RU2033504C1 - Sandwich building panel and method for its production - Google Patents

Abstract

FIELD: construction. SUBSTANCE: ends of branch pipes have quick-acting joint in form of socket slots for locking of reinforcing bars that is ensured by flexible springy walls of slots. Special bosses replace known gaskets to form reinforcement protective layer. Labor consuming operation of pulling reinforcing bars through holes in ends of branch pipes is replaced by simple and quick operation of direct connection of branch pipe to ready reinforcing fabric. Operation for installation of known gaskets for protective layer is excluded. EFFECT: simplified design of joint of branch pipes and reinforcement of external layers, and reduced labor input for manufacture of spatial reinforcing cage in course of panel formation. 5 cl, 2 dwg

Description

 The invention relates to three-layer building panels and methods for their manufacture mainly in the factory with an outer layer of dense material, mainly reinforced concrete, and an inner layer of heat-insulating material on rigid discrete bonds between layers, intended for building envelope structures of external walls, floor panels, heat-insulating coatings of buildings and structures.

 Known three-layer building panels of cooling structures with external reinforced concrete layers reinforced with steel grids and an internal insulation layer on discrete flexible or rigid bonds [1-7] Flexible bonds [1-4] provide a satisfactory heat-insulating ability, but complicate the molding process. In addition, their use is limited in seismic construction conditions. Hard links [5 and 6] are less labor intensive and more reliable under seismic conditions, but they are more heat-conducting inclusions (cold bridges) compared to flexible links.

 Closest to the claimed technical solution is a three-layer building panel [7] with hard discrete connections in the form of thin-walled pipes with anchors at the ends. They provide a reliable and rigid connection of the layers, have low thermal conductivity. However, the connection pipes allow connection only with single reinforcing bars that are not connected to each other in a mesh.

 Closest to the claimed method is a method of manufacturing a three-layer building panels [7] which includes a spatial frame device by attaching pipe connections to the reinforcing bars, fixing the frame in the molding matrix to form a protective layer of reinforcement, laying concrete in the lower layer of the molded panel, the middle layer device thermal insulation on the connections from the pipes passed through it, laying concrete in the upper layer of thermal insulation with filling the pipes with layer material, heat treatment and stripping of the finished panel. This method provides reliable anchoring of the bonds in the outer layers of the panel, but has a time-consuming operation of attaching the connection pipes to the reinforcing bars by pulling the latter one through the holes.

 The method also requires the operation of setting known gaskets to form a protective layer of reinforcement (fixing the frame in the molding matrix by setting gaskets).

 The inventive device is aimed at simplifying the design of the docking nodes in the spatial frame of a three-layer building panel, consisting of reinforcing meshes and hard discrete connections in the form of pipes, and saving material gaskets that fix the frame in the molding matrix.

 The inventive method is aimed at reducing labor costs when installing and fixing the spatial frame in the process of forming a three-layer building panel.

 A positive result is achieved by the fact that in the construction of a three-layer wall panel, including external reinforced concrete layers, an internal heat-insulating layer and rigid discrete bonds in the form of pipes mainly made of polymeric material, and containing a spatial frame of reinforcing bars and rigid discrete bonds, the latter have fixing elements from socket and adjacent slots and protrusions at the ends. Nesting slots have flexible walls and are used for quick connection with reinforcing rods of welded steel grids, and protrusions for fixing the frame in the molding matrix in order to form the required protective layer, which eliminates the need for known gaskets. The flexibility of the walls of the nesting slots is provided by adjacent slots. Flexible walls create a speed effect when connecting pipes to the reinforcing rods of the mesh. After concreting the layers, the hardened concrete in the slots closes the reinforcement in them. The depth of the nesting slot in the protrusion of the end of the pipe is equal to the thickness of the protective layer for the reinforcing mesh.

 A method of manufacturing a three-layer building panel includes a spatial framework by connecting the rods of the reinforcing meshes of the outer layers with hard discrete bonds in the form of nozzles, fixing the spatial framework in the molding matrix to form a protective layer, laying concrete in the lower layer of the molded panel with concrete filling the lower part of the nozzle, arrangement of the middle layer of thermal insulation with filling the middle part of the nozzles with its material, laying concrete in the upper layer of the molded panel whether with the filling of the upper part of the nozzles, heat treatment and stripping of the finished panel. The reduction of labor costs in comparison with the prototype is achieved by the fact that during the installation of the spatial frame, the operation of pulling individual reinforcing bars through the holes at the ends of the pipes before subsequent welding of the rods into the mesh is replaced by the operation of fastening the pipes to the finished reinforcing meshes with fast-acting docking units by transverse movement to the mesh plane with fixing reinforcing rods of the latter in springy socket slots.

 Reducing labor costs is achieved by eliminating the need for the operation of laying out known gaskets in the molding matrix to form a protective layer, since the latter is formed by the protruding ends of the pipes when fixing the spatial frame in the matrix.

 In FIG. 1 shows a fragment of a three-layer building panel, section; in FIG. 2 fragment of the spatial framework, axonometry.

 The three-layer building panel in the position corresponding to its molding includes a lower reinforced concrete layer 1 and an upper reinforced concrete layer 2, separated by a layer 3 of heat-insulating material. The panel contains a spatial framework of reinforcing rods 4 and 5 of external reinforced concrete layers interconnected by rigid discrete connections in the form of nozzles 6. The ends of the nozzles have quick-acting docking assemblies consisting of socket slots 7 and protrusions 9. The rods 4 and 5 of the reinforcing bars are placed in slots 7 grids. On both sides of the socket 7 there are adjacent slots 8, due to which the flexibility of the walls of the socket 7 and the speed of the docking unit as a whole are ensured. The protrusions 9 form the height of the protective layer for the reinforcing mesh.

The molding of the building panel according to the present invention can be carried out in the following sequence:
the reinforcing mesh 4 of the lower reinforced concrete layer 1 is laid at the bottom of the molding matrix (operation A);
in the prescribed order, pipes 6 are fixed of discrete rigid connections, fixing them on the reinforcing rods of the mesh 4 using high-speed docking nodes from nesting slots 7, adjacent slots 8 and thrust projections 9, preferably at the intersection of the rods of the reinforcing mesh (operation B); while the latter rises above the bottom of the molding matrix to the height of the protrusions 9, forming a protective layer;
laying concrete in the lower reinforced concrete layer of the panel with filling the bottom of the nozzles with it (operation B);
arrange a heat-insulating layer, for example, backfilling a heat-insulating material with filling the middle part of the nozzles 6 with it or put rigid foam boards with through holes on the nozzles (operation D);
attached to the upper ends of the nozzles 6 of the rod 5 of the reinforcing mesh of the upper reinforced concrete layer 2 (operation D);
concrete is laid in the upper reinforced concrete layer 2 (operation E).

 In another embodiment, in the case of bulk insulation, operation D can immediately follow operation B. Then operations B, D and E follow, i.e. first, the spatial frame is completely assembled from the lower reinforcing mesh 4, nozzles 6 and the upper reinforcing mesh 5, and then the concrete of the lower reinforced concrete layer 1, the material of the insulation layer 3 and the concrete of the upper reinforced concrete layer 2 are successively laid.

Claims (4)

 1. A three-layer building panel containing external reinforced concrete layers, an internal heat-insulating layer and a spatial framework of reinforcing meshes of layers connected by rigid discrete connections in the form of pipes with connecting nodes, characterized in that the connecting nodes are made in the form of nested slots with flexible spring walls for reinforcing rods of nets of layers and persistent protrusions at the ends of the nozzles.  2. The panel according to claim 1, characterized in that on the two sides of each nesting slot there are additional slots.  3. The panel according to claim 1, characterized in that the recesses are formed in thrust protrusions at the ends of the nozzles, and their depth is equal to the thickness of the protective layer for reinforcing meshes.  4. A method of manufacturing a three-layer building panel, including a spatial framework device by connecting the reinforcing rods of the outer layers with rigid discrete bonds in the form of nozzles, fixing the framework in the molding matrix to form a protective layer, laying concrete layers and thermal insulation with filling the corresponding parts of the nozzles with layer material, heat treatment and formwork of the finished panel, characterized in that the nozzles are attached to the finished reinforcing meshes by connecting nodes at the ends of the nozzles in the form nesting slots with flexible springy walls and persistent protrusions by lateral movement to the plane of the meshes with fixing the reinforcing rods of the latter in the springy nesting slots, while the operation of connecting the rods of the net with ties into the spatial frame is combined with the operation of fixing it in the molding matrix to form a protective layer.

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