UA76965C2 - Armature net for reinforced concrete - Google Patents

Abstract

A reinforcing mat (1) for reinforced concrete, consisting of longitudinal and transversal wires (2, 5) which intersect each other at right angles and are welded at the intersection points thereof. The reinforcing mat respectively comprises two longitudinal edge wires (3, 4) and two transversal wire end parts which protrude from the longitudinal edge wires and are bent back in relation thereto in the form of a loop on the plane of the mat in addition to being welded thereto. The longitudinal wires arranged in the center area (Z) of the reinforcing mat have the same mutual axial distances (a) and the same cross-sectional surfaces (F). The reinforcing mat has edge areas (R) on both longitudinalsides, said edge areas consisting of a pair of parallel longitudinal edge wires having a mutual axial distance (c) which is smaller than the axial distance of the longitudinal wires in the center area of the reinforcing mat and the axial distance (b) of the inner longitudinal wires from the adjacent longitudinal wire of the center area is greater than the axial distance of the longitudinal wires in the center area of the reinforcing mat, in addition to consisting of edge loops (7).

Description

Description of the invention

The invention relates to a reinforcing mesh for reinforced concrete consisting of longitudinal and transverse bars crossed at right angles and 2 welded to each other at the intersection points, and the parts of the transverse bars protruding beyond the edge longitudinal bars are bent back to the edge longitudinal bars in the plane of the mesh in the form of a loop bars and welded to them.

The reinforcing mesh of the above type is used to reinforce flat load-bearing structures, which must withstand forces in two mutually perpendicular directions, that is, in the longitudinal and transverse 70 directions according to the crossed groups of reinforcing mesh bars. A large number of different structural designs of reinforcing meshes are known, designed for the best possible coordination with a wide variety of flat load-bearing structures subject to reinforcement and having different sizes, and above all with different steel cross-sections correlated with the directions of reinforcement. Since the reinforced concrete elements to be reinforced, as a rule, have a greater width than the reinforcing meshes, the reinforcing meshes 12 must be stacked one next to the other with an overlap. At the same time, certain minimum overlaps are necessary to ensure force transfer from one reinforcing mesh to another.

From (the description of the patent RE 973 001) a so-called edge-saving mesh is known, in which, in order to avoid excessive accumulation of steel in the overlap zone in both marginal longitudinal zones, at least two extreme longitudinal rods have a cross-section approximately twice as small as the rods of the central zone of the mesh. The distance between all longitudinal bars across the entire width of the reinforcing mesh is the same. This edge-saving rebar does not have looped crossbars and cannot take advantage of the above type of rebar.

From (РЕ-А1-1484116) a program for the production of reinforcing meshes for reinforced concrete is known, in which, in order to significantly reduce the number of different standard sizes of rods used for the implementation of the entire program, as well as to avoid the production of reinforcing meshes of different widths, separate series of the program are made from reinforcing meshes of the same width, and all meshes of the same series are made of rods that, at least in the inner Ge) zone of the meshes, have the same diameter. At the same time, within each series, the number of rods varies from type to type of mesh, and for all series, the width of the inner zone of individual reinforcing meshes, on which the rods are distributed, is constant. The grids produced by this program also do not have looped transverse bars, so this program also cannot take advantage of the advantages of reinforcing grids of the above type. at

From (AT-8-377564) and related additional |patents AT-8-381540 and AT-8-381542) reinforcement of Ge) of the above type is known, in which the distance between two external longitudinal elements, the so-called edge longitudinal elements, at each edge of the mesh is smaller than the distance between the rest of the longitudinal elements, and at each edge of the mesh, the parts of the transverse rods bent back in a loop-like manner are welded to one of the two edge longitudinal elements, preferably to the outer one, or to both edge longitudinal elements. 325 At the same time, the distance between the two marginal longitudinal elements is much smaller than the distance between the remaining longitudinal elements. The distance between the inner marginal longitudinal element and the adjacent longitudinal element of the inner zone of the reinforcing mesh is greater than the uniform distance between the longitudinal elements of the inner zone. In addition, both marginal longitudinal elements have a smaller cross-sectional area than the rest of the longitudinal elements of the inner zone of the reinforcing mesh. With regard to these reinforcing meshes, the approach for creating a program for the manufacture of reinforcing meshes is not disclosed. For the production of reinforcing meshes, hot-rolled material improved by rolling heating is increasingly used, which has high plasticity and, moreover, can be produced very economically, since the technological operation of cold forming is not required. This material is manufactured according to the standard with integer values of diameters.

The task of the invention is to avoid the disadvantages of known reinforcing meshes and to develop a reinforcing mesh of the type 7 indicated above, which, on the one hand, can be manufactured as a mesh that is economical at the edges using

Gee! of hot-rolled material with integer values of diameters is particularly economical, i.e. with the involvement of the smallest possible number of diameter gradations, and, on the other hand, within the framework of the program for the production of reinforcing meshes, it ensures the smallest possible step of changing the nominal values of the total cross-sectional area along the width of the mesh to solve all reinforcement problems in the production of planar reinforced concrete structural elements. sl The reinforcing mesh according to the invention differs in that the distance between the longitudinal bars placed in the central zone is constant, and the indicated longitudinal bars have the same cross-sectional area, and also in that the reinforcing mesh on both longitudinal sides has edge zones containing two parallel marginal 52 longitudinal bars, the distance between which is known to be less than the distance between the longitudinal bars in the central

GF) zone of the reinforcing mesh, the distance between the inner marginal longitudinal bar and the adjacent longitudinal bar of the central zone is known to be greater than the distance between the longitudinal bars of the central zone of the reinforcing mesh, as well as the edge loops.

According to another feature of the invention, longitudinal bars, marginal longitudinal bars and transverse bars are made of 60 hot-rolled material with high plasticity and have integer values of diameters.

In the corresponding inventive reinforcing mesh, the cross-sectional area of both edge longitudinal bars of each edge of the mesh is smaller than the cross-sectional area of the longitudinal bars of the central zone of the mesh or the same as the cross-sectional area of the longitudinal bars.

The invention also relates to a typical program consisting of several series of reinforcing meshes, which differs in that the total width of all reinforcing meshes of the typical program is constant, that both edge zones of all reinforcing meshes of the typical program are made the same and have a constant distance between the two edge longitudinal bars , that the number of longitudinal bars in the central zone of the reinforcing mesh within the series with the growth of the total cross-section of steel in the central zone of the reinforcing mesh in integer steps

It increases, and the interaxial distance decreases to the same extent, as well as the fact that the required values of the total cross-sectional area of the reinforcing meshes of the standard program are achieved by the minimum number of integer values of the diameters of the longitudinal, marginal longitudinal and transverse bars.

Other features and advantages of the invention are explained in more detail below on the example of implementation with reference to the drawings. They are schematically shown: Fig. 1 - reinforcing mesh according to the invention with rectangular meshes in the central zone 70, Fig. 2. reinforcing mesh according to the invention with square meshes in the central area.

Shown in Fig. 1 and 2, the corresponding inventive reinforcing meshes 1 consist of a central zone 7 and marginal zones K on both sides of the central zone 7. The reinforcing mesh 1 contains parallel longitudinal bars 2 in the central zone 7, and in each of the marginal zones K - the inner edge longitudinal bar C and the outer edge longitudinal bar 4 are oriented parallel to each other and parallel to the remaining /5 longitudinal bars 2. The longitudinal bars 2 are placed from each other at the same interaxial distance a (the so-called longitudinal pitch), and the interaxial distance a measured from mid-rod to mid-rod.

At a right angle to the longitudinal bars 2 and to the edge longitudinal bars 3, 4, parallel transverse bars 5 are oriented, which are welded to the longitudinal bars 2 and to the edge longitudinal bars З, 4 at the intersection points of the mesh. The transverse bars 5 are placed one from the other on the same centerline distances are (the so-called 2o transverse step).

Edge longitudinal bars 3, 4 are placed from each other at an interaxial distance c, much smaller than the interaxial distance a between the longitudinal bars 2 in the central zone 2, as a result of which the edge longitudinal bars 3, 4 form a pair of edge longitudinal bars. The interaxial distance c is preferably 50 mm, but within the framework of the invention it can be from 20 mm to 5 mm. Due to such a small interaxial distance s between the edge members of the longitudinal bars Z, 4, when using several reinforcing meshes for continuous reinforcement of large reinforced concrete structural elements, the section along which the transverse bars 5 and) of two adjacent reinforcing meshes are connected to the overlap is shortened and thus material of transverse bars is saved.

The inner marginal longitudinal bars Z are placed relative to the adjacent longitudinal bars 2 at an interaxial distance B greater than the interaxial distance a between the longitudinal bars 2 in the central zone 7. Due to such a

From the Design of the reinforcing mesh 1, when reinforcing large reinforced concrete structural elements using several reinforcing meshes placed in a row, mutually overlapped by the side sections forming a load-bearing x, connection, an approximately uniform distribution of the total cross-sectional area of the steel is ensured throughout the Ge! reinforced surface; the cross-sectional area of the steel in the overlap zone is almost equal to the cross-sectional area of the steel in the central zone 7 of the reinforcing mesh 1. Excessive accumulation of material in the overlap zone is eliminated, thanks to which material is saved and the effect of saving material at the edges is fully used. uh-

However, within the framework of the invention, the interaxial distance B can also be equal to the interaxial distance a between the longitudinal bars 2 in the central zone 7. The recommended minimum overlap in the connection zone is 200 mm. For all the corresponding inventive reinforcing meshes 1, the interaxial distance B is chosen to be equal to 200 Ωm, since, on the one hand, the effect of saving material on the edge should be achieved and, on the other hand, it should be ensured that the longitudinal bars are not piled up, but the distribution of the longitudinal bars as evenly as possible in the overlapping area. with c The ends of the transverse bars 5 protruding above the outer marginal longitudinal bar 4 on each side of the grid are bent in the form of an edge loop 7 symmetrically relative to the longitudinal axis of the reinforcing grid 1 and at points 8;" crossings are welded to the corresponding outer edge bars 4. Within the framework of the invention, it is also possible to bend the edge loop 7 on each side of the grid in opposite directions. In addition, within the framework of the invention, it is also possible to bring the edge loops 7 to the inner edge bar C and additionally weld at the point 9 of the intersection to -I of this edge bar 3. The diameter of the edge loop 7 is chosen so that, when embedded in reinforced concrete, the permissible compression of concrete in curvature zone of the edge loop 7. Distance 4 from the outer edge

Me. loop to the middle of the outer edge bar 4 is preferably 50 mm, but it should be at least

Ge) than 4-6 diameters of cross bar 5.

Due to the formation of marginal loops 7 in combination with a denser placement of marginal longitudinal rods 3'

Me, 4, in the overlap zone of two reinforcing meshes 1, both points of welding of the part of each sp transverse bar placed in front of the loop with both edge longitudinal bars 3, 4, due to the small distance c between them, are almost uniformly involved in the transmission of force, due to which the load on each welding point. In addition, edge loops 7 improve the attachment of reinforcing meshes in the overlapping area and

Provide a small width of the overlap zone. Due to the fact that the edge loops 7 allow you to see very well the position of the edges of several interconnected reinforcing meshes 1, it is possible to very accurately determine the actual (Ф, dimensions of the overlap zones and easily control the placement of the reinforcing meshes on the construction site. ka In the example of execution according to Fig. 1, in the central zone 7, the interaxial distance v between the transverse bars 5 is greater than the interaxial distance a between the longitudinal bars 2, as a result of which in this example, the longitudinal bars 2 and the transverse bars 5 in the central zone 7 of the reinforcing mesh 1 form the mesh 10 of a rectangular At the same time, the transverse step e is greater than the longitudinal step a.

The second embodiment of the reinforcing mesh 1 shown in Fig. 2 differs from the first embodiment in that in the central zone 7 the interaxial distance e between the transverse bars 5 is equal to the interaxial distance a between the longitudinal bars 2, due to which in the central zone 2 the longitudinal bars 2 and transverse 65 bars 5 of the reinforcing mesh 1 form square meshes 11.

The sum of all interaxial distances a, b and c, as well as heights and hinges 7 forms the total width B of the reinforcing mesh 1. Usually the width of the reinforcing mesh is selected according to the smallest possible number of standard sizes, and the total width of 2400 mm, consistent with the loading width of vehicles, is adopted in throughout the world as an economically especially expedient standard. Based on this standard, the corresponding inventive reinforcing meshes 1 have a constant total width of В-240Ω. Constant width is obtained on the basis of constant interaxial distances of c-5O0mm, constant interaxial distances of 0-200mm, and constant heights of hinges of 4-200mm

ZOOmm of the edge zone K, as a result of which the central zone 7 of the reinforcing mesh 1 has a constant width of 1800 mm.

Within the framework of the invention, the diameter of the marginal longitudinal bars 3, 4 is less than or at most equal to the diameter of the longitudinal bars 2 in the central zone 7, as a result of which the cross-sectional area U of the marginal bars 3, 4 /o is less than or equal to the area E of the cross-section of the longitudinal bars 2 in the central zone 7 reinforcing mesh 1.

Thanks to this solution, the accumulation of steel in the overlapping area of two reinforcing meshes 1 is eliminated. Within the framework of the invention, the diameters of the transverse bars 5 are chosen to be smaller or at most the same as the diameters of the longitudinal bars 2 in the central zone 7, as a result of which the cross-sectional area of the transverse bar 5 is smaller or is equal to the cross-sectional area of the longitudinal bar 2 in the central zone 7 of the reinforcing mesh 1.

Reinforcement grids can have any length Й, and the standard value of the length with a meter step is preferred. The common value of the length of the grid is bm, therefore, in the case of rectangular meshes 10, the corresponding standard value of the transverse step e is 400, 330 and 200 mm.

In order to increase the adhesion of the reinforcing mesh in concrete, the surface of bars 2, 3, 4, 5 is preferably covered with ribs.

All bars 2, 3, 4, 5 of the corresponding inventive reinforcing mesh 1 are made of hot-rolled material with high plasticity, which is achieved by processing hot-rolled material during rolling heating. Within the framework of the invention, high plasticity can also be obtained by microalloying the material. According to the standard, hot-rolled material is produced with integer values of diameters: 6, 8, 9, 10 and 12 mm.

Within the framework of the invention, all the bars 2, 3, 4, 5 of the reinforcing mesh 1 can also be made of hot-rolled material, which in the course of a separate technological operation is additionally subjected to cold deformation and thanks to this, gets better mechanical and technological properties. Cold deformation consists mainly in i) stretching of hot-rolled material. Within the framework of the invention, cold deformation may alternatively consist of cold tempering by rolling and/or drawing. With this method of production, the rods are freed from scale before cold deformation, thanks to which welding is carried out without any obstacles. Alternatively, cold deformation may consist of stretching the hot-rolled material. With this method of production, the rods are not freed from scale before stretching, because the fragile layer x, scale during the technological process of stretching cracks and crumbles. And with this method Ge! the production of scum layers, which interferes with the welding of rods, is removed.

For the most economical production of the program from various types of reinforcing meshes in accordance with the idea of 5 of the invention, on the one hand, only types of meshes with a constant total width B, with a constant width M, identically made edge zones K and, thus, with a constant width of the central zone 7 with the exclusive use of hot-rolled rod material having the standard, integer values of the diameters indicated above, and, on the other hand, to achieve the smallest possible step of changing the total cross-sectional area in reinforcing meshes of various types, the longitudinal bars 2 in the central zone « 5 of the reinforcing mesh 1 is distributed evenly, and the interaxial distances a are chosen with the appropriate step. With the overall width of the reinforcing mesh B-2400mm, the following mesh parameters were particularly appropriate: interaxial distance 6-200mm, interaxial distance c-5mm and loop height 4-5mm, as a result of which the width of the central zone c is 2-1800mm, and the optimal values center distance and form the following series: 100mm, 120mm, 150mm, 180mm, 200mm. For most reinforcement tasks, the main series containing the following selected values is sufficient: а-100; 150; 200 mm. The change of the interaxial distance a for the placement of longitudinal bars in this main -I row is carried out with a step of 50 mm, which is optimally consistent with the most used step changes of conventional welding installations. In principle, within the framework of the invention in this example, smaller or larger steps could also be chosen, which, however, would have neither static nor technological meaning. Within the scope of the invention,

Ge) other values of the total width V and/or other values of the distance 56, other optimal rows are selected for the 5p distribution of longitudinal bars, and often a compromise between the optimal, economic

Me. production and static requirements for the program of types of reinforcing meshes. sp By designing the reinforcing mesh 1 according to the invention and observing the optimal discreteness of the longitudinal step and with a constant total width B of the mesh 1 and observing the constant performance of the left and right edge zones K, it is possible to create a program of types of reinforcing mesh that uses a minimum number of values of the diameters of longitudinal bars; in particular, in each case it is possible to use only integer values of the diameters of longitudinal bars in order to ensure the desired discreteness of the values of the total

F) cross-section of steel within the program of types of grids. The production of the corresponding inventive reinforcing mesh 1 is carried out in multi-point welding installations operating according to the method of electric resistance. Longitudinal rods 2, C, 4 within the framework of the invention can be supplied to the welding installation in the form of pre-prepared straight blanks or in the form of an endless rod. Transverse rods 5 are supplied from an endless rod, which - depending on the diameter and properties of the material - can be supplied in the form of a coil or ring-shaped coils or rings. The starting material is leveled and fed to the welding machine. Within the framework of the invention, it is also possible to first level the raw material, cut it lengthwise, and then feed it to the welding machine in the form of cross bars. 65 It goes without saying that the presented example of implementation within the framework of the general idea of the invention can be modified in various ways, in particular in the part of the implementation of the reinforcing mesh; yes, within the framework of the invention, double bars can also be used instead of single bars to design the central zone 7 of the reinforcing mesh 1.

In addition, within the framework of the invention, longitudinal and marginal longitudinal bars 2; 3; 4 of the reinforcing mesh 1 can be made of hot-rolled material without additional cold deformation, while transverse bars 5 are made of hot-rolled material, which is subjected to cold deformation during an additional technological operation. Cold forming can consist of tempering by rolling and/or drawing or in stretching. In addition, within the framework of the invention, the transverse bars 5 of the corresponding inventive reinforcing mesh 1 can be made of hot-rolled material without additional cold deformation, while 70 longitudinal and edge longitudinal bars 2; 3; 4 are made of hot-rolled material, which is subjected to cold deformation during an additional technological operation. And in this case, cold deformation may consist of tempering by rolling and/or drawing or stretching.

Claims (11)

The formula of the invention 1. A reinforcing mesh for reinforced concrete consisting of longitudinal and transverse bars crossed at right angles and welded to each other at the points of intersection, and has two marginal longitudinal bars at each edge, and the parts of the transverse bars protruding beyond the marginal longitudinal bars are in the plane meshes in the form of a loop are bent back to the edge longitudinal bars and welded to them, which differs in that the longitudinal bars (2) in the central zone (7) of the reinforcing mesh (1) are placed from each other at the same interaxial distance (a) and have the same area (ER) of the cross-section, as well as the fact that the reinforcing mesh (1) on both longitudinal sides has edge zones (CK), each formed by a pair of parallel edge longitudinal bars (Z, 4), placed from each other at an interaxial distance (c ), which is smaller than the interaxial distance (a) between the longitudinal P bars (2) in the central zone (7) of the reinforcing mesh (1), and at the interaxial distance (B) between the inner marginal longitudinal bar (3) and by the adjacent longitudinal bar (2) of the central zone (7), which is greater than (o) the interaxial distance (a) between the longitudinal bars (2) in the central zone (7) of the reinforcing mesh (1), as well as the marginal loops (7), and also by the fact that the reinforcing mesh (1) is part of a typical program, in which the total width (B) of all reinforcing meshes (1) of the typical program is constant, both edge zones (K) of all reinforcing meshes (1) of the typical program are made identically and have constant interaxial distances (B, c, 4), and the number of longitudinal bars (2) in the central zone (7) of the reinforcing mesh (1) within the series with the growth of the total cross-section of the steel in the central zone (7) of the reinforcing mesh in integer steps increases, and the interaxial distance (a) decreases to the same extent, and the required values of the total cross-section of the steel of the standard program are achieved by using the minimum number of integer values of the diameters |se) of the blanks for the longitudinal, marginal longitudinal and transverse bars (2; WITH; 4; 5). chn 2. Reinforcing mesh according to claim 1, which differs in that all reinforcing meshes (1) have a constant total width (B) - 2400 mm, constant interaxial distances (B) - 200 mm from the inner edge longitudinal bars (3) to the adjacent longitudinal bars of rods (2) of the central zone (7), fixed interaxial distances (c) - 50 mm between the inner edge longitudinal rods (3) and outer edge longitudinal rods (4), fixed height of loops (4) - 50 mm, and « 70 Also by the fact that the interaxial distances (a) between the longitudinal bars (2) in the central zones (7) of the reinforcing meshes with (1) are 100, 120, 150, 180 and 200 mm, and also by the fact that the diameters of the longitudinal, marginal longitudinal and transverse bars (2; Z, 4; 5) are 6, 8, 9, 10 and 12 mm. :z" Z. The reinforcing mesh according to claim 2, which differs in that the interaxial distances (a) between the longitudinal bars (2) in the central zone (7) of the reinforcing meshes (1) change in steps of 5 Ohm, and the interaxial distances (a) are preferably 100, 150 and 200 mm -AND 4. The reinforcing mesh according to one of the claims 1 - C, which differs in that the interaxial distances (e) between the transverse bars (2) of all the reinforcing meshes (1) are 100, 150, 200, 330 and 400 mm. (22) 5. A reinforcing mesh according to one of claims 1 - 4, which is characterized by the fact that the longitudinal bars (2), edge longitudinal bars (3, 4) and transverse bars (5) are made of blanks of hot-rolled material with high 5r plasticity, which have integer values of diameters. (2) 6. The reinforcing mesh according to claim 5, which is characterized by the fact that the longitudinal bars (2), edge longitudinal bars (3, 4) and transverse bars (5) are made of hot-rolled material with high plasticity, subjected to additional cold deformation, preferably stretching. 7. A reinforcing mesh according to one of claims 1 - b, which differs in that the cross-sectional areas (Y) of both edge longitudinal bars (3, 4) at each edge of the mesh are smaller than the areas (P) of the cross-sections of the longitudinal bars (2) in the central zone (7) of the reinforcing mesh (1) or the same as the areas (P) of the cross sections (F) of the longitudinal bars (2). GI 8. A reinforcing mesh according to one of claims 1 - 7, which differs in that the areas (n) of the cross sections of the transverse bars (5) are smaller than the areas (P) of the cross sections of the longitudinal bars (2) in the central zone (7) in the reinforcement mesh (1) or the same as the area (GE) of the cross-sections of the longitudinal bars (2). 9. The reinforcing mesh according to one of claims 1 - 8, which is characterized by the fact that the central zone (7) of the reinforcing mesh (1) has rectangular meshes (10), and the interaxial distances (e) between the transverse bars (5) are greater than the interaxial distances distances (a) between longitudinal bars (2) in the central zone (7) of the reinforcing mesh (1). 10. The reinforcing mesh according to one of claims 1-5, which is characterized by the fact that the central zone (72) of the reinforcing mesh (1) has square meshes (11). 11. A reinforcing mesh according to one of claims 1 - 10, which is characterized by the fact that in order to achieve an economical laying of reinforcing meshes (1), the cross-section of steel in the overlap zone of neighboring reinforcing meshes (1) is approximately equal to the cross-section of steel in the central zone (7) of the reinforcing meshes nets (1). s o IS) "so (22) (Se) and - shi s ;" -I (22) se) b 50 sl F) name) 60 b5