EP0065512A1 - Three-dimensional welded grid element resistant to shearing in all directions - Google Patents

Abstract

1. A three-dimensional welded grid body which is stiff in shear in all directions, comprising two parallel planar grid mats (G1, G2) having longitudinal and transverse wires (L11-L1n, L21-L2n; Q11-Q1n, Q21-Q2n) crossing one another and welded together at the points of intersection, and web wires (Sa, Sb, Sc, Sd; S) extending in an inclined manner between said grid mats, spacing the grid mats a predetermined distance apart and being welded to a wire of each of the two grid mats, characterized by the combination of features that straight web wires (Sa, Sb; S) cut to length are inclined to planes normal to the longitudinal wires (L11-L1n, L21-L2n), and either other longitudinal wires (Sc, Sd) cut to length or the same longitudinal wires (S) cut to length are in addition inclined to planes normal to the transverse wires (Q11-Q1n, Q21-Q2n) of the two grid mats (G1, G2), the two ends of each of the web wires (Sa, Sb, Sc, Sd; S) being welded to the two grid mats (G1, G2) at a distance from the ends of the respective other web wires and at a distance from the points of intersection (K) of the grid wires.

Description

The invention relates to a three-dimensional welded lattice body, consisting of two parallel, flat lattice mats made of crossing and at the crossing points welded longitudinal and transverse wires and the lattice mats at a predetermined mutual distance, at each end with a wire one of the two lattice mats welded, cut straight web wires.

Lattice bodies of this type are known, for example, from DE-A2-2 314 002 and serve mainly as reinforcement for composite components, the web wires of the lattice body carrying a heat-insulating core layer and the lattice mats protruding on both sides of this layer forming tragnets and surface reinforcements for outer shells made of concrete. In the lattice body known from the aforementioned DE-A2, all the web wires are arranged in an alternating opposite oblique position in planes running parallel to the longitudinal wires of the lattice mats and perpendicular to the mat surfaces. This known design of a spatial lattice body offers for the use as reinforcement for components of the type described above the advantage that the heat-insulating core layer is easily inserted in strip form in two opposite sides of the lattice mats and on two further opposite sides of web wires limited longitudinal channels of the lattice body can, on the other hand, limit the possible uses of the lattice body to those cases in which rigidity against shear in the direction of the transverse wires is not required. Given such a shear stress on the known spatial lattice body, the initially rectangular cross sections of the longitudinal channels mentioned can easily deform into parallelogram cross sections due to the lack of stiffening of the lattice body in the transverse direction. On the other hand, from DE-A1-2 440 578 a spatial lattice body with two external lattice mats and intermediate webs is known, in which the webs are formed by continuous, wavy wires in the direction of the longitudinal wires of the lattice mats, which are either perpendicular to the lattice mats Layers or in pairs in mutually inclined planes run so that four webs meet at one point and form the edges of a pyramid. When the corrugated land wires are arranged in longitudinal planes perpendicular to the lattice mats, similar conditions result as for spatial lattice bodies of the type specified at the outset. When the corrugated web wires are arranged in mutually inclined planes, on the other hand, an oppositely inclined position of the web wire sections with respect to the longitudinal and transverse planes that are perpendicular to the grid mats results in a shear-resistant grid body on all sides.

Similar relationships exist in the spatial lattice bodies described in FR-A-1 354 223 and in US-A-3 347 007, in which two parallel lattice mats are caused by sheets of corrugated land wires running in normal planes to the longitudinal wires and others in normal planes The cross-wires of sheets of corrugated land wires are connected in such a way that four land wires of both wire sheets come to rest on the edges of pyramids.

In all of these cases, it is difficult to weld the crests of the bridge wires to the grid wires properly, because inevitably several welding spots come to lie close to each other. Furthermore, there are further difficulties in welding the corrugated ridge wires to the grid wires if it is additionally required that the Wave crests of the web wires should not protrude above the levels of the grid mats, as is the case, for example, when using such grid bodies as walk-in rust-like structures. In this application, corrugated web wires, each of which forms curved wire sections between the welding points with the two mesh mats instead of straight webs, are disadvantageous insofar as the wire sections mentioned cannot withstand a greater bending stress due to their pre-curvature.

Finally, from US-A-2 670 819 a spatial reinforcement element is known, which is formed from mutually parallel, ladder-like longitudinal elements which are connected vertically to one another by outer cross-wires forming grid meshes which are normal to their longitudinal extent, and by diagonal to these grid meshes running corrugated bridge wires are stiffened on all sides. Such reinforcement elements are so expensive in terms of their complicated structure that, as far as is known, they have not been used in practice.

The invention is now concerned with the task of designing a lattice body of the type specified in the introduction in such a way that it is shear-resistant on all sides in such a way that it can be easily manufactured and in particular enables the web wire ends to be welded to the lattice wires using simple welding tongs.

This object is achieved in the lattice body according to the invention in that at least some of the straight bridge wires run obliquely to normal planes on the longitudinal wires and at least some of the straight bridge wires run obliquely to normal planes on the transverse wires.

In this construction, the spatial grid body is oblique to the normal planes on the cross wires extending web wires in the transverse direction and stiffened in the longitudinal direction by the web wires running obliquely to the normal planes on the longitudinal wires, so that the lattice body is shear-resistant in all directions.

A particularly simple embodiment results if at least some of the web wires, but preferably all of them run obliquely to normal planes on the longitudinal wires and also obliquely to normal planes on the transverse wires of the two grid mats. In this case, each bridge wire has a stiffening effect in both the transverse and longitudinal directions.

In order to ensure easy access to the welding points of the bridge wires with the grid wires, it is advisable to weld the two ends of the bridge wires to the wires of the two grid mats at a distance from the crossing points of the grid wires.

In particular in the event that the lattice body according to the invention is to be used as a walk-in supporting structure, it is also advisable to cut the web wires to length with the outer sides of the two lattice mats so that they do not protrude beyond the lattice mats.

The straight bridge wires used in the context of the invention already ensure a buckling stiffness which is desirable for rust-like structures, but this can be increased if necessary by forming the bridge wires with a larger diameter than the grid wires. The accessibility of such structures can be further favored by the fact that the grid wires of at least one of the two grid mats have a profiled surface.

However, a spatial lattice body according to the invention can of course also be used as a component in a conventional manner Find use, then a layer of heat-insulating material is arranged in its central region, at a distance from the two lattice mats.

• Figur 1 in Schrägansicht einen Gitterkörper, bei dem eine Versteifung in Richtung der Gitterlängsdrähte und eine Versteifung in Richtung der Gitterquerdrähte durch je eine Schar von geraden, abgelängten Stegdrähten erzielt ist;
• Figur 2 in ähnlicher Schrägansicht einen Gitterrost, bei dem die schräg verlaufend.en Stegdrähte eine gleichzeitige Versteifung sowohl in Längs- als auch in Querrichtung bewirken,und
• Figur 3 schematisch einen Teil eines erfindungsgemäßen räumlichen Gitterkörpers mit einer von dessen Stegdrähten getragenen wärmeisolierenden Schicht.

Embodiments of the invention are shown in the drawings. It shows

• Figure 1 in an oblique view of a lattice body, in which a stiffening in the direction of the longitudinal grid wires and a stiffening in the direction of the lattice transverse wires is achieved by a group of straight, cut web wires;
• Figure 2 in a similar oblique view, a grating in which the obliquely running web wires bring about simultaneous stiffening in both the longitudinal and transverse directions, and
• Figure 3 schematically shows a part of a spatial lattice body according to the invention with a heat-insulating layer carried by its web wires.

In the lattice body according to FIG. 1, two lattice mats G1 and G2 with aligned longitudinal and transverse wires L1-1-L1n and L21-L2n or Q11-Q1n and Q21-Q2n are at a predetermined distance from one another. They are held at this distance by cut straight web wires Sa, Sb or Sc, Sd, of which the former alternately in opposite directions obliquely between aligned longitudinal wires L11, L21 or L13, L23 etc., i.e. obliquely to normal planes on the longitudinal wires, and the latter alternately run in opposite directions obliquely between cross wires Q11, Q21 or Q13, Q23 etc. aligned with one another, that is to say obliquely to normal planes on the cross wires. The lattice body is therefore stiffened both in the direction of the longitudinal wires of the lattice mats and in the direction of the transverse wires thereof and therefore shear-resistant on all sides.

As can be seen particularly clearly in FIG. 1 for the bridge wires Sa, Sb or Sc, Sd running between the longitudinal wires L1n and L2n or for the bridge wires Q11 and Q21, the ends of the bridge wires are at points P1 and P2 Longitudinal or transverse wires of the lattice mats G1 and G2 are welded, which are at intervals from crossing points K of the lattice wires, so that these points are easily accessible for simple welding guns.

FIG. 2 shows another exemplary embodiment of the invention using the same designation as in FIG. 1, in which each web wire S runs from a point P2 lying within a longitudinal wire section of the lower lattice mat G2 to a point P1 on a longitudinal wire section of the upper lattice mat, which is offset approximately by a longitudinal wire pitch as well as approximately by a transverse wire pitch with respect to the point P1 on the grid mat G1. In this way, each web wire S has a stiffening effect both in the longitudinal direction and in the transverse direction of the lattice body.

The welding points P1 and P2 of the ends of the web wires S with longitudinal wires of the grid mats G1 and G2 are again at a distance from the crossing points K of the grid wires.

As already mentioned, the web wires in spatial lattice bodies, which are to be used as rust-like supporting structures, should end flush with a lattice mat level, that is, they should not protrude above this. The grid wires of a mat to be walked on can advantageously be profiled, for example ribbed, in order to increase the grip. By increasing the diameter of the bridge wires, their buckling stiffness and thus the load-bearing capacity of the structure can be increased. Such rusty structures can be used for work platforms, covers, formwork beams, however can also be used for prefabricated floor, wall and ceiling elements.

Likewise, a spatial lattice body according to the invention, as has been indicated in a partial view in FIG. 3 for the embodiment according to FIG. 1, is suitable in a conventional manner for producing prefabricated components whose webs Sa, Sb, Sc and Sd have a core layer KS in the central region of the lattice body wear from heat-insulating material, whereby the freely protruding mesh mats G1 and G2 can be embedded in concrete and then form wall shells. It can be seen that the inclined webs running in different directions carry the core layer and hold it firmly in the central region of the lattice body.

Claims (7)

1.Three-dimensional welded lattice body, consisting of two parallel, flat lattice mats (G1, G2) made of crossing and welded longitudinal and transverse wires (L11-L1n, L21-L2n; Q11-Q1n, Q21-Q2n) and from the straight mat wires (Sa, Sb, Sc, Sd; S), which hold the grid mats at a predetermined mutual distance and are welded at each end to a wire of one of the two grid mats, characterized in that at least some of the cut straight bar wires (Sa, Sb; S) obliquely to normal planes on the longitudinal wires (L11-L1n, L21-L2n) and at least some of these land wires (Sc, Sd; S) obliquely to normal planes on the transverse wires (Q11-Q1n, Q21-Q2n) of the two grid mats ( G1, G2) run. 2.Grid body according to claim 1, characterized in that at least some web wires (S) both obliquely to normal planes on the longitudinal wires (L11-L1n, L21-L2n) and obliquely to normal planes on the transverse wires (Q11-Q1n, Q21-Q2n) of the two grid mats (G1, G2) run. 3.Grid body according to claim 1 or 2, characterized in that the two ends of the web wires (Sa, Sb, Sc, Sd; S) are welded to the two grid mats (G1, G2) at a distance from the crossing points (K) of the grid wires . 4.Grid body according to one of claims 1 to 3, characterized in that the web wires (Sa, Sb, Sc, Sd; S) are cut to length with the outer sides of the two grid mats (G1, G2). 5. slatted body according to one of claims 1 to 4, characterized in that the web wires (Sa, Sb, Sc, Sd: S) have a larger diameter than the grid wires (L11, L21, Q11, Q21 etc.). 6.Grid body according to one of claims 1 to 5, characterized in that the grid wires L11-L1n, Q11-Q1n) at least one of the two grid mats (G1, G2) have a profiled surface. 7.Grid body according to one of claims 1 to 6, characterized in that a core layer (KS) made of heat-insulating material is arranged in its central region, at a distance from the two lattice mats (G1, G2).

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