DE102016124226A1 - Lattice girder for concrete structures - Google Patents

Abstract

Lattice girder and method for its manufacture, wherein flocks of thread or yarn-shaped individual elements (10) are provided, which are arranged as sections of a belt (12, 12 ') and of struts (14) and in such a way that their multiplicity a total carrying capacity of the lattice girder (1) leads.

Description

The invention relates to a lattice girder for structures, in particular concrete structures. A lattice girder is a girder that consists of a plurality of rods that are placed diagonally above one another and connected to form a grid at the crossing points. The upper and lower edges are fixed with light rods. This construction method is closely related to the truss and traditionally uses wood as a building material.

Steel lattice girders are often used in concrete construction, where they fulfill two main tasks in the production of concrete slabs, namely securing the bond between the finished slab and in-situ concrete in the final state and improving the load-bearing capacity (assembly rigidity) of the finished slab in the assembled state. In addition, lattice girders z. B. can be used as a spacer for the upper reinforcement. Such a well-known lattice girders disclose the publications DE 195 15 638 A1 . DE 20 2013 011 404 U1 and DE 10 2013 210 232 A1 ,

Common steel lattice girders or general metal lattice girders for use in precast concrete parts and semi-finished concrete parts (prefabricated filigree parts for walls and ceilings or roofs) are susceptible to corrosion. There is therefore an effort to produce these from a non-corrosion-sensitive material.

Various solutions are known from the prior art, use corrosion-resistant textile materials as reinforcement. This is how the document describes DE 290 29 74 A1 a building board, but in which the textile reinforcement is provided only on the outer surfaces, thus no lattice girder is provided to increase the stability. Another building board, known from the publication DE 28 55 194 A1 has a structure inside, is formed by rigid webs between the limiting cover layers. Although the webs stabilize the position of the cover layers, but are unsuitable for the removal of loads in the sense of a lattice girder.

Other textile reinforcing elements use reinforcing bars, which are initially made of fiber-reinforced plastic and then joined together. However, the reinforcing bars are inflexible in application and arrangement and have, due to the plastic layer, deficiencies in the connection between the reinforcing fiber and the matrix material, especially the concrete.

In the publication DE 10 2012 101 498 A1 is provided within a complex component, a support shell. For a specific embodiment of the tray, a textile tray reinforcement (see claim 13) is described, with other features or details are not specified.

From the publication DE 28 36 456 A1 are packing of hard foam plastic or lightweight concrete for ribbed and beamed ceilings and similar roof panels are known in which the area lying under bending stress in the train area is completely or in strips provided with a tensile reinforcement. For this tension reinforcement, various embodiments provide textile materials, especially fabrics (see page 6, paragraph 4), in particular glass fiber fabric (claim 2) and polyester fabric (claim 3). With simple fabrics, however, no load-compatible arrangements of the reinforcing fibers can be achieved.

The publication DE 10 2005 015 442 A1 describes thin-layered ceilings in sandwich and composite construction, in which a textile reinforcement is provided. However, this is designed only as a woven fabric and therefore without the ability to choose a load-oriented yarn arrangement can.

In addition, no flat or spatial lattice girders are known specifically from carbon materials for concrete construction. There exist at best textile structures in which the intersecting thread or yarn layers are connected by sewing technique or by bonding with EP resins. Non-metallic materials can not be built up by the previously common punctiform connection of the rod elements by welding to a lattice girder. Although metal lattice girders can be welded, they are sensitive to corrosion, but at least relatively expensive.

It is therefore an object of the present invention to provide a corrosion-resistant and fixed position reinforcement, which can also be used as a lattice girder.

The object is achieved by a lattice girder comprising shares of relatively soft thread-like or yarn-shaped individual elements, which are arranged as belt sections and strut sections and in such a way that they ensure the total carrying capacity of the lattice girder by their multiplicity. As belt the loaded on train or pressure upper and lower portions of the lattice girder are called, the struts form the connection between the straps and keep them on the one hand at a distance and connect these on the other hand frictionally, in the sense of transverse force reinforcement in construction.

Carbon fiber, rovings, yarn or the like is preferably provided as the material of the thread-like or yarn-shaped individual elements. Likewise, glass or basalt can be used for Use come. These thread-like or yarn-shaped individual elements, also referred to as monofilaments, are provided with load-dependent different overall cross sections. An overlap of monofilaments is provided in order to realize larger belt cross-sections. The arrangement of many individual threads spaced from each other is provided in order to accommodate in particular corresponding strut forces in the bandage can. The strength, the load-bearing capacity of the lattice structure is determined by the distance between the individual threads and the load capacity or rigidity of the individual threads. The carrying capacity of the straps is determined by the overlap of the individual threads at the edge of the web. The mutual fixation of the monofilaments takes place, at least in the flat precursor, the textile reinforcement web, preferably by a sewing technique. Supporting threads in the 0 ° and 90 ° directions can be integrated into the production of the web. The webs thus produced can be rolled up and thus easily transported and stored.

The dissolution of the mesh and belt elements into a plurality of threads makes it easy to connect them and thus produce an overall rigid reinforcement element that meets the requirements of concrete construction. In this case, the statics of the semi-finished parts must be ensured to accommodate the loads for the completion of the concrete section and to meet the static requirements of the finished construction.

An advantageous development of the invention provides that at least one of the lattice girders or a set of parallel lattice girders on one side or on both sides of a supplementary belt, z. B. a concrete belt, which is provided in addition to the formed of textile material belt. A statically required supplementary or concrete belt (compression or tension side) can be easily supplemented in a separate operation. A double-sided supplementary or concrete belt is also provided. Instead of concrete, another matrix material is generally considered. Due to the strut structure, the elements have a relatively good lateral force-bearing capacity and can also be used as short shear allowances.

The object is further achieved by a method for producing a lattice girder according to the above description, wherein a monofilament (also a roving o. Ä.) From one edge of a future or already partially existing textile reinforcement track is led to the other edge and then over a certain length runs parallel to the edge, before he is led back to the first page. This thread pattern is supplemented by further threads, which are each shifted in the longitudinal direction by one unit. This creates a flat lattice structure as a textile web and at the edges of the lattice structure several threads are always laid parallel to each other. They thus form a continuous, higher-strength belt over the longitudinal extent of the lattice structure.

It has proved to be advantageous if the anchoring of individual threads between the belt and strut by deflection of the threads when changing from the belt function is achieved in the strut function. The problem of anchoring individual threads together, especially with carbon threads, is solved by the deflection of the threads when changing from the belt to the strut function. This procedure replaces the welding of belt and strut sections in conventional lattice girders. By using a plurality of threads, it is possible to largely adapt the structure in terms of their resistance to the requirements, in particular with regard to the static. Any belt and strut cross sections can be produced by overlapping and corresponding thread spacing of the individual threads.

A particularly advantageous embodiment of the method according to the invention comprises in a first manufacturing step, the production of the lattice structure as a textile armor, whereby the use of existing process technology for flat textile scrim for three-dimensional components is possible by first the textile reinforcement sheet is made.

In a second production step, the textile reinforcement sheet is provided with a curable coating, followed immediately by a third production step, in which the textile reinforcement sheet is erected in such a way that a three-dimensional structure of the lattice girder is formed. In a subsequent fourth production step during which the coating cures, the lattice girder is fixed by the then hardened coating. The fixation and stiffening of the threads can also be done by cement, in particular fine cement, which is then used as a curable coating. Thus, according to the invention, initially a flat production and a subsequent folding to the finished lattice girder are provided. Fixation and stiffening of the threads is preferably carried out by conventional coating and impregnation techniques, as they are known for example from the production of textile reinforcements for textile concrete.

An advantageous embodiment of the method according to the invention provides that on the lattice girder at least one belt made of concrete subsequently supplemented and frictionally connected to the lattice girder by the lattice girder, for example, partially inserted in fresh concrete.

Reinforced concrete components are sized according to the load assumptions. The type, quantity, geometry and position of the reinforcement are selected in such a way that the component or the structure resists the effects and safe use over the entire service life is ensured. The invention ensures that form and position of textile reinforcing elements remain unchanged from the assembly state through the construction state to the final state and that the occurring stresses can be reliably removed in all states.

An endless production of the lattice girder, based on an infinitely long textile web, has proved to be advantageous, wherein individual lattice girders are separated off in the required length. The endless production of the carriers based on a theoretically infinitely long textile web thus leads to the lossless separation of the finished products.

The lattice girder is not made of a few single, relatively strong, load-bearing elements for struts and straps, but from a bevy of relatively soft individual elements, threads or yarns that ensure the total carrying capacity by their large number.

The basic structure, a flat textile reinforcement track, is formed by a thread changing from one edge of the textile web to the other and then running parallel to the edge over a certain length before changing sides again. The thread meanders there according to an intended, preferably load-dependent system over the web. This thread pattern is complemented by other individual threads, which are each shifted in the longitudinal direction by one unit. This creates a grid structure on the track. At the edges of this grid structure several threads are always parallel and thus form a continuous belt over the length.

The coating and / or impregnation of the individual textile fabrics, in particular the preferably provided carbon, basalt or glass fibers, gives the structure the required rigidity and strength. In this process, the textile reinforcement web is also transferred from the flat to the spatial state (U to V cross-sectional shape). With the curing or crosslinking of the coating and / or impregnation, the spatial stability is also produced.

The stackable lattice girders can be supplemented in this state to semi-finished parts (concrete mirror) or they are provided in an additional step with a concrete upper chord or they can be used as a thrust supplement and the like. Processed in semi-finished parts or as a pure support, you can absorb the required stresses when working on a concrete construction site as reinforcement elements.

Due to the large number of individual elements and the compounds are resolved accordingly and it must be transmitted in each individual connection a correspondingly smaller force. By using continuous individual threads eliminates the anchoring problem of each thread. These are adequately anchored by the deflection between the strut and the belt and the connections.

The lattice girders are preferably first produced as a planar textile structure and can thus be provided with any desired coatings in the conventional processing processes. If, according to a preferred embodiment, an open design (U-shape to V-shape as cross section) is selected, the finished lattice girders are stackable and can be easily transported.

Further details, features and advantages of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying drawings.

1 shows a schematic plan view of an embodiment of a textile reinforcement sheet 1' for a lattice girder according to the invention with continuous individual threads 10 who has a belt 12 (shown as a thick solid line) and a belt 12 ' (shown as thick dashed line) forms when several individual threads were laid parallel and fixed. Once the monofilament 10 between the straps 12 respectively. 12 ' runs, it forms a footbridge 14 , This can be bundled or, as shown here, be formed as spaced apart individual webs.

2 shows a schematic representation of the sequence of the third method step, in which a three-dimensional structure of the lattice girder 1 from the textile reinforcement track 1' with the individual threads 10 is formed by the side wings of the reinforcement track 1' be folded down, represented by two arrows. On the side walls of the lattice girder 1 are the bars 14 arranged the upper strap 12 with the lower straps 12 ' connect. In the subsequent fourth production step, the lattice girder is fixed by the hardened coating.

3 also shows a schematic representation of an embodiment of a lattice girder according to the invention 1 after application of the method according to 2 , The textile reinforcement track 1' is folded, so that the three-dimensional structure of the lattice girder 1 is formed. It forms the continuously represented thread or the thread bundle the lower straps 12 , the thread shown as a dashed line or the thread bundle the upper strap 12 ' , Between the straps 12 . 12 ' the bridges run 14 ,

LIST OF REFERENCE NUMBERS

1

 girder

1'

textile rebar for lattice girders

10

Monofilament, filament or yarn-shaped single element

12

lower belt

12 '

upper belt

14

web

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19515638 A1 [0002]
• DE 202013011404 U1 [0002]
• DE 102013210232 A1 [0002]
• DE 2902974 A1 [0004]
• DE 2855194 A1 [0004]
• DE 102012101498 A1 [0006]
• DE 2836456 A1 [0007]
• DE 102005015442 A1 [0008]

Claims (9)

Lattice girder, characterized in that flocks of thread or yarn-shaped individual elements ( 10 ) provided as sections of a belt ( 12 . 12 ' ) and of aspiration ( 14 ) and are arranged in such a way that their multiplicity lead to a total carrying capacity of the lattice girder ( 1 ) leads. Lattice girder according to claim 1, wherein the material of the thread-like or yarn-shaped individual elements ( 10 ) Carbon, basalt and / or glass is provided. Lattice girder according to claim 1 or 2, wherein the thread-like or yarn-shaped individual elements ( 10 ) are provided with load-dependent different overall cross sections. Lattice girder according to one of claims 1 to 3, wherein at least one of the lattice girders ( 1 ) on at least one side an additional belt ( 12 . 12 ' ) made of concrete or of another matrix material. Method for producing a lattice girder according to one of claims 1 to 4, characterized in that a thread-like or yarn-shaped individual element ( 10 ) from an edge of a future or already partially existing textile reinforcement track ( 1' ) is guided to the other and then runs over a certain length parallel to the edge, before it is again guided to the opposite side, said thread course being characterized by further threads, which in the longitudinal direction in each case by a distance of a web ( 14 ), so that a flat lattice structure as a textile reinforcement sheet ( 1' ) and at the edges of the lattice structure always several thread-like or yarn-shaped individual elements ( 10 ) are laid parallel to each other and so a continuous, higher-strength belt ( 12 ) over the longitudinal extent of the lattice structure. Method according to claim 5, wherein the anchoring of the thread-like or yarn-shaped individual elements ( 10 ) between belt ( 12 . 12 ' ) and strut ( 14 ) by deflection of the thread-like or yarn-shaped individual elements ( 10 ) is achieved when changing from the belt function in the strut function. A method according to claim 5 or 6, wherein in a first manufacturing step, the production of the lattice structure as a textile reinforcement sheet ( 1' ), in a second production step, the textile reinforcement sheet ( 1' ) is provided with a curable coating and in a third manufacturing step, the textile reinforcement sheet ( 1' ) is erected in such a way that a three-dimensional structure of the lattice girder ( 1 ) is formed, and in a fourth manufacturing step of the lattice girders ( 1 ) is fixed by the cured coating. Method according to claim 7, wherein on the lattice girder ( 1 ) at least one supplementary belt made of concrete added later and frictionally with the lattice girder ( 1 ) is connected by the lattice girder ( 1 ) is partially inserted in fresh concrete. Method according to claim 7 or 8, wherein a continuous production of the lattice girder ( 1 ), based on an infinitely long textile reinforcement track ( 1' ), and the individual lattice girder ( 1 ) are separated in the required length.

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