DE3325879A1 - Reinforcing lattice made of various materials - Google Patents

Abstract

Published without abstract.

Description

Reinforcement grids made from various materials

The invention relates to eill reinforcement grids from various MaterialsR for mineral setting compounds, adapted to the intended use Strand sizes and mesh sizes.

In the case of masses forming layers, it is well known that the Longevity and strength in a special measure of the quality of the reinforcement depend. As practice has shown, grid-like reinforcements can do good Successes are achieved. However, care must be taken that they are with each other plant peat or masses that come into contact with one another, so to speak. It is known, for example, that mineral setting compounds are hostile to glass fibers, in other words, a material that is very important for reinforcements and reinforcements owns. For the state of the art, reference is made to DE-OS 30 32 533 A1.

According to this prior publication it is known a glass silk grating to soak with synthetic resin and then sprinkle shredded fibers on the wet grid. In itself this method is correct, but not yet perfect enough to e.g. Keep hydrated lime plaster away from the glass fiber material of the grille at all points, i.e., at one The plaster can remove certain areas through capillary action become effective, which sooner or later leads to a loss of mechanical strength.

Even with wire mesh, especially spot-welded and galvanized Wire mesh, difficulties arise because the mineral bound plaster layers have a relatively coarse-grained porous structure, what stands in the way of a good bond between the reinforcement and the reinforced compound.

In contrast, the invention is based on the object of one of the to design various materials existing reinforcement grid so that it is free of the defects described, i.e. it should be used against every mass, in particular to be resistant to any plaster compound and, on the other hand, to be an optimal one Lead reinforcement effect.

These optimal reinforcement and plaster base properties should also be given with wire mesh.

This object is achieved according to the invention in that the respective The grid has a tight covering on all sides and the at least one-layer Sheathing serves as a carrier and binding layer for fiber chips. Since the respective If the grille is tightly encased on all sides, aggressive plasters cannot affect the Strands act so that a loss of mechanical strength is not to be feared is. As a material for the fiber chips, such materials are expediently used, which are insensitive to mineral setting compounds from the outset. In any Case, the new reinforcement mesh is ideally suited, durable and against chemical Influences to obtain permanent consolidations without adding anything intolerable Effort required. For example, one can meet optimal requirements Grid in the Way to get that a fiberglass mesh in a continuous process impregnated with synthetic resin and cured and then with a synthetic resin layer is sheathed, whereupon then, with the sheathing still adhesive, chips, fibers or a kind of grain size can be used. It goes without saying that a multilayer or multi-layeredness is a great advantage in that it means that, to a certain extent an absolute tightness is achieved, which in turn increases the longevity of the respective association. Metal layers also have the advantage that once you can use a material that has good impregnation properties and on the other hand, there is nothing in the way of the selection c Read well-adhesive material. Exposed let it be said again that the shredded fibers anchored in a tangled manner to the carrier and binding layer Od. Like. A fibrous rough structure that is suitable together with the Lattice strands to reinforce the respective wet, e.g. plaster, excellently.

If, despite the well-known properties of Use glass fiber chips against mineral-setting compounds wants, then the invention provides that sheathing as well as shredded fibers with are provided, for example, with a sprayed-on film-forming coating. Such a cover protects the fibers sufficiently from the aggressiveness of the respective.

Plaster.

Furthermore, it is conceivable according to the invention that the all-round seal Sheathing is applied to an impregnated fiberglass mesh. Beyond that notes that impregnating a fiberglass mesh increases the mechanical Brings strength with it.

According to the invention, it is also useful that the all-round density, for example made of synthetic resins, plastic dispersions, bitumen or the like. existing sheathing surrounds a wire mesh or its rods. A wire mesh can be used for this with binding agent, e.g. coated with bitumen and then with a scattering be provided by fiber chips. The after the hardening or drying of the binding agent multiply tangled fiber chips anchored in the binder layer the binding surface of the wires and give the wire reinforcement grid a optimal interlocking effect for the layering compound, e.g. for plaster. The confused of the Fibers protruding from the wires also act as a well-balanced fiber reinforcement for the layer mass itself.

Bitumen, for example, is also a useful protection against corrosion for the grid itself. Of course, the same can be done, for example, with synthetic resin dispersions reach.

Another feature of the invention is that a heated Wire mesh accommodates the fiber shreds made of thermoplastic material and the grid can be protected against corrosion. In practice this means that one simply heats a wire mesh and through an accumulation of shredded fibers made of thermoplastic material, the fiber shreds to a certain extent be melted or welded to the bars. A similar effect can be achieved if the grid is protected against corrosion beforehand, which in addition the dense sheathing, recognized as advantageous, is created.

If one considers the clawing effect, which has already been recognized as advantageous wants to improve between layer compound and reinforcement even further, then recommends it is according to the invention that a fiber material with specific for the fiber chips large surface, for example splicing threads made of divorced Fabrics are used that are appropriately cut onto the sheathing are. This is because splicing threads are not smooth, but protrude from their surfaces Fibers from which the force-fit connection between reinforcement and arir rter Raise mass qualitatively. In this direction it is also an advantage if after of the invention, the length of the fiber chips to be applied is in a ratio moved from 1: 1 to 1: 3 of the mesh size of the respective grid and the applied Fiber chips in order to achieve a free passage for the to be reinforced Measure the middle area of the mesh in the weFc.

To explain the idea of the invention, it should be mentioned that the strand thickness and mesh size of a grid in certain proportions to the armored masses and must stand up to their strengths. But this only comes into play with the invention in second line on; What is important, however, is that the fiber chips are tightly dense Sheathing are anchored, which in turn are inextricably linked to the grid stands.

In the drawing, the invention is illustrated by way of example; The figures show: FIG. 1 a reinforcement grating according to the invention viewed from the broad side and FIG. 2 shows a nodal point of the grid according to FIG. 1, seen from above and strongly enlarged.

As can be seen from Fig. 1, a reinforcement grid 1 consists of longitudinal strands 2 and transverse strands 3. All strands 2, 3 have randomly protruding fiber chips 4 so that the meshes 5 themselves act like a grid and irregular.

The node according to FIG. 2 shows that the strands 2, 3 at 6 are glued together. In addition, the sectional view of this FIG recognize that the strands 2, 3 are surrounded by a dense jacket 7, which is not has leaks. The jacket or the casing 7 consists in the embodiment from two layers or

Layers 8, 9. For example, layer 8 is the result of an impregnation process of strands 2, 3, i.e. an outer skin 8 has formed, while the second Layer 9 is a carrier and binding layer applied in any way for the fiber chips 4 represents. It goes without saying that strands 2, 3 made of a wide variety of materials can exist; wire grids are also conceivable without thereby affecting the idea of the invention is diminished. The same applies to the shape of the grids and the type of connection of strands 2, 3 with each other.

Claims (7)

Reinforcement grid made of different materials claims t. Reinforcement grids made of various materials, for mineral-setting liquids, with strand sizes and mesh sizes adapted to the intended use, characterized in that that the respective grid (1) has an all-round sealed casing (7) and the at least one-layer sheathing (see FIG. 9) as a carrier and binding layer for Fiber shredded (4) is used. 2. Reinforcement grid according to claim 1, characterized in that sheathing (7) and fiber chippings (4) with a film-forming top layer, for example, sprayed on are provided. Reinforcement grid according to claim 1 or according to claims 1 and 2, characterized in that the all-round sealed casing (7 or 8) on a impregnated fiberglass mesh (1) is applied. 4. Reinforcement grid according to claim 1 or according to claims 1 and 2, characterized in that the all-round density, for example made of synthetic resins, Arts- Material dispersions, bitumen or the like. Existing casing (7) surrounds a wire mesh or its rods. 5. reinforcement grid according to claim 1, characterized in that a heated wire mesh the fiber shreds made of thermoplastic material (4) and the grille (1) can be protected against corrosion. 6. reinforcement grid according to claim 1, characterized in that for the fiber chips t4) a fiber material with a specific large surface, for example Splicing threads made from different materials are used and cut accordingly are applied to the casing (7). 7. Reinforcement grid according to claims 1 to 6, characterized in that that the length of the fiber chips (4) to be applied is in a ratio of 1: 1 to 1: 3 of the mesh size (cf. 5) of the respective grid moves and the Applied fiber chippings (4) essentially form the middle area of the meshes (5) set free.