RU2633462C1 - Reinforced formwork block with retained formwork and building structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: reinforced formwork unit with a retained formwork comprising a reinforcing cage consisting of working and structural rods connected at connection joints and at least one sheet of retained formwork attached to the reinforcing cage; according to the claimed solution, as a retained formwork sheet, a steel-fibre-concrete sheet is used, fixed at a distance of less than two diameters of the working rods from the reinforcing cage, the coaxially located working rods at their connection points are installed end to end or with a gap of not more than one diameter of the working rods, loop interblock joints are made at the ends of the working rods facing at least one side of the reinforced formwork block, and the inner surface of the steel-fibre-concrete sheet is made with an adhesive layer. Said technical result regarding the building structure is achieved by the fact that the building structure comprising a concrete-filled reinforced formwork block with a retained formwork comprising a reinforcing cage consisting of working and structural rods connected at connection joints and at least one retained formwork sheet attached to the reinforcing cage; according to the claimed solution, as a retained formwork sheet, a steel-fibre-concrete sheet is used, the inner surface of which is adhesively bonded to the concrete surface to be mated. The steel-fibre-concrete sheet is fixed at a distance of less than two diameters of working rods from the reinforcing cage, loop interblock joints are made at the ends of the working rods facing at least one side of the reinforcement formwork block, and coaxially located working rods at their connection points are installed end to end or with a gap of not more than one diameter of the working rods.

EFFECT: reducing the weight of the reinforced formwork block and the resulting building structure while simultaneously increasing their strength and spatial rigidity during transportation and installation, simplifying and increasing the accuracy of their installation.

25 cl, 2 dwg

Description

The group of inventions relates to ground construction, namely to fixed formwork for the construction of walls, floors, ceilings, as well as to building structures as a whole, in particular to walls and ceilings.

From the description of the USSR inventor's certificate for invention No. 1728432 (dated 04/23/1992, IPC E04G 9/10), non-removable fiber-reinforced concrete formwork is known for the manufacture of a building structure, including thin-walled formwork fiber-reinforced concrete slabs connected to each other by fasteners having on the side directed to the filling material the spaces between the slabs, which increase the fastening ability of the anchor outlets with an additional anchoring layer formed by the protruding concrete fibers of the reinforcing formwork slab. The use of fiber-reinforced concrete formwork increases the strength of the resulting structure. However, the need for installation of a reinforcing frame (hereinafter referred to as the reinforcement cage) leads to an increase in labor input, a decrease in the accuracy and quality of installation. In addition, the need to secure the anchor outlets further complicates the design.

The closest analogue of the claimed invention is a fixed formwork for the construction of a monolithic structure (RF patent for utility model No. 24487 dated 08/10/2002, IPC E04G 9/00), containing parallel formwork panels made of mineral wool and reinforced with frames of horizontal and vertical rods , and fixing elements, made in the form of a mounting grid of interconnected longitudinal and transverse rods. The combined use of fixed formwork and armoframes increases the speed of construction of a building structure. At the same time, the reinforcing cage rods are located at a considerable distance from parallel formwork panels in order to comply with building code requirements for reinforcing the reinforcement in the concrete structure, which consists in protecting the latter from adverse atmospheric influences and incorporating the reinforcement into the power work of the building structure. In addition, the use of formwork panels made of mineral wool slabs that do not have sufficient strength in comparison with steel-fiber concrete sheets does not allow the formwork to be included in the power work of the building structure when it is calculated, especially in the work on the perception of external loads and the dead weight of the building structure.

The problems solved by the proposed group of inventions are the inclusion in the power work of formwork and concrete with reinforcement without prestressing, increasing the efficiency of rod reinforcement (reinforcing bar rods), ensuring the protection of rod reinforcement from corrosion.

The technical result achieved by the claimed group of inventions is to reduce the weight of the reinforcement formwork and the resulting building structure, while increasing their strength and spatial rigidity during transportation and installation, as well as simplifying and improving the accuracy of their installation.

The specified technical result regarding the reinforcing formwork block with fixed formwork is achieved due to the fact that the reinforcing formwork block with fixed formwork, comprising an arm frame, consisting of working and structural rods connected in the connection nodes, and at least one sheet of fixed formwork, fastened with reinforcing cage, according to the stated decision, a steel-fiber-reinforced concrete sheet is used as a sheet of fixed formwork, which is fixed at a distance of less than two diameters of the working rods from the reinforcing cage, coaxially positioned working rods at their joints are installed end-to-end or with a gap of not more than one diameter of working rods, at the ends of working rods facing at least one of the sides of the reinforcement formwork, loop interlock joints are made, and the inner surface of the steel-fiber-reinforced concrete sheet is made with an adhesive layer.

In this case, the working and structural rods of the reinforcement cage in the connection nodes can be fastened to each other by welding, and / or soldering, and / or strapping.

And loop interconnects of working rods can be made in the form of an arc or free ends of working rods, bent at an angle from 45 ° to 170 °.

In addition, the steel-fiber-reinforced concrete sheet can be bonded to the reinforcing cage with at least three rod outlets on a threaded and / or welded and / or pin joint.

Also, the adhesive layer of the steel-fiber-reinforced concrete sheet may be made of sand and / or represents a rough and / or granular surface and / or a notched surface.

Mostly steel-fiber-reinforced concrete sheet includes fiber from 1.5 to 3.0% by volume, the smallest dimension of which is not more than 0.5 mm, milled from slabs with anchors at the ends of the fiber, and / or fiber chopped from wire with anchors at ends, and / or fiber, chopped from a corrugated wire, and / or fiber of variable profile, cut from a steel sheet. At the same time, the steel-fiber concrete sheet may include concrete having a strength class of at least B70, and the steel-fiber concrete sheet may have a thickness of 15 to 50 mm.

The diameter of the working rods of the reinforcement cage predominantly exceeds the diameter of the structural rods of the reinforcement cage.

The specified technical result regarding the building structure is achieved due to the fact that in the building structure, including a concrete-filled reinforcement formwork block with fixed formwork, including an arm frame, consisting of working and structural rods connected at the connection nodes, and at least one sheet fixed formwork fastened with reinforcing cage, according to the claimed solution, a steel-fiber concrete sheet is used as a fixed formwork sheet, the inner surface of which is adhesively bonded to on the concrete surface, while the steel-fiber-reinforced concrete sheet is fixed at a distance of less than two diameters of the working rods from the reinforcement cage, at the ends of the working rods facing at least one side of the reinforcement formwork, loop interconnects are made, and coaxially located working rods in places their joints are installed end-to-end or with a gap of not more than one diameter of working rods.

In this case, the working and structural rods of the reinforcement cage in the connection nodes can be fastened to each other by welding, and / or soldering, and / or strapping.

And loop interconnects of working rods can be made in the form of an arc or free ends of working rods, bent at an angle from 45 ° to 170 °.

In addition, the steel-fiber-reinforced concrete sheet can be bonded to the reinforcing cage with at least three rod outlets on a threaded and / or welded and / or pin joint.

Also, the adhesive layer of the steel-fiber-reinforced concrete sheet may be made of sand and / or represents a rough and / or granular surface and / or a notched surface.

Mostly steel-fiber-reinforced concrete sheet includes fiber from 1.5 to 3.0% by volume, the smallest dimension of which is not more than 0.5 mm, milled from slabs with anchors at the ends of the fiber, and / or fiber chopped from wire with anchors at ends, and / or fiber, chopped from a corrugated wire, and / or fiber of variable profile, cut from a steel sheet. At the same time, the steel-fiber concrete sheet may include concrete having a strength class of at least B70, and the steel-fiber concrete sheet may have a thickness of 15 to 50 mm.

At the same time, concrete for reinforcing cage can have a strength class from B20 to B70.

The diameter of the working rods of the reinforcement cage predominantly exceeds the diameter of the structural rods of the reinforcement cage.

The use of steel fiber-reinforced concrete sheets, the inner surface of which is adhesively bonded to the mating surface formed in the reinforcement formwork block of concrete, makes it possible to place reinforcing cores in concrete at a distance of less than two of their diameters from the inner surface of steel-fiber concrete sheets or to place them directly near the inner surface of steel-fiber concrete sheets, which ensures the transfer of forces at the joints of coaxially located working rods installed end-to-end or with a gap of no more e of the same diameter of the working rods, through a steel-fiber concrete sheet and concrete near them, without bypassing the rods. Failure to bypass the rods reduces material consumption, and, consequently, the weight of the structure as a whole.

The joint work of steel-fiber concrete sheets and reinforcing working rods increases the structural strength, which allows designing building structures of smaller thickness due to thinner steel-reinforced concrete sheets and less concrete, which, together with the absence of bypasses of reinforcing working rods, reduces the weight and material consumption of the resulting building structure.

In addition, the use of steel fiber reinforced concrete sheets with high strength changes the work of building structures in bending, including concrete, which is not taken into account when calculating reinforced concrete structures without prestressing, and increases the rigidity of reinforced concrete structures. Fixed formwork made of steel-fiber concrete sheets protects the reinforcing bars from corrosion due to the water resistance of steel-fiber concrete sheets due to their high density.

The presence of loop interconnects, simplifies installation and improves accuracy when installing reinforcement blocks.

The claimed group of inventions is illustrated by graphic material, where figure 1 shows a General view of the reinforcing formwork block with fixed formwork in one embodiment, and figure 2 shows a view "A" of the junction of coaxially arranged working rods with a gap.

Reinforcing block with fixed formwork includes an arm frame consisting of working 1 and structural 2 rods connected in nodes 3 of the connection. Reinforcing block contains at least one steel-fiber-reinforced concrete sheet 4 of fixed formwork, if it is designated as an overlap, or two steel-fiber-reinforced concrete sheets 4 for use in a wall panel. Steel-fiber concrete sheet 4 is fixed at a distance of less than two diameters of the working rods 1 from the reinforcement cage. Coaxially located working rods 1 of the armature frame in the places of their connection (shown in Figure 2, type “A”) are installed end-to-end, that is, without overlapping, touching each other, or with a gap of not more than one diameter of working rods 1, at which part of the force reinforcement at the junction of the working rods 1, is transferred from one working rod 1 to another through a steel-fiber concrete sheet 4 of fixed formwork, and part through concrete, frozen in the process of installing an arm formwork unit with a fixed formwork. At the ends of the working rods 1, facing at least one side of the reinforcing block, loop interconnects 5 are made, while on each side of the reinforcing block, loop interlock joints can be made, if necessary, 5. The inner surface of the steel-reinforced concrete sheet 4 is made with an adhesive layer (not shown in the figures).

In this case, the working 1 and structural 2 rods of the armature frame in the connection nodes 3 are fastened to each other by welding, in addition to and besides which soldering and / or strapping can be used, the choice of a specific method of fastening is carried out at the design and / or construction stage (construction of structures) .

Loop interblock joints 5 of the working rods 1 are made in the form of an arc. In addition, these elements can be made in the form of the free ends of the working rods, bent at an angle from 45 ° to 170 °, the execution form of the interblock joints 5 depends on the design loads and the equipment used in the production of the reinforcement formwork unit - a bending press or levers.

The steel-fiber-reinforced concrete sheet 4 is fastened to the armature frame with eight rod outlets 6 on a threaded connection (not shown in the figures), while the number of rod outlets 6 can be at least three and no more than the number of working rods 1 in the reinforcement cage, and in addition to and threaded connections can be selected welded and / or pin connection, which is determined at the design stage. To achieve the claimed technical result, a steel-fiber concrete sheet 4 is made with fiber from 1.5 to 3.0% by volume, the smallest dimension of which is not more than 0.5 mm, milled from slabs with anchors at the ends of the fiber, and / or fiber, chopped from wire with anchors at the ends, and / or fiber, chopped from corrugated wire, and / or fiber of variable profile, cut from steel sheet, and concrete for steel-fiber concrete sheets 4 is selected for strength class not less than B70. In this case, the thickness of the steel fiber-reinforced concrete sheet 4 is projected in the range from 15 to 50 mm.

To provide better adhesion to the concrete poured into the reinforcing formwork block, an adhesive layer (not shown in the figures) is made on the steel-fiber-reinforced concrete sheet 4, which is a rough surface, and can also be made of sand, and / or a granular surface, and / or a notched surface deposited on a steel-fiber-reinforced concrete sheet during its production. The specific form of the adhesive layer is selected based on perceived loads.

In order to reduce the material consumption, the diameter of the structural rods 2 of the armature frame is less than the diameter of the working rods 1 of the armature frame.

The building structure consists of a reinforced formwork block filled with concrete with a fixed formwork, including an arm frame, consisting of working 1 and structural 2 rods connected in nodes 3 of the connection. Reinforcing block contains at least one steel-fiber-reinforced concrete sheet 4 of fixed formwork, if it is designated as an overlap, or two steel-fiber-reinforced concrete sheets 4 for use in a wall panel. The inner surface of the steel fiber-reinforced concrete sheet 4 is adhesively bonded to the mating surface of concrete (not shown in the figures). Steel-fiber concrete sheet 4 is fixed at a distance of less than two diameters of the working rods 1 from the reinforcement cage. At the ends of the working rods 1, facing at least one of the sides of the reinforcement formwork, loop interconnects 5 are made, while on each side of the reinforcement formwork, loopback interconnects can be made in case of design need 5. Coaxially located working rods 1 reinforcing cage in the places of their connection (shown in Figure 2, view “A”) are installed end-to-end, that is, touching each other, or with a gap of not more than one diameter of the working rods, at which part of the force perceived by the reinforcement in the place of ar after the working rods 2 are transferred from one rod to another through the steel-fiber concrete sheet 4 of the fixed formwork, and part through concrete, frozen in the reinforcement formwork block with the fixed formwork.

In this case, the working 1 and structural 2 rods of the reinforcement cage in the connection nodes 3 are fastened to each other by welding, in addition to and besides which soldering and / or strapping can be used, the choice of a specific method of fastening is carried out at the design stage.

Loop interblock joints 5 of the working rods 3 are made in the form of an arc, in addition, these elements can be made in the form of the free ends of the working rods, bent at an angle from 45 ° to 170 °. The execution form of the interblock joints 5 depends on the design loads and the equipment used in the production of the reinforcement formwork block - a bending press or levers.

The steel-fiber-reinforced concrete sheet 4 is bonded to the armature frame with eight rod outlets 6 on a threaded connection (not shown in the figures), while the number of rod outlets 6 can be at least three and no more than the number of working rods 1 in the armature. The threaded connection can be replaced by a welded and / or pin connection, which is also determined at the design stage.

To achieve the claimed technical result, a steel-fiber concrete sheet 4 is made with fiber from 1.5 to 3.0% by volume, the smallest dimension of which is not more than 0.5 mm, milled from slabs with anchors at the ends of the fiber, and / or fiber, chopped from wire with anchors at the ends, and / or fiber, chopped from corrugated wire, and / or fiber of variable profile, cut from steel sheet, and concrete for steel-fiber concrete sheets 4 is selected for strength class not less than B70. In this case, the thickness of the steel fiber-reinforced concrete sheet 4 is projected in the range from 15 to 50 mm.

To achieve the claimed technical result, concrete molded in an reinforcing formwork block with a fixed formwork has a strength class from B20 to B70.

In order to reduce the material consumption, the diameter of the structural rods 2 of the armature frame is less than the diameter of the working rods 1 of the armature frame.

The proposed technical solutions - reinforcing formwork block with fixed formwork and building construction, are explained by the specific design of reinforcing formwork wall block with fixed formwork, however, the given example is not the only one possible, but clearly demonstrates the possibility of achieving the essential features of the claimed technical result with these sets.

Reinforcing wall block with a fixed formwork, includes an armature frame, consisting of working 1 and structural 2 rods, two steel-fiber concrete sheets 4 of fixed formwork, fastened to the reinforcement frame with rod outlets 6 on a threaded connection (not shown in the figures). Steel fiber-reinforced concrete sheets 4 are fixed at a distance from the reinforcing cage of less than one third of the diameter of the working rods 1. Moreover, at the ends of the working rods 1 facing the two sides of the reinforced formwork wall block, looped interblock joints 5 in the form of an arc are made. In addition, the inner surface of the steel fiber-reinforced concrete sheet is made with an adhesive layer, which is a rough surface (not shown in the figures).

On issues 6 installed brackets 7 for mounting process equipment. Also, in steel-reinforced concrete sheets 4 of fixed formwork, holes 8 are made for installing penetrations under cable or pipe channels.

The connection point “A” of the coaxially located working rods 1 installed end-to-end (with the formation of a small gap), indicated in FIG. 1 and shown in FIG. 2, includes working 1 and structural 2 reinforcing bar rods connected in connection nodes 3 by welding. In this case, the working rods 1 at the junction are installed without bypass. As already mentioned, part of the force perceived by the reinforcement at the junction of the working rods 1 is transmitted from one working rod 1 to another through a steel-fiber concrete sheet 4 of fixed formwork, and part through concrete, which solidified during the installation of the reinforcing formwork block with fixed formwork.

The building structure contains a reinforced formwork block filled with concrete with a fixed formwork, including an arm frame, consisting of working 1 and structural 2 rods connected in nodes 3 of the connection, and at least one steel-fiber concrete sheet 4 of fixed formwork, bonded to the reinforcing frame, the inner surface of which is adhesive connected to the mating surface of concrete. The steel-fiber-reinforced concrete sheet 4 is fixed at a distance of less than two diameters of the working rods 1 from the reinforcement cage, and at the ends of the working rods 1, facing at least one side of the reinforcement formwork, loop interblock joints are made 5. Coaxially located working rods 1 at their junctions installed end-to-end or with a gap of not more than one diameter of working rods 1.

The use of reinforced formwork wall block with fixed formwork is as follows: concrete mortar is poured into the installed reinforced formwork wall block, after molding (solidification) of which the resulting building structure can be used.

Claims (25)

1. Reinforced formwork block with fixed formwork, comprising an armature frame, consisting of working and structural rods connected in connection nodes, and at least one sheet of fixed formwork, bonded to the reinforcement frame, characterized in that a steel-fiber concrete sheet is used as a sheet of fixed formwork, which fixed at a distance of less than two diameters of the working rods from the reinforcement cage, coaxially located working rods in the places of their connection are installed end-to-end or with a gap of not more than one diameter of the working rods, n and at the ends of the working rods facing at least one of the sides of the reinforcing formwork block, loop interblock joints are made, and the inner surface of the steel-fiber-reinforced concrete sheet is made with an adhesive layer. 2. Reinforcement formwork block with fixed formwork according to claim 1, characterized in that the working and structural rods of the reinforcement cage in the connection nodes are fastened to each other by welding, and / or soldering, and / or strapping. 3. Reinforcement formwork block with fixed formwork according to claim 1, characterized in that the loop interconnects of the working rods are made in the form of an arc or free ends of the working rods, bent at an angle from 45 ° to 170 °. 4. Reinforcement formwork block with a fixed formwork according to claim 1, characterized in that the steel-fiber concrete sheet is bonded to the armature frame with at least three rod outlets. 5. Reinforcing formwork block with fixed formwork according to claim 4, characterized in that the steel-fiber concrete sheet is fastened with reinforcing cage by rod outlets on a threaded and / or welded and / or pin joint. 6. Reinforcement formwork block with fixed formwork according to claim 1, characterized in that the adhesive layer of the steel-fiber-reinforced concrete sheet is made of sand and / or represents a rough and / or granular surface and / or a notched surface. 7. Reinforcement formwork block with a fixed formwork according to claim 1, characterized in that the steel-fiber concrete sheet includes a fiber milled from slabs with anchors at the ends of the fiber, and / or fiber chopped from a wire with anchors at the ends, and / or fiber, chopped from corrugated wire, and / or fiber of variable profile, cut from steel sheet. 8. Reinforcement formwork block with fixed formwork according to any one of paragraphs. 1, 7, characterized in that the steel-fiber concrete sheet includes fiber from 1.5 to 3.0% by volume. 9. Reinforcement formwork block with fixed formwork according to any one of paragraphs. 1, 7, characterized in that the steel-fiber concrete sheet includes a fiber, the smallest dimension of which is not more than 0.5 mm. 10. Reinforcing formwork block with fixed formwork according to claim 1, characterized in that the steel-fiber-reinforced concrete sheet includes concrete having a strength class of at least B70. 11. Reinforcement formwork block with fixed formwork according to claim 1, characterized in that the steel-fiber concrete sheet has a thickness of 15 to 50 mm. 12. Reinforcement formwork block with fixed formwork according to claim 1, characterized in that the diameter of the working rods of the reinforcing frame exceeds the diameter of the structural rods of the reinforcing frame. 13. Building structure, comprising a concrete-filled reinforcing formwork block with fixed formwork, including an arm frame, consisting of working and structural rods connected in connection nodes, and at least one sheet of fixed formwork, bonded to an arm frame, characterized in that as fixed formwork sheets use a steel-fiber concrete sheet, the inner surface of which is adhesively bonded to the mating surface of concrete, while the steel-fiber concrete sheet is fixed at a distance of less than two diameters ditches of working rods from the reinforcing cage, at the ends of the working rods facing at least one side of the reinforcement formwork, loop interconnects are made, and coaxially located working rods at their joints are installed end-to-end or with a gap of not more than one diameter of the working rods. 14. The building structure according to claim 13, characterized in that the working and structural rods of the reinforcement cage in the connection nodes are fastened to each other by welding, and / or soldering, and / or strapping. 15. The building structure according to claim 13, characterized in that the loop inter-unit joints of the working rods are made in the form of an arc or free ends of the working rods, bent at an angle from 45 ° to 170 °. 16. The building structure according to claim 13, characterized in that the steel-fiber-reinforced concrete sheet is bonded to the armature frame with at least three rod outlets. 17. The building structure according to claim 16, characterized in that the steel-fiber-reinforced concrete sheet is fastened to the armature frame by rod outlets on a threaded and / or welded and / or pin joint. 18. The building structure according to p. 13, characterized in that the adhesive layer of the steel fiber-reinforced concrete sheet is made of sand and / or represents a rough and / or granular surface and / or a notched surface. 19. The building structure according to claim 13, characterized in that the steel-fiber concrete sheet includes a fiber milled from slabs with anchors at the ends of the fiber, and / or fiber chopped from wire with anchors at the ends, and / or fiber chopped from corrugated wire, and / or fiber of variable profile, cut from steel sheet. 20. Building construction according to any one of paragraphs. 13, 19, characterized in that the steel-fiber concrete sheet includes fiber from 1.5 to 3.0% by volume. 21. The building structure according to any one of paragraphs. 13, 19, characterized in that the steel-fiber concrete sheet includes a fiber, the smallest dimension of which is not more than 0.5 mm. 22. The building structure according to claim 13, characterized in that the steel-fiber-reinforced concrete sheet includes concrete having a strength class of at least B70. 23. The building structure according to p. 13, characterized in that the concrete for the reinforcing cage has a strength class from B20 to B70. 24. The building structure according to claim 13, characterized in that the steel-fiber concrete sheet has a thickness of 15 to 50 mm. 25. The building structure according to p. 13, characterized in that the diameter of the working rods of the reinforcing frame exceeds the diameter of the structural rods of the reinforcing frame.

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