DE2311911A1 - LATTICE GIRDER - Google Patents

Description

Lattice girder The invention relates to a lattice girder for Reinforcement of large-area concrete construction elements in connection with a reinforcement mesh, consisting from a string of struts to which an upper and a lower chord are welded, hook-like support elements protrude laterally from the lattice girder in the lower belt area, a longitudinal rod of the welded wire mesh for hanging the lattice girder into the welded wire mesh reach under while the lower chord is supported on the cross bars of the reinforcement mesh.

There are known lattice girders in which the support elements are formed by the fact that all of the lower Reversal points of the string of struts are laterally bent like loops. It has been shown to be suitable for assembly purposes By no means sufficiently secure connection of the lattice girder to the welded wire mesh as many support elements are required. The bending of all lower turning points the formation of support elements therefore leads to an unnecessary additional consumption of material. This problem is exacerbated if you have a strut length with an angle of inclination used in the order of 50 °, as it is statically most favorable. at The most commonly used Gräger height of 11cm then results in a distance between the Reversal points, which is far smaller than the usual grid size of welded wire mesh. If you surde to bend all the lower turning points to the side here, you would get a large additional material consumption.

The invention is based on the object; a lattice girder the To create the type described at the beginning, with the smallest possible material consumption can have a statically optimal strut position.

This object is achieved according to the invention in that the distance the reversal points of the strut serpentine from each other smaller than the grid dimension of the reinforcement mesh is, and that the support elements are attached to the lattice girder at intervals that correspond to two or more times the grid dimension of the reinforcement mesh.

By attaching the support elements to the lattice girder in one of the two or .Multiple of the grid size of the reinforcement mesh is the corresponding distance on the one hand ensured that the support elements are definitely in the Let the reinforcement mesh hang in without colliding with the cross bars, and on the other hand there is a far lower material consumption than if all the lower reversal points the strut serpent would be bent laterally. The lattice girder can in its struts get the statically most favorable shape.

An embodiment of the invention is shown in the drawing. 1 shows a perspective illustration of a lattice girder according to the invention combined with. a reinforcement mesh, Fig. 2 is a vertical section through the lattice girder, and FIG. 3 shows a vertical section corresponding to FIG. 2 of the welded wire mesh suspended carrier.

In the drawing, 1 generally denotes a lattice girder, that of a continuous string of struts bent continuously from round material 2, a channel-shaped upper chord 3 welded to the strut coil and one There is also a lower chord 4 welded to the strut coil. Like Fig. 2 shows, the top chord can also be designed as a round steel 3 '. The lower chord is also designed as round steel and laterally in the area of the lower reversal points the strut coil 2 is welded to this.

Under the lower chord are hook-shaped or bow-shaped support elements 5 welded, which protrude laterally from the lattice girder 1.

As can be seen from Fig. 1, the lattice girder 1 is in a welded wire mesh G suspended, which consists of longitudinal bars 6a and 6b cross bars. The grid dimension of the Welded wire mesh is denoted by R. The distances between the support elements 5 from one another, which are welded to the lower chord 4 outside the lower reversal points 2a of the strut coil are, amount to 2 R, but could also be a multiple thereof.

In contrast, the distance A of the reversal points of the string of struts is 2 from each other smaller than the grid dimension R.

As can be seen from FIGS. 1 and 2, the hook-like grip Support elements 5 under a longitudinal bar 6a of the reinforcement mat 6, while the lower chord 4 is supported on the cross bars 6b of the reinforcement mesh. To rip the lattice girder 1 to prevent counterclockwise in Fig. 2, a rod 7 is so through the hook-shaped Support elements 5 pushed through that it is with a 7Sde on the lower chord 4 and with the other end on an adjacent longitudinal rod 6a or, as in FIG. 1 shown, supported on a cross bar 6b of the welded wire mesh.

Claims (2)

P a t e n t a ii 5 p r ü c h e 9 lattice girders for reinforcing large-scale concrete construction elements in connection with a reinforcement mat, consisting of a string of struts to which an upper and a lower chord are welded on, with the lattice girder in the lower chord area laterally protrude hook-like support elements for hanging the lattice girder in the welded wire mesh reach under a longitudinal bar of the welded wire mesh, wilrend the lower chord on the Supports cross bars of the welded wire mesh, thereby g e k e n n n z e i c h n d t that the distance (A) of the reversal points (2a) of the string of struts (2) from one another is smaller than the grid dimension (R) of the reinforcement mat (6), and that the support elements (5) on Lattice girders (1) are attached at intervals that are two or more times the Grid dimensions correspond to the reinforcement mesh. 2. Lattice girder according to claim 1, characterized in that g e k e n n -z e i c h n e t that the support elements (5) outside of the reversal points (2a) of the string of struts (2) are attached to the lower chord (4). Blank page