DE3625810A1 - Latticed girder - Google Patents

Abstract

The invention relates to a latticed girder, in particular as a reinforcing element for reinforced concrete, having at least one top longitudinal member, one bottom longitudinal member and at least one deformed connecting element which comprises a round bar and is connected to the longitudinal members at the points at which it makes contact therewith. The object of the invention is to design a latticed girder of the abovementioned type such that, along with simple production, a high degree of strength and accuracy of the connecting points can be achieved. This object is achieved in that each longitudinal member has a cross-sectional profile with at least one rounded indent for the positively locking abutment of the connecting element at the points of contact, and in that the transitions from the indent to the longitudinal-member periphery are rounded.

Description

The invention relates to a lattice girder for reinforced concrete the Gat described in the preamble of claim 1 tung.

Such lattice girders are be as reinforcement elements knows, for example from DE-PS 33 07 155. It han is a bundle of rods made up of three or more spars and between them spatially in zigzag lines stretching fasteners. At the touch point len is the spar with the touching connection Ver tion element by spot welding bound. Reinforcement elements of this type have, in particular re in load-bearing vertical or horizontal supports, bean endure spells of different kinds, in which the connection points are significantly burdened. Theirs exact placement as well as their firmness and the possible Power transmission at the connection points are therefore essential for the properties of the finished component. The same requirements apply to lattice girders len to be used as a lightweight support without concrete coating are put. Lattice girders are known in which spars and connecting elements have V or angle profiles.

The object of the invention is a lattice girder of ge described type so that in simple terms  position a great strength and accuracy of the ver binding points can be achieved.

The object is achieved by the features of Claim 1 solved.

The positive engagement of the connecting element the correspondingly rounded indentation of the longitudinal bar creates a liaison that is not just theories table is punctiform but flat. It follows there is inevitably an exact arrangement of the connecting element mentes in the contact area as well as one opposite the Be knew increased power transmission. The rounded over aisles of the indentation facilitate the placement of the ver binding element in the manufacture. The automatic Manufacture of the lattice girder is this way relieved.

The feature of claim 2 makes every longitudinal spar a lot mutually usable in the truest sense of the word, d. H. also for three-dimensional lattice girders. Every spar can two or more other bars through connecting elements be connected, the extension planes with each other form an angle. The centric-symmetrical arrangement also has the advantage that when the Longitudinal bars through rolling and / or cold drawing no cracks form.

The features of claims 3 and 4 speak execution form the longitudinal spars, the cross sections of which are essentially Lichen consist of adjacent circles. The In this way, Holm resembles a bundle close together of fixed rods, for example three or four.  

The cross-sectional shape also decreases with reinforcement elements the slip between concrete and reinforcement.

In a preferred embodiment according to the feature of claim 5, the longitudinal spars are made of nonro steel. This has significant advantages of the lattice girder. Manufacturing is simplified because such a steel, for example according to DIN 4571, a Profiling first by rolling and then Cold forming enables. The Festig also allows cross-sectional dimensions of this material significantly below the previously common cross-sections the use of normal structural steel. Corresponding the dimensions of the lattice girder and can be small Use as a reinforcement element of the corresponding Reinforced concrete component. The additional costs for the Be Reinforcement is made by saving concrete as well if necessary, additional casings, for example se for thermal insulation, more than paid. You can also such thin components - with the same load capacity - influence the entire building design favorably. The with stainless steel there is an increased risk compared to normal mild steel of slip between concrete and reinforcement is due to that Profile, as stated above, caught.

The strength values of the lattice girder will continue to be increased by the feature of claim 7.

The remaining claims speak further embodiments of lattice girders for various to be manufactured with it Components, as well as different manufacturing options keiten.

Embodiments of the present invention will be described below Lattice girders and their special advantages based on the Described drawings. It shows  

Fig. 1 shows a portion of a lattice girder in a perspective view;

Fig. 2 shows a corresponding section of an embodiment to which a Gitterträ gers,

Fig. 3 shows a stringer cross section in an enlarged scale;

Fig. 4 is an enlarged view of a Gitterträ gers,

Figure 5 is a side view of a further terträgers Git.,

Fig. 6 is an enlarged view of a section along the line VI-VI in Fig. 5,

Fig. 7 is a sectional view of a Gitterträ gers of FIG. 5, in a concrete component

Fig. 8 is a sectional view of another embodiment and

Fig. 9 the side view.

In a lattice girder, of which Fig. 1 shows a section, three longitudinal spars 1 are arranged parallel to each other so that they form the corners of an equilateral triangle in cross section. Each longitudinal spar 1 has a cross-sectional profile 2 with three rounded indentations 2 a . This will be discussed in more detail below. Between the upper longitudinal spar 1 and the lower longitudinal spars un extend approximately zigzag from angled connecting elements 3rd Between the lower longitudinal spar just such connecting elements 3 are arranged. The connecting elements 3 have circular cross section. Both the longitudinal spars 1 and the connec tion elements 3 are made of stainless steel with high strength properties.

The connecting elements 3 lie on the contact points len, some of which are designated 4 , with the longitudinal spars in a form-fitting manner in the indentations 2 a . The longitudinal beam 1 and the connecting element 3 in question are connected at the contact point 4 by one or more welding points 5 . The points of contact and thus welding are on the upper spar. Between the lower spars, the Verbindungsele element runs such that its contact points there are offset to the other connecting elements.

The spars can also have a cross section on the corners of a beosceles triangle.

Fig. 2 shows a portion of another embodiment form of a lattice girder with four longitudinal spars 1 , arranged in cross section at the corners of a square. The connecting elements 3 ' each consist of a round steel formed square. Each of the four square "corners" is positively supported in an indentation 2 a of a longitudinal bar 1 . At these points of contact 4 ' there are welding points, which are not shown for the sake of clarity.

In the embodiment of Fig. 2, the Längshol me can of course be arranged at such intervals that they do not form the edges of a square, son of a rectangular cuboid, with the shape of the connecting elements 3 ' in Fig. 2. Likewise, an arrangement possible from only three longitudinal spars 1 in the form of an equilateral or non-equilateral triangle. In this case, the connecting elements 3 'of FIG. 2 are correspondingly triangular.

Fig. 3 shows an enlarged view of the cross-sectional profile 2 of a longitudinal bar 1 . The dash-dotted circles make it clear that the entire profile is based on circular shapes with all the same radius R. Three touching circles with this radius form the essential part of the cross-sectional profile 2 . They also each deliver a convex circular arc section 6 for the circumferential section of the cross-sectional profile. The transitions between these convex circular arc sections 6 form concave circular arc sections 7 , likewise with the radius R. They form the indentations 2 a of the cross-sectional profile 2 .

Fig. 4 is a view showing, on a large scale, again a lattice girder with four longitudinal beams 1 with the clear in the recesses 2 a form-locking abut the connecting elements 3.

Figs. 5 to 7 relate to a further embodiment of a lattice girder which extends in only two dimensions he stretches. Between an upper longitudinal spar 1 ' and a lower longitudinal spar 1' extends a Verbindungsele element 3 '' . Between its inclined struts 3 '' a from mock to mock, it lies with a web 3 '' b in the respective recess 2 a 'of the spar in question. In this area of contact 4 ' , the connection is made by welding 5 . The cross-sectional profile 2 a 'of the spar 1' can be seen in the sectional view in Fig. 6. It has four indentations 2 a ' , which lie opposite one another in pairs and are distributed symmetrically over the circumference. The cross-sectional profile 2 ' is essentially formed from five circles with the radius R , four of which are arranged symmetrically around a fifth. The between the convex circular arc sections 6 arranged indentations 2 a ' are formed by concave Kreisbo gene sections 7 with the radius R.

FIG. 7 shows a reinforcement element according to FIG. 5 in a finished reinforced concrete component 8 . Such components can be economically small in size: thanks to the good power transmission between the longitudinal spars and the connecting elements, the reinforcement can be subjected to heavy loads thanks to the form-fitting system at the connection points. The formation of the reinforcement made of stainless steel with high strength properties increases this property. In addition, the reinforcement made of stainless steel does not require the usual thick concrete sheathing as corrosion protection.

FIGS. 8 and 9 show a further embodiment ei nes truss. The spars 1 ' correspond to their cross section 2' the spars of Fig. 5, the Verbindungselemen te 3 '' also. In the lattice girder four bars 1 'are arranged on average as on the corners of a rectangle. The connecting elements 3 '' each extend between the rule belonging to a rectangular side spar pairs. The spar pairs on the two narrow sides of the fictitious rectangle, the upper and the lower spar pair in FIG. 8, and the associated connecting elements each form the reinforcement of a concrete beam 9 . The areas around the contact points 4 'of those reinforcement elements 3' , which extend in the longer sides of the rectangle, are embedded in the concrete beams 9 . However, the essential lengths of these connecting elements are exposed. When it is made from stainless steel, no corrosion protection by concrete is necessary. This results in a significant weight saving compared to a fully solid concrete beam with appropriate reinforcement.

The invention is not limited to the exemplary embodiments described. Longitudinal bars with a cross section as in Fig. 6 can of course also be used for three-dimensional reinforcements. The Ver connecting elements can extend in spar arrangements as in FIGS . 1 and 2 or in a triangular arrangement of the longitudinal spars spatially shaped between more than two longitudinal spars.

Instead of welded joints can be touched make the connection also made by gluing be.

Claims (16)

1. Lattice girder, in particular as a reinforcing element for reinforced concrete, with at least one upper longitudinal spar, a lower longitudinal spar and at least one deformed Ver connecting element made of round steel, each of which is connected at its contact points with the longitudinal spars with these, characterized in that each longitudinal spar (1) a cross-sectional profile (2) with at least one ge rounded recess (2 a) for form-fitting contact of the connecting element (3) provide to the touch (4), and that the transitions are rounded from the indentation (2 a) with the stem circumference . 2. Lattice girder according to claim 1, characterized in that each longitudinal spar ( 1 ) has two or more, preferably three or four, indentations ( 2 a) in cross-section in a centrally symmetrical arrangement on the circumference. 3. Lattice girder according to claim 1 or 2, characterized in that the circumference of the cross-sectional profile ( 2 ) of the longitudinal spar ( 1 ) between the indentations ( 2 a) each consists of convex circular arc sections ( 6 ) and the indentations ( 2 a) of concave Circular arc sections ( 7 ) are formed. 4. Lattice girder according to claim 3, characterized in that all circular arc sections ( 6 and 7 ) have the same chen radius (R) . 5. Lattice girder according to one of claims 1 to 4, characterized in that the longitudinal spars ( 1 ) consist of stainless steel. 6. Lattice girder according to claim 5, characterized in that the longitudinal bars ( 1 ) are profiled by rolling from round steel and subsequent cold drawing. 7. Lattice girder according to one of claims 1 to 6, characterized in that the connecting element ( 3 ) consists of stainless steel. 8. Lattice girder according to one of claims 1 to 7, characterized in that the connecting element ( 3 ) consists of one or more helically deformed, in the longitudinal direction of the lattice girder carrying rods. 9. Lattice girder according to one of claims 1 to 7, characterized in that as a connecting element ( 3 ' ) closed triangles or quadrilaterals are each held within a triangle or square of spars ( 1 ) on these. 10. Lattice girder according to one of claims 1 to 9, characterized in that the bars ( 1 ) with the connecting elements ( 3 ) are welded ver at the points of contact ( 4 ). 11. Lattice girder according to one of claims 1 to 9, characterized in that the spars ( 1 ) with the connec tion elements ( 3 ) are glued together. 12. Lattice girder according to at least one of claims 1 to 11, characterized in that it as a whole as Be reinforcement element can be embedded in reinforced concrete. 13. Lattice girder according to at least one of claims 1 to 11, characterized in that in each case the spars ( 1 ) can be surrounded individually or in pairs with reinforced concrete and the connecting elements ( 3 ) remain at least partially free. 14. Lattice girder according to at least one of claims 1 to 11, characterized in that he without concrete umman telung can be used as a lightweight support. 15. Lattice girder according to at least one of claims 1 to 14, characterized in that in cross section four bars ( 1 ) are arranged to each other on the corners of a rectangle or square. 16. Lattice girder according to at least one of claims 1 to 14, characterized in that in cross section three bars ( 1 ) are arranged on the corners of an equilateral or isosceles triangle.