EP0079892A1

EP0079892A1 - Lattice girder.

Info

Publication number: EP0079892A1
Application number: EP82900001A
Authority: EP
Inventors: Franz Bucher
Original assignee: Individual
Current assignee: Individual
Priority date: 1980-12-29
Filing date: 1981-12-18
Publication date: 1983-06-01
Also published as: IT8125887A0; WO1982002222A1; IT8123921V0; ATA632080A; HU185499B; AT373012B; EP0079892B1; DE3167760D1; DE8138571U1; JPS57502008A; IT1169296B

Abstract

Une barre longitudinale (4) comme membrure superieure, deux barres longitudinales (2) comme membrures inferieures et une barre additionnelle plus courte (6) par barre de membrure inferieure sont reunies au moyen d'entretoises (3) de preference de forme ondulee, en une poutre en treillies. La longueur et la disposition de la barre courte (6) sont adaptees a la courbe des moments. La barre courte (6) est en contact direct avec la barre longue (2) sur toute sa longueur et lui est solidarisee. Toutes les barres de membrure inferieure (2, 6) se trouvent dans un seul plan horizontal et sont soudees a chaque point de contact a des parties pliees parallelement (5) des entretoises (3). Les jonctions soudees ainsi obtenues comprennent des soudures aux angles d'un triangle ou d'un trapeze resistant a la torsion de facon qu'une transmission de force complete soit atteinte. Les parties pliees (5) des entretoises (3) forment deux rangees de droites qui sont alignees, de preference par paires et disposees dans un meme plan et alternativement obliques par rapport aux barres de membrure inferieure (2, 6). Ainsi, les barres de membrure inferieure (2, 6) peuvent rester lisses et n'exigent pas une partie d'adherence.A longitudinal bar (4) as upper chord, two longitudinal bars (2) as lower chords and an additional shorter bar (6) per lower chord bar are joined by means of spacers (3) preferably of wavy shape, in a lattice beam. The length and arrangement of the short bar (6) are adapted to the moment curve. The short bar (6) is in direct contact with the long bar (2) over its entire length and is secured to it. All lower chord bars (2, 6) lie in a single horizontal plane and are welded at each point of contact to parallel bent portions (5) of the struts (3). The resulting welded joints include welds at the corners of a triangle or trapezoid resisting twisting so that full force transmission is achieved. The folded parts (5) of the spacers (3) form two rows of straight lines which are aligned, preferably in pairs and arranged in the same plane and alternately oblique to the lower chord bars (2, 6). Thus, the lower chord bars (2, 6) can remain smooth and do not require a portion of adhesion.

Description

Lattice girder

The invention relates to a lattice girder for the production of reinforced concrete ceilings, with at least one longitudinal bar as the upper chord, at least one longitudinal bar as the lower chord, and with transverse bars connecting them, each longitudinal bar of the lower chord being reinforced by at least one shorter additional bar, the length and arrangement of which is adapted to the course of the moment, directly touches the longitudinal bar over the entire length and is connected to it in a force-transmitting manner, and all the bars of the lower flange lie in a horizontal plane.

Characteristics of the closest state of the art

The current state of reinforced concrete science provides in the classic dimensioning theory for components subjected to bending a correlation between tensile and compressive forces via the shear absorption capacity of the concrete. This assumption presupposes that the reinforcement steel anchoring the tensile forces in the lowest possible arrangement in the tensile zone of the component subjected to bending has an adhesive force. Only when this adhesion is guaranteed does the reinforcing steel transfer its forces to the surrounding concrete, which transmits them to the concrete pressure zone via its shear strength.

The anchoring ability of the reinforcing bars under tension is in the concrete. an essential, cost-intensive weak point, the at least partial solution of which has been attempted by welded ladder-like intermediate pieces (DE-PS 907.587), welded-on node pieces, swellings, attached sleeves (DE-OS1 609 910). This has made it possible to shorten the length of detention. However, these solutions are not applicable to reinforcement bars that touch each other over the entire length, i.e. are bundled, as this would result in the reinforcement bars being too far apart. AT-PS 309.757, according to which short reinforcement bars are welded to the ends of the additional bars, which dissipate the tensile forces, shows a first solution in which the shorter additional bars can dispense with the adhesive length and allow the reinforcement bars to be arranged close to one another allow in the pressure zone of the concrete.

A reinforcement element, which can also form part of a lattice girder of the type mentioned at the outset, has subsequently become known (AT-PS 359.253), in which the reinforcement bars of the tensile zone, that is to say of the lower chord, which are provided in staggered lengths, are directly welded to one another in a manner are that about the welded joints a complete Force transfer from the shorter to the longer reinforcing bars can take place, so that the tensile force is reduced in the end points of the additional bars. The reinforcement bars of the lower chord are thus directly adjacent to one another in the lowest possible level, which prevents an excessive width of the lattice girder in the lower chord. However, the direct welding, which is an almost optimal solution to the problem with rod bundles, means an additional work step in the manufacture of lattice girders, additional equipment in automatic production systems, which cannot be fully offset in economic terms by the greatest possible reinforcement steel saving.

Object of the invention

The object of the invention is therefore to create a lattice girder, the additional bars of the tensile reinforcement which are adapted to the torque profile do not require any adhesive length, the entire lower chord reinforcement lying in the lowest possible level, and all shorter bars being connected to at least one continuous longitudinal bar in a force-transmitting manner, and no additional work step or special additional devices are required for the production of the lattice girder.

State the nature of the invention

According to the invention, such a lattice girder has the following features, some of which are known per se: a) the parts of the crossbars assigned to the lower flange are angled parallel to the plane of the lower flange rods,

b) the angled parts of the cross bars run in two sets of straight lines, which are oriented obliquely opposite to the reinforcing bars, and

c) each reinforcement bar of the lower chord is welded to the angled parts of the cross bars on each contact part.

The angled parts of the crossbars are preferably in the same plane.

In a further embodiment of the invention it is provided that the oppositely oblique, angled parts of the cross bars are each arranged in pairs.

In particular, the crossbars are formed by loop coils, the lower loops of which form the angled parts.

The force-transmitting connection of each additional bar to the longitudinal reinforcement bar is therefore not made by welding the reinforcement bars directly, but via the angled parts of the cross bars. It has surprisingly been found that a force transmission corresponding to the requirements is also possible if the angled parts of the cross bars are only parallel to the horizontal plane formed by the reinforcement bars Level, especially above the reinforcing bars, are arranged because the vertical components in each path of the flow of force, from the additional bar over the

Weld up into the angled part of a crossbar, and from there over the next

Weld down into the next longer reinforcement bar, is negligible. A prerequisite for the transfer of force is, on the one hand, direct contact between the reinforcement bars, since the transverse component lying in the reinforcement plane is reduced to the minimum possible, namely the sum of the radius of two reinforcement bars, and, on the other hand, the angled parts that run in opposite directions with respect to the reinforcement bars the crossbars, so that the flow of force in the horizontal is deflected at both obtuse angles. This results in a welded connection with welds at the corner points of a triangle, in particular a trapezoid that is torsion-resistant due to the contact of the rods. Such welds are repeated along the reinforcement bars at relatively short intervals (approximately every 20 - 25 cm) in accordance with the arrangement of the cross bars. This results in the additional advantage that the angled parts of the cross bars ensure the composite effect between the reinforcing bars and the heavy concrete, and so smooth reinforcing wires can be used instead of the otherwise required ribbed or profiled wires. In a comparison with the lattice girder mentioned at the outset, the totality of the above advantages in the production of lattice girders outweighs the somewhat increased material requirement for the angled parts due to the bending of the cross bars parallel to the reinforcement plane, and the resulting, if any, then Material requirements for the additional rods if the end of the additional rod cannot be arranged at the actually required point, but only at the next loop of the loop snake.

This combination of the features mentioned cannot be derived from other known lattice girders. The use of bent bracket coils in lattice girders, on the loops of which two reinforcement bars are provided at a distance from one another, is described in AT-PSs 279.864, 286.582 and 348.217, DE-OS 2 065 433 and FR-PS 1 374 389. Due to the distance between the Reinforcing bars are not torsionally rigid, and the reinforcing bars must therefore have a length of grip.

It is also known to provide individual stirrups which are installed vertically or at an incline, and in any case have parts which run parallel to one another and are bent parallel to the reinforcement plane. Examples of this are shown in AT-PSen.241.079 and 297.452, DE-OSen 27 50 032 and 23 29 943, and finally AT-PSen 340.650, 357.313 and 360.722 by the applicant. The welded joints are formed in these designs by welds at the corner points of non-torsionally rigid rectangles, and the force flow is reversed twice at right angles, in contrast to the solution according to the invention, the distance is therefore considerably longer.

Other known lattice girders with loop coils and reinforcing bars touching one another (AT-PSen 348.217 and 360.722) have no bent

Loops so that the lower chord reinforcement is not arranged in a horizontal plane, and therefore all additional bars arranged above the lowest bars cannot be calculated with their full cross-sectional area as tensile reinforcement, which means oversizing.

Description of the drawing figures

The invention will now be explained in more detail in several exemplary embodiments with reference to the figures of the drawings, without being limited thereto.

Description of preferred embodiments

1 shows an oblique view of a part of a lattice girder according to the invention, FIG. 2 shows an end view of an exemplary embodiment, FIGS. 3 and 4 end views of further exemplary embodiments, FIGS. 5 and 6 plan views of a section of the lower chord reinforcement of two exemplary embodiments, and FIG. 7 shows an end view another embodiment.

A lattice girder 1 according to the invention has an upper chord formed by at least one longitudinal bar 4, a lower chord formed by at least two reinforcement bars 2, 6 and a row of transverse bars 3 connecting them. The lower chord reinforcement has at least one reinforcement bar 2 which is continuous over the entire length of the lattice girder 1 and which is reinforced by at least one shorter additional bar 6. The length and the arrangement of each additional bar 6 are chosen so that an under-belt reinforcement adapted to the torque curve is formed. The additional rods have no adhesive length, they are at most only slightly longer than required to cover moments if they do not end at a cross bar 3. All reinforcement bars 2, 6 lie in a horizontal plane and are preferably below the angled one. Parts 5 are provided so that the reinforcing bars 2, 6 can be arranged in the concrete component at the lowest possible point. The reinforcing bars 2, 6 touch each other over the entire length and therefore form a flat bundle. The cross bars 3, which are preferably in the form of loop coils (FIGS. 1, 5), have horizontally angled parts 5 on which the reinforcement bars 2, 6 are welded. The angled parts 5 run in two sets of straight lines, which are oriented obliquely to the reinforcing bars, whereby they are advantageously arranged in pairs, but in opposite directions at an angle. The welding points 7 (FIGS. 5, 6) lie at the corner points of a trapezoid, which is torsion-resistant due to the reinforcement of the reinforcing bars 2, 6. The cross bars 3 are preferably formed by loop coils, the lower loops of which are angled and which represent the parts 5. In this case, the arrangement of the welding points 7, not shown, can also be provided in a triangle, via the angled parts 5, the tensile forces from the additional bars 6 are transferred to the longitudinal reinforcement bars 2, the force flow being deflected at an obtuse angle in the horizontal.

The lattice girder 1 according to FIG. 1 has two bow-shaped coils provided with angled loops as cross bars 3, which connect the two-part lower chord reinforcement to the upper chord. 2, the cross bars 3 can also be formed by individual brackets. In the 3, in which the cross bars 3 are again single brackets or loop coils, three reinforcement bars 2, 6, 6, two of which are additional bars 6, are combined in the lower chord reinforcement.

In the embodiment according to FIG. 4, two mutually offset stirrups are preferably also provided as cross bars 3, the angled parts 5 of which point towards one another. The longitudinal reinforcement bar 2 is on the angled parts 5 of all. Cross bars 3 welded, the additional bars 6, however, are only attached to the parts 5 of the cross bars 3 on one side.

Fig. 5 shows the top view of angled loops of a bow snake, in Fig. 6 angled parts of single brackets are shown as cross bars, which are arranged in pairs in opposite directions, Fig. 7 finally shows an embodiment in which the cross bars 3 (bow snakes or single brackets ) have angled parts 5 in two parallel planes, the reinforcing bars 2, 6 being arranged between these two planes and running above or below the parts 5.

Claims

Patent claims

1. Lattice girder for the production of reinforced concrete ceilings, with at least one longitudinal bar as the upper chord, at least one longitudinal bar as the lower chord, and connecting them. Cross bars, each longitudinal bar of the lower chord is reinforced by at least one shorter additional bar, which is adapted in length and arrangement to the torque curve, directly touches the longitudinal bar over the entire length and is connected to it in a force-transmitting manner, and wherein all bars of the lower chord lie in a horizontal plane , characterized by the following, in part known feature s

a) the parts (5) of the transverse rods (3) assigned to the lower flange are angled parallel to the plane of the lower flange rods (2, 6),

b) the angled parts (5) of the cross bars (3) run in two sets of straight lines, which are oriented obliquely opposite to the reinforcing bars (2, 6), and

c) each reinforcement bar (2, 6) of the lower flange is welded to the angled parts (5) of the cross bars (3) at each point of contact (7).

2. Lattice girder according to claim 1, characterized in that all angled parts (5) of the cross bars (3) lie in the same plane.

3. Lattice girder according to claim 1 or 2, characterized in that the opposite obliquely out directed, angled parts (5) of the cross bars (3) are each arranged in pairs.

4. Lattice girder according to claim 3, characterized in that the angled parts (5) of the cross bars (3) are loops of loop coils.