DE29901676U1 - Reinforcement fiber for the reinforcement of steel fiber concrete - Google Patents

Description

hrxs0024.004
AG/co

Reinforcing fibre for reinforcing steel fibre concrete

The present invention relates to a reinforcing fiber for reinforcing steel fiber concrete, made of steel wire with a round cross-section, which has a substantially straight central section, to which end anchors in the form of shorter, bent end sections are connected at both ends and which is at least partially provided with a corrugation with notches running transversely to the longitudinal extension.

&iacgr;&ogr; Steel wire fibers, as well as sheet metal fibers and milled steel fibers, are known in a variety of designs for reinforcing fiber-reinforced concrete. The spatial reinforcement is simply carried out by adding the fibers to the concrete, which can still be processed as usual.

The properties of the concrete ceiling in terms of bending tensile strength, impact strength and the like are equally influenced by the amount of aggregate - and - in particular by the physical and geometric properties of the steel fibers themselves. In the state of the art, this has led to a large number of designs even in the area of wire fibers with a round cross-section that are each optimized with regard to certain properties.

A steel wire fiber according to the state of the art is described, for example, in DE 92 07 598 U1. This special design has a straight middle section with double bent end sections. This fiber is initially made from steel wire with a circular cross-section. To increase the adhesion in the concrete, a steel wire is subsequently added to the

the essentially straight central section located between the end anchors has a flattened shape. This creates an enlarged active surface in the central area, which is known to be particularly advantageous with regard to preventing the formation of microcracks. The bent end anchors ensure an improved long-range bond.

From DE 90 06 524 U1 and DE 88 1 5 1 20 U1 it is also known to provide the wire surface with corrugation. This provides that the fiber surface is provided with a profile in the form of successive notches or the like running transversely to the longitudinal extension. This measure improves the local microscopic anchoring of the wire cross-section in the concrete through the enlarged surface together with the geometric shape, thereby preventing the formation of microcracks. In this state of the art it is also already proposed to provide bent end anchors in addition to the corrugation.

In particular, in the last-mentioned state of the art, the aim is to combine the advantages of corrugation and end anchors by combining these two geometric structuring measures in parallel. The embodiments described therein only suggest designs in which the steel wire fibers are made from already corrugated wire by cutting them to length and then bending them at the ends. Although this approach combines some of the advantages of the different structures, it also has disadvantages. The corrugation in the area of the end anchors simultaneously means a weakening of the mechanical tensile strength with regard to the long-range reinforcement between the end anchors. When the wire bends in the area of notches, this effect is obvious due to the notch effect. In addition, the point-based adhesion of the wire surface in the area of the end anchors is not necessary or desired for special applications.

The aim of the invention arises from the aforementioned problem, namely to provide a steel wire fiber which combines the advantages of bent end anchors with the advantages of corrugation in an improved manner.

To solve this problem, the invention proposes, based on the prior art presented at the beginning, that only the central section has notches.

According to the invention, only the section between the end anchors is provided with a corrugation. In comparison to the state

This achieves a certain separation of functions using the technology. While the straight middle section has particularly advantageous properties in terms of preventing micro-cracks due to its structure, the long-range connection is created by the end anchors. According to the invention, the stability of the bent areas is definitely higher than in the prior art, since there are no notches there, which could otherwise lead to weakening due to their notch effect when bending.

Therefore, the particular advantage of the steel wire fiber designed according to the invention lies in an improved microscopic and macroscopic bond, which of course benefits the properties of the fiber concrete as a whole.

It is also advantageous that the notches are only on one side of the wire cross-section. The corrugations, which are arranged axially along a surface line, ensure sufficient reinforcement forces in the longitudinal direction of the wire and, thanks to the asymmetrical local wire cross-section, ensure spatial fixation that is also secured against rotation and shear.

The above-mentioned embodiment is further optimized by the fact that the notches are located on the side of the wire cross-section to which the end anchors are bent. This embodiment assumes that

that all bent end sections and the middle section lie in a single plane, namely the fiber plane. It has been found that the corrugation according to the invention brings about an optimized adhesive effect at this point.

A preferred embodiment of the steel wire fiber according to the invention provides that the end anchors have a first end section bent at an obtuse angle to the middle section and a second end section extending outwards and running parallel to the middle section. This form of a flat steel wire fiber is a particularly proven design which, due to the special shape of the end anchors, has excellent static and dynamic properties, which are further improved by the inventive combination with the corrugation in the middle area.

Preferably, the notches are V-shaped. Such a design is particularly suitable for preventing the formation of microcracks.

The dimensions of the steel wire fibers according to the invention are in a length range between 20 and 60 mm, whereby the wire diameter can be between 0.5 and 1.5 mm.

In some circumstances it may be advisable to provide the fibres with a corrosion-protective coating, such as galvanisation.

As a rule, high-tensile steel with a tensile strength of > 1000 N/mm ² should be used. In some circumstances, the use of stainless and/or hardenable steel is also conceivable. This means that special requirements can be fully taken into account.

An embodiment of a fiber according to the invention is shown in the drawing Figure 1. This shows a view of a fiber lying in the fiber plane,

flat steel wire fiber, which is shown enlarged and as a whole is provided with the reference number 1.

The fiber 1 consists of steel wire with a circular cross-section. It has a straight central section 2, which is connected on both sides by bluntly bent, first end sections 3. The connected second end sections 4, which protrude outwards, in turn run parallel to the central section 2.

Only the straight middle section 2 is provided with a corrugation in the form of V-shaped notches 5 on the side to which the end sections 3, 4 are bent.

The steel wire fiber 1 shown has the advantages already explained due to the notches 5 introduced on one side only in the middle section 2.

The production of a fiber 1 involves first cutting sections of steel wire with a circular cross-section, as is known, whereby the end sections 3 and 4 are bent as shown using an embossing tool and notches 5 are made in the middle section. The bending and notching can be carried out in a single or separate work step.

Claims (9)

Protection claims 1. Reinforcing fibre for reinforcing steel fibre concrete made of steel wire with a round cross-section, which has a substantially straight central section with end anchors in the form of shorter, bent end sections and which is at least partially provided with a corrugation with notches running transversely to the longitudinal extent, &iacgr;&ogr; characterized in that only the middle section (2) has notches (5). 2. Reinforcing fiber according to claim 1, characterized in that the notches (5) are located on one side of the wire cross-section. 3. Reinforcing fiber according to claim 2, characterized in that the notches (5) are located on the side of the wire cross-section to which the end anchors (3, 4) are bent. 4. Reinforcing fiber according to claim 1, characterized in that the end anchors (3, 4) and the middle section (2) lie in a common fiber plane. 5. Reinforcing fiber according to claim 4, characterized in that the end anchors (3, 4) have a first end section (3) bent at an obtuse angle to the central section (2) and a second end section (4) adjoining it to the outside and running parallel to the central section (2). 6. Reinforcing fiber according to claim 1, characterized in that the notches (5) are V-shaped. 7. Reinforcing fiber according to claim 1, characterized in that it is provided with a corrosion-protective coating. 8. Reinforcing fibre according to claim 1, characterised in that it consists of high-tensile steel with a tensile strength > 1000 N/mm ² . 9. Reinforcing fibre according to claim 1, characterised in that it consists of hardenable steel.