning holes 5. A first movable shaft 8 is fixedly connected to one side of the positioning plate 6. A movable rod 9 is hinged to the first movable shaft 8. A second movable shaft 10 is hinged to one end of the movable rod 9. A base plate 11 is fixedly connected to the bottom of the second movable shaft 10. (See...) Figure 1 As shown, an I-beam frame 12 is fixedly connected to the front end of the top of the floor plate 11. Figure 1 As shown, a sliding groove is provided on the inner side of the I-beam frame 12. Slider blocks are fixedly connected to both sides of the movable plate 13, and one side of the slider is slidably connected to the inner wall of the sliding groove. The sliding groove limits the slider, assisting the movable plate 13 in moving downwards and preventing it from rotating and becoming unable to move downwards during use. A mounting bolt 15 is threadedly connected to the inner wall of the top of the I-beam frame 12. A bearing 14 is movably connected to the bottom of the mounting bolt 15. The movable plate 13 is fixedly connected to the bottom of the bearing 14. A set of grounding cones 16 are fixedly connected to the bottom of the movable plate 13. Rotating the mounting bolt 15 causes its surface and one end to rotate within the top of the I-beam frame 12 and the inner ring of the bearing 14, respectively, thus driving the movable plate 13 to move downwards. The grounding cone 16 is moved downwards until it is inserted into the ground and stops moving to prevent the grounding plate 11 from sliding during use. The snap-fit block 4 on one side of mold 1 is inserted into the snap-fit groove 3 on one side of mold 2. The snap-fit groove 3 and snap-fit block 4 are compatible to achieve quick assembly. Next, the positioning plate 6 is attached to the connection between mold 1 and mold 2, and the through hole on the positioning plate 6 is aligned with the positioning hole 5. Then, the fastening bolt 7 is screwed into the positioning hole 5 through the through hole on the positioning plate 6. With the cooperation of the positioning plate 6, mold 1 and mold 2 are fixed through the positioning hole 5, which improves the stability of the connection between mold 1 and mold 2. Similarly, the reverse operation can be used to quickly remove them, which improves the efficiency of wall panel grouting.
[0026] See Figure 1As shown, a set of through holes are provided on the positioning plate 6, and the positions of the through holes correspond to the positions of the positioning holes 5. By using the through holes, the fastening bolt 7 can be quickly screwed into the positioning hole 5 through the positioning plate 6, which is convenient for the user to operate. The inner wall of the positioning hole 5 is provided with internal threads, which are adapted to the external threads on the surface of the fastening bolt 7. By using the compatibility between the threads, the fastening bolt 7 is prevented from getting stuck during rotation, which improves the smoothness of the fastening bolt 7 during rotation. Anti-slip pads are glued to all four sides of the bottom of the grounding plate 11, and there are four anti-slip pads. The anti-slip pads increase the friction between the grounding plate 11 and the ground and make the grounding plate 11 have an anti-slip function.
[0027] In use, firstly, insert the snap-fit block 4 on one side of mold 1 into the snap-fit groove 3 on one side of mold 2. Utilizing the compatibility of the snap-fit groove 3 and snap-fit block 4, quick assembly is achieved. Next, attach the positioning plate 6 to the connection point of mold 1 and mold 2, ensuring the through hole on the positioning plate 6 corresponds to the positioning hole 5. Then, screw the fastening bolt 7 through the through hole on the positioning plate 6 into the positioning hole 5. With the cooperation of the positioning plate 6 and the positioning hole 5, mold 1 and mold 2 are fixed, improving the stability of the connection. Similarly, the reverse operation allows for quick removal, improving the efficiency of wall panel grouting. During the process, by changing the angle of the movable rod 9, one end of the movable rod 9 drives the second movable shaft 10 to move, which in turn drives the grounding plate 11 to move until the grounding plate 11 contacts the ground and stops moving. This increases the grounding area of the component and improves the stability of the component during use. Finally, the mounting bolt 15 is rotated, causing the surface of the mounting bolt 15 and one end to rotate in the inside of the top of the I-beam frame 12 and the inner ring of the bearing 14, respectively. This causes the movable plate 13 to move downward, which in turn drives the grounding cone 16 to move downward until the grounding cone 16 is inserted into the ground and stops moving, preventing the grounding plate 11 from slipping during use.
Claims
1. A prefabricated vertical wall panel component, characterized in that: The system includes a first mold (1), a second mold (2), and a positioning plate (6). A snap-fit block (4) is fixedly connected to one side of the first mold (1), and a snap-fit groove (3) is provided on one side of the second mold (2). The snap-fit groove (3) and the snap-fit block (4) are compatible with each other. A set of positioning holes (5) are provided on the first mold (1) and the second mold (2). A set of fastening bolts (7) are threadedly connected to the positioning plate (6). The fastening bolts (7) are compatible with the positioning holes (5). A first movable shaft (8) is fixedly connected to one side of the positioning plate (6). A movable rod (9) is hinged to the first movable shaft (8). A second movable shaft (10) is hinged to one end of the movable rod (9). A base plate (11) is fixedly connected to the bottom of the second movable shaft (10).
2. The prefabricated vertical wall panel component according to claim 1, characterized in that: The positioning plate (6) has a set of through holes, and the positions of the through holes correspond to the positions of the positioning holes (5).
3. A prefabricated vertical wall panel component according to claim 1, characterized in that: The front end of the top of the grounding plate (11) is fixedly connected to an I-beam frame (12), the inner wall of the top of the I-beam frame (12) is threaded with a mounting bolt (15), the bottom of the mounting bolt (15) is movably connected to a bearing (14), the bottom of the bearing (14) is fixedly connected to a movable plate (13), and the bottom of the movable plate (13) is fixedly connected to a set of grounding cones (16).
4. A prefabricated vertical wall panel component according to claim 3, characterized in that: The inner side of the I-frame (12) is provided with a sliding groove, and both sides of the movable plate (13) are fixedly connected with sliders, and one side of the slider is slidably connected to the inner wall of the sliding groove.
5. A prefabricated vertical wall panel component according to claim 1, characterized in that: The inner wall of the positioning hole (5) is provided with an internal thread, which is adapted to the external thread on the surface of the fastening bolt (7).
6. A prefabricated vertical wall panel component according to claim 1, characterized in that: The bottom of the grounding plate (11) is covered with four anti-slip pads.