RU2053334C1 - Grate reinforcement for concrete slab and plate-type member of a wall concrete form for monolithic shell building - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: grate reinforcement for concrete slab has spaced flat bridges of similar width and zigzag-shaped reinforcing bars welded to the bridges on their sides. Apices of the zigzags are projected over the flat bridges to keep concrete form plates apart from the flat bridges to place concrete between the concrete form plates and the flat bridges. The spacing is 15 - 50 mm. Reenforcing zigzags may be shifted along lengthwise direction by half distant between apices of each other and bent outside. Grate reinforcement may be additionally provided with rods welded on outer sides of reinforcing bars in the area of flat bridge to fasten to ceiling slab. Plate- type member of wall concrete form includes concrete form plates and grate reinforcement placed between. The member is provided with flat bridges placed between plates and parallel to them. Zigzag-shaped reinforcement is attached to the bridges. The zigzags are projected over flat bridges to interconnect them to one another. Fastening members are made in the form of screws and split pins. Displacing body glued on concrete form plate between two reinforcing structures is placed. The plate is set in concrete. EFFECT: high reliability. 18 cl, 11 dwg

Description

 The invention relates to lattice reinforcement for a concrete slab with two flat bridges located at a distance from each other, and can be used in construction during the construction of buildings and structures.

A wall is known, in the cavity of which there are metal nets bent into vertical rectangular pylons, on the sides of which two zigzags of reinforcing bars that protrude beyond the sides of the pylons are reinforced. The protruding zigzag peaks pass through the polystyrene formwork plates and are used to fasten metal meshes from the outside, which are immersed in sprayed concrete, and the polystyrene plates serve as formwork for the internal cavity [1]
The disadvantage of this device is the relatively high cost of time when performing the outer layers of the wall from a metal mesh and applying sprayed concrete.

Known spatial reinforcement formwork package for reinforced concrete structures, including formwork slabs and frame made in the form of composite elements [2]
The disadvantage of this technical solution is the impossibility of building the elements of the formwork of the ceilings for shell monolithic concreting.

 The objective of the invention is the creation of reinforcement, with which it is possible to build not only wall elements for shell monolithic concrete, but also elements of the formwork of the ceilings, as well as increased productivity, reduced labor intensity while protecting important parts of the reinforcement from corrosion during the construction of buildings and structures.

 This is achieved by the fact that the reinforcement has parts protruding beyond the flat lintels on both sides, which hold the formwork plates at a distance from the flat lintels, which makes it possible to completely surround the lintels with concrete during concreting. Due to the protruding parts of the reinforcement, the formwork plates are not directly adhered to the flat lintels, which, when concreted, are completely surrounded by concrete, which provides protection against corrosion. Thanks to the full concreting, reinforcement can be used not only in wall plates, but also in ceiling ones.

 In addition, it is possible to perform the protruding parts of the reinforcement zigzags with flat jumpers with the possibility of forming a channel profile for applying it on the side shelves of the formwork plates, and the distance from the tops of the zigzags of the reinforcement rods to the flat jumpers is from 15 to 50 mm. The reinforcing zigzags in the longitudinal direction can be offset halfway between the vertices relative to each other, on the outer sides of the reinforcing bars additional reinforcing rods can be welded in the area of the flat bridge for fastening the reinforcement in the ceiling plate, and the protruding zigzag vertices on one side can be bent outward.

 The slab-like element of the wall formwork for a monolithic concrete shell building includes several truss reinforcing structures that are parallel to each other and on the protruding parts of which on both sides formwork plates are fastened with heads, which are externally passed through the formwork plate and enter a flat jumper so that the end of the fastener protrudes into the cavity between the two flat jumpers. The ends are thus poured with concrete. In particular, it turns out to be advantageous if the fasteners are made in the form of stainless screws with an end shaped as the end of a drill and when each screw has a thread-free portion adjacent to the head, the length of which is approximately equal to the length of the threaded portion and the end of the drill, the length of both sections is approximately equal to the distance from the formwork plate to the flat bridge.

 In addition, in the plate-like element, each plate can be made with slots in the region of the tops of the reinforcement zigzags through which the vertices of the reinforcement zigzags are passed, which are attached to the longitudinal edges of the side flanges of the channel profiles.

 In this case, formwork plates can be fixed by means of cotter pins, which are externally inserted into openings that are bounded by the zigzag tops of the reinforcement and the free longitudinal edges of the side shelves.

 The formwork plates have a thickness corresponding to the protrusion of the bent peaks of the zigzags above the free longitudinal edges, and in the area of the cotter pins have recesses outside of their placement.

 It is also possible to mount heat-insulating plates, which are worn on the incoming parts of the reinforcement, and additional plates of a more durable material that can hold screws and nails, for example, plywood plates, etc. rebars adjacent to the protrusions, which are attached to the flat jumpers, and for the construction of ceilings, the remaining formwork plate is attached to the tops of the reinforcing zigzags, bent outward, using brackets. If brackets are used for this, the ends of which are longer than the thickness of the formwork plates and have beveled edges, then these ends are bent outward if the formwork plate is placed on an appropriate gasket, for example, a steel plate. The brackets are then embedded in the formwork plate. The ceiling elements preferably have 3-4 truss beams per formwork plate. Between the beams there may be displacing (facilitating) beams of light material, for example expanded polystyrene, which are attached to the formwork plate. The formwork plates themselves may consist of polystyrene foam or wood chips bound by cement.

 The self-drilling and cutting screws for fastening the formwork plates are made so that the screw in the transition from the head to the thread-free part is made with a concave part with a conical section profile. By choosing the type of this conical section, a transition section can be obtained which, depending on the screw thread height, drilling speed and formwork plate material, smoothly amplifies the displacement of the formwork plate material when the screw is screwed with the most vertical application of force.

 The recess for the tool in the screw head goes into an expanding recess, which includes a button-shaped protrusion of a special plate covering the screw head and is fixed there.

 Figure 1 shows a perspective image of a slab-like element of a wall formwork for a monolithic shell building; figure 2 shows a plot of a plate-like element in a perspective image; figure 3, the reinforcement region of the plate-shaped element of figure 1, a horizontal section; in Fig.4 plate-like element of Fig.1, a horizontal section; figure 5 plate-like element of figure 2, a vertical section; in FIG. 6 plate-like element, an embodiment; in FIG. 7 two attachment points in two different positions of the screw during screwing; on Fig transition section at the screw head, an embodiment; 9 and 10, the ceiling formwork element, embodiments; 11, a ceiling plate-like element with a displacing body, front view.

 The lattice reinforcement 1 consists of two flat jumpers 2 and 3, in particular sheet metal strips, which are parallel to each other and connected by reinforcing rods 4, welded from the sides, especially in the form of a zigzag of the reinforcement bar. The rods 4 extend beyond the flat lintels 2 and 3 on both sides by the vertices 5 of the zigzags of the reinforcing bar. On the outer sides of the reinforcement rods, additional reinforcement rods 6 are welded at the height of the flat bridge 2.

 Plate-like elements are made as follows. Arrange several elements of reinforcement 1 at the desired distance from each other, then lay the formwork plate 7 and fasten it at a distance from the flat bridge 2.3 at the ends of the reinforcement rods 4 or the tops 5 of the reinforcement zigzags with screws 14 with a head 25, a thread-free section 8 and sharpened at the end, like drills, with a thread 9, which are wrapped externally through the formwork plate 7 and the flat jumper 2. In this case, the threaded section 9 before drilling the jumper 2 leaves the formwork plate 7 and the plate is not damaged waiting. The screw 14 is screwed at least until the head 25 adheres to the formwork plate 7, and with this ratio of the lengths of the threaded and smooth parts 9.8 and the thickness of the formwork plate 7, the threaded portion of the screw engages with the flat jumper 2.3, while the end of the screw comes out into the cavity between the flat jumpers 2,3 and directly poured with concrete.

 The screw head 25 may be covered by a plate 28, which is inserted by a protrusion into the tool recess in the head 25. To do this, there is a hole 26 extending inward in the tool recess. It includes a button-shaped protrusion 29 of the plate 28. The head 25 is recessed into the formwork plate 7, 10, 20 by the thickness of the plate 28 so that the surface of the formwork is smooth. In order to obtain a recess in the formwork plate for the transition section from the head 25 to the thread-free section 8, as well as for the head 25 itself, the concave part of the transition section 27 is a segment of a conical section, for example, an ellipse or a parabola. Fig. 8 shows two different embodiments of the transition section 27, the left half of which with an enlarged diameter head for the formwork plates 10, 20 is of a less crush-resistant material, and the right half for the more crush-resistant material of the formwork plates 7. The curvature of the generatrix is transitional, it causes a progressive increase in the displacement of the material, which at the head is compacted without destruction, thereby achieving maximum tensile strength.

 On the formwork plates 10, 20, slots 17 are made in the region of the peaks 5 so that the plates are put on until the longitudinal edges 16 of the side shelves 18. In this position for concrete, however, the required distance to the flat bridge 2.3 remains. The formwork plates 10 are fastened, for example, from polystyrene foam, by means of cotter pins 12, which are located in the outer recesses 11 of the formwork plates 10 and pass through the holes 15.

 The ceiling formwork element, according to Fig. 5, has a single formwork plate 7, which is attached with screws 14 to the lower flat jumper 2. The reinforcement 1 in this design is provided with tensile reinforcement in the form of rods 6 that are welded outside the rods 4 onto the height of the flat lintel 2. Their pouring with concrete is provided due to the distance to the formwork plate 7.

 In FIG. 9 shows a ceiling formwork element that has a cement chip formwork plate 20. The reinforcement 1 is attached to it, in which the vertices 5 of the reinforcement zigzags are offset in the longitudinal direction relative to each other. The lower peaks have sections 21, bent outward, which are fastened by brackets 22 to the formwork plate 20. In the manufacture of the ceiling formwork element, the formwork plate 20 is placed on the lining 24, for example, in the form of a steel plate, and the brackets 22 are pressed using a device (not shown) , the oblique edges 23 of the ends of the brackets on the lining 24 diverge to the sides and bend upward so that the brackets 22 are firmly fastened.

 In FIG. 11 shows the ceiling formwork element, in which between the two screwed or fixed brackets to the formwork plate 7,10,20 the reinforcement beams 1 is a filling body 30, in particular of foam styrene, which is preferably attached to the plate.

 The manufacture of both reinforcement and the slab-like formwork element with it is quick and easy, and the profitability of production and storage is increased, since the same reinforcement 1 is used for the manufacture of both concrete slabs.

Claims (18)

 1. Lattice reinforcement for a concrete slab containing flat lintels of the same width spaced from each other and welded in a zigzag shape reinforcing rods on the sides for fastening the latter to the formwork plates parallel to the flat lintels, characterized in that the bent vertices of the rebar rods are made protruding above the flat lintels to hold the formwork plate away from the flat lintels to place concrete between the formwork plates and the flat lintels.  2. The reinforcement according to claim 1, characterized in that the protruding parts of the bend vertices of the zigzag reinforcement rods with flat jumpers form a channel profile for applying formwork plates to its side flanges.  3. The reinforcement according to claim 1, characterized in that the distance from the vertices of the bends of the reinforcing rods to the flat jumpers is from 15 to 50 mm.  4. Fittings according to paragraphs. 1 to 3, characterized in that the zigzags of the reinforcement in the longitudinal direction are offset relative to each other by half the distance between the peaks.  5. The reinforcement according to claims 1 to 4, characterized in that on the outer sides of the reinforcing rods additional reinforcing rods are welded in the area of the flat bridge for fastening the reinforcement in the ceiling plate.  6. Fittings according to paragraphs. 1 to 5, characterized in that protruding from one side of the top of the bend of the reinforcement is bent outward.  7. A slab-like element of wall formwork for a monolithic concrete shell building, including formwork slabs and lattice reinforcement located between the slabs, characterized in that it is provided with flat jumpers located between the slabs parallel to them with zigzag fasteners attached to the latter, whose zigzags are located above the flat jumpers for connecting them with the latter.  8. The element according to claim 7, characterized in that the fasteners are provided with screws made of stainless material with a drilling end that are screwed externally into flat jumpers, each screw having a thread-free section and a threaded end ending with a drilling end, wherein the lengths of both sections are equal to the distance between the flat jumper and the plate.  9. The element according to claim 7, characterized in that each formwork plate in the region of the vertices of the reinforcement zigzags has slots through which the vertices of the reinforcement bends are passed and attached to the longitudinal edges of the side shelves of the channel profiles.  10. The element according to claim 7, characterized in that the formwork plates are fixed by means of cotter pins, which are externally inserted into holes that are bounded by the tops of the bends of the reinforcement and the free longitudinal edges of the side shelves.  11. The element of claim 10, characterized in that the formwork plates have a thickness corresponding to the protrusion of the zigzag vertices above the free longitudinal edges, and in the area of the cotter pins have recesses outside of their location.  12. The element according to claim 10, characterized in that the formwork plate is fastened against the parts of the reinforcement protruding from the reinforcing rods protruding from the flat bridges with additional reinforcement rods, the elements being protruding through the formwork plates and a flat jumper into the cavity between both flat jumpers.  13. The element according to claim 7, characterized in that the formwork plate remaining in the concrete structure is attached with brackets to the outwardly bent peaks of the reinforcement bends.  14. The element according to p. 12, characterized in that on the remaining formwork plate of the formwork between two reinforcing structures, a displacing body is glued to it.  15. The item according to paragraphs. 7 to 14, characterized in that the formwork plates are made of plastic such as polystyrene foam.  16. The item according to paragraphs. 7 to 14, characterized in that the formwork plates are made of wood chips with a cement binder.  17. The element according to claim 8, characterized in that the screw in the transition region between the thread-free portion and the head is made expanding with concave curvature, wherein the generatrix of the concave curved transition region is a segment of the sectional line of the cone.  18. The item according to paragraphs. 7 to 17, characterized in that the recess for the tool in the screw head is made turning into an expanding recess, which includes a button-shaped protrusion of the plate covering the screw head with fixation in it.

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