Integrated construction structure of prefabricated building PCF panels and aluminum formwork bracing
By pre-embedding side and bottom components within the PCF board to connect support rods, the splicing of the aluminum formwork and the fixed module is achieved, solving the problem of poor stability of the PCF board after the aluminum formwork is removed, and improving construction safety and efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU HAOSEN BUILDING DESIGN CO LTD
- Filing Date
- 2025-05-23
- Publication Date
- 2026-06-30
Smart Images

Figure CN224431995U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of construction structure of PCF board and aluminum formwork, specifically to an integrated construction structure of PCF board and aluminum formwork diagonal bracing for prefabricated buildings. Background Technology
[0002] In existing engineering construction processes, PCF panel installation typically requires the use of temporary diagonal bracing for reinforcement. However, when installing aluminum formwork, these diagonal bracing must be removed, which makes the outer panels highly susceptible to displacement or falling due to loss of support.
[0003] This results in the PCF slab being fixed solely by the slab connectors at the beam and the curb after the diagonal bracing is removed. Before concrete pouring, its stability is poor, posing a significant safety risk. Furthermore, the diagonal bracing requires repeated disassembly and reassembly, which undoubtedly increases the time required for the process and reduces construction efficiency. At the same time, the process of removing the diagonal bracing can easily disturb the positioning of the PCF slab, thereby affecting its verticality and flatness and reducing construction quality. Utility Model Content
[0004] The purpose of this utility model is to provide an integrated construction structure for prefabricated building PCF panels and aluminum formwork diagonal bracing. By installing the assembled aluminum formwork on the side of the fixed module, the support rods no longer need to be disassembled compared to the installation of the corresponding aluminum formwork. The support rods can always support the PCF panel, improving the stability of the PCF panel and the safety of construction.
[0005] This utility model provides the following technical solution: an integrated construction structure of prefabricated building PCF panel and aluminum formwork bracing, including a PCF panel set on a base plate, characterized in that: a side embedded part is pre-embedded in the PCF panel, the end face of the side embedded part is flush with the end face of the PCF panel, a fixing module is connected to the end face of the side embedded part, and aluminum formwork is spliced on both sides of the fixing module, the aluminum formwork includes multiple splicing plates, the multiple splicing plates are spliced to form the groove of the fixing module, the splicing plates are all located on the side of the fixing module and are attached to the end face of the fixing module.
[0006] In one embodiment, there are two splicing panels, including a first splicing panel and a second splicing panel. A first splicing groove is formed on one side of the first splicing panel, and a second splicing groove is formed on one side of the second splicing panel. The first splicing groove and the second splicing groove constitute the slot for fixing the module.
[0007] In another embodiment, there are three splicing panels, including a first splicing panel, a second splicing panel, and a third splicing panel. The first splicing panel and the second splicing panel are symmetrically distributed. The first splicing panel and the second splicing panel are respectively provided with symmetrical first splicing grooves and second splicing grooves. The first splicing grooves and the second splicing grooves are spliced together to form a groove that matches the shape of the fixed module. The third splicing panel is in the shape of an isosceles trapezoid.
[0008] Furthermore, the edges of the first, second, and third splicing plates are all formed with folded edges, and round holes are evenly provided on the folded edges. Bolts are connected in the round holes on adjacent different folded edges to connect adjacent splicing plates. Adjacent different splicing plates are connected together by the folded edges.
[0009] Furthermore, a bottom embedded part is also pre-embedded on the base plate, and a support rod is connected between the bottom embedded part and the side embedded part. The support rod supports the aluminum mold and the PCF plate, so that the PCF plate can remain stable.
[0010] Furthermore, the support rod includes connectors at both ends, with the two connectors respectively connected to the bottom embedded part and the side embedded part. The two ends of the support rod are threadedly connected to the two connectors respectively. The detachable connection between the support rod and the connectors makes the installation of the support rod more convenient.
[0011] Furthermore, the back of the aluminum mold is also connected to a back rib, which enhances the rigidity and strength between the aluminum molds and reduces the deformation of the aluminum mold during casting.
[0012] Compared with the prior art, the beneficial effects achieved by this utility model are: by connecting the fixing module to the side embedded part and using the assembled aluminum mold to connect the aluminum mold to the side of the fixing module, the installation of the aluminum mold no longer requires the disassembly of the support rod. In this way, the support rod can always support the PCF board, which improves the stability of the PCF board and the safety of construction. Attached Figure Description
[0013] The accompanying drawings are provided to further illustrate the present invention and form part of the specification. They are used together with the embodiments of the present invention to explain the present invention, but do not constitute a limitation thereof. In the drawings:
[0014] Figure 1 This is a schematic diagram of the structure of the aluminum mold and the diagonal brace of this utility model;
[0015] Figure 2 This is a schematic diagram of the structure of the split aluminum mold of this utility model;
[0016] Figure 3 This is a structural schematic diagram of Embodiment 2 of this utility model;
[0017] In the diagram: 1. First splicing plate; 11. First splicing groove; 2. Second splicing plate; 21. Second splicing groove; 3. Outer leaf plate; 4. Inner leaf plate; 5. Insulation layer; 6. Side embedded part; 7. Bottom embedded part; 8. Support rod; 81. Connector; 9. Base plate; 10. Fixing module; 20. Third splicing plate; 30. Back rib. Detailed Implementation
[0018] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0019] Please see Figure 1 This utility model provides a technical solution: an integrated construction structure for prefabricated building PCF panels and aluminum formwork bracing, including PCF panels installed on a base plate 9, wherein the PCF panel includes an outer sheet 3, an insulation layer 5, and an inner sheet 4. A side embedded part 6 is pre-embedded inside the PCF board. One end of the side embedded part 6 is embedded in the outer page plate 3, and the other end is embedded in the inner page plate 4. The end face of the side embedded part 6 is flush with the end face of the inner page plate 4 of the PCF board. A fixing module 10 is connected to the end face of the side embedded part 6. Aluminum molds are spliced on both sides of the fixing module 10. The end face of the aluminum molds and the end face of the fixing module 10 are on the same plane. The aluminum molds include multiple splicing plates, which are spliced to form the groove of the fixing module 10. The splicing plates are all located on the side of the fixing module 10 and fit against the end face of the fixing module 10. By using the splicing aluminum mold, it is convenient to install the aluminum mold on the side of the fixing module 10. Compared with the existing aluminum mold installation process, it is no longer necessary to disassemble the support rod 8, reducing the disassembly process, improving the installation efficiency of the aluminum mold and the stability of the PCF board, ensuring the support of the PCF board during the installation of the aluminum mold, and further ensuring the safety of construction.
[0020] like Figure 2 As shown, there are two splicing plates, including a first splicing plate 1 and a second splicing plate 2. The first splicing plate 1 has a first splicing groove 11 formed on one side, and the second splicing plate 2 has a second splicing groove 21 formed on one side. The first splicing groove 11 and the second splicing groove 21 form the groove of the fixing module 10. The groove is used to wrap the fixing module 10, so that the support rod 8 can be installed on the side of the fixing module 10 without disassembling, thus completing the installation of the aluminum formwork. This reduces the disassembly process, ensures the support force on the PCF plate, and improves the safety of construction.
[0021] Both the first splicing plate 1 and the second splicing plate 2 have folded edges formed on their edges, with evenly spaced round holes. Bolts are used to connect the round holes on the folded edges of adjacent splicing plates, thus connecting the adjacent splicing plates together. The bolts are used to connect the folded edges of different splicing plates together, making the connection between the first splicing plate 1 and the second splicing plate 2 stable. The edge of the fixing module 10 is also formed with folded edges, which facilitates the connection of the fixing module 10 to the first splicing plate 1 and the second splicing plate 2 and maintains a seal.
[0022] The bottom embedded part 7 is also pre-embedded on the base plate 9. A support rod 8 is connected between the bottom embedded part 7 and the side embedded part 6. The support rod 8 supports the PCF plate to ensure the stability of the PCF plate and the safety of construction.
[0023] The support rod 8 includes connectors 81 at both ends. The two connectors 81 are respectively connected to the bottom embedded part 7 and the side embedded part 6. The two ends of the support rod 8 are threadedly connected to the two connectors 81. The threaded connection between the connectors 81 and the support rod 8 makes the disassembly of the support rod 8 more convenient and improves the installation efficiency of the support rod 8.
[0024] The back of the aluminum mold is also connected to a back rib 30. Small holes are opened on the PCF plate, and studs are inserted into the small holes. The back rib 30 is connected to the bolts using bolts, so that the back rib 30 is tightened on the back of the aluminum mold, which enhances the rigidity and strength of the aluminum mold and reduces the deformation of the aluminum mold during casting. Example 2
[0025] like Figure 3 As shown, there are three splicing plates, including a first splicing plate 1, a second splicing plate 2, and a third splicing plate 20. The first splicing plate 1 and the second splicing plate 2 are symmetrically distributed and are right-angled trapezoids. The first splicing plate 1 and the second splicing plate 2 are respectively provided with symmetrical first splicing grooves 11 and second splicing grooves 21. The first splicing grooves 11 and the second splicing grooves 21 are spliced together to form a groove that matches the shape of the fixed module 10. The third splicing plate 20 is an isosceles trapezoid and is located at the lower end of the first splicing plate 1 and the second splicing plate 2. By splicing the first splicing plate 1, the second splicing plate 2, and the third splicing plate 20, the splicing plates are connected to the side of the fixed module. In this way, the aluminum formwork can be installed without disassembling the support rod 8, which improves the installation efficiency of the aluminum formwork.
[0026] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.
Claims
1. A prefabricated building PCF board and aluminum mold diagonal brace integrated construction structure, comprising a PCF board arranged on a bottom plate, characterized in that: The PCF board has a side embedded part, the end face of which is flush with the end face of the PCF board. A fixing module is connected to the end face of the side embedded part. Aluminum molds are spliced on both sides of the fixing module. The aluminum molds include multiple splicing plates. The multiple splicing plates are spliced to form the groove of the fixing module. The splicing plates are all located on the side of the fixing module and are attached to the end face of the fixing module.
2. The integrated construction structure of prefabricated building PCF panel and aluminum formwork diagonal bracing according to claim 1, characterized in that: There are two splicing panels, including a first splicing panel and a second splicing panel. The first splicing panel has a first splicing groove formed on one side, and the second splicing panel has a second splicing groove formed on one side. The first splicing groove and the second splicing groove constitute the slot for fixing the module.
3. The integrated construction structure of the fabricated building PCF board and the aluminum mold diagonal brace according to claim 1, characterized in that: There are three splicing panels, including a first splicing panel, a second splicing panel and a third splicing panel. The first splicing panel and the second splicing panel are symmetrically distributed. The first splicing panel and the second splicing panel are respectively provided with symmetrical first splicing grooves and second splicing grooves. The first splicing grooves and the second splicing grooves are spliced together to form a groove that matches the shape of the fixed module. The third splicing panel is in the shape of an isosceles trapezoid.
4. The integrated construction structure of the PCF panel of the fabricated building and the aluminum form diagonal brace according to claim 3, characterized in that: The first, second, and third splicing plates all have folded edges formed on their edges, and round holes are evenly distributed on the folded edges. Bolts are connected in the round holes on adjacent different folded edges to connect adjacent splicing plates.
5. The integrated construction structure of the fabricated building PCF board and the aluminum mold diagonal brace according to claim 1, characterized in that: The base plate also has a bottom embedded part, and a support rod connects the bottom embedded part and the side embedded part.
6. The integrated construction structure of the PCF panel of the fabricated building and the aluminum form diagonal brace according to claim 5, characterized in that: The support rod includes connectors at both ends, which are respectively connected to the bottom embedded part and the side embedded part. The two ends of the support rod are threadedly connected to the two connectors.
7. The integrated construction structure of the fabricated building PCF board and the aluminum mold diagonal brace according to claim 1, characterized in that: The back of the aluminum mold is also connected to a back rib.