HU212747B - Steel wire especially for reinforcing concret - Google Patents

Abstract

The present invention relates to a steel wire, particularly for reinforcing concrete, having a cross-sectional shape along its length and having a distorted surface. The steel wire according to the invention is characterized in that it has sections of irregular octagonal and rounded corners of irregular octagon with rounded, rounded corners along its length. FIGURE 2 EN 212 747 B Scope of the description: 6 pages (including 2 sheets)

Description

FIELD OF THE INVENTION This invention relates to steel wires, particularly for reinforcing concrete.

It is known that steel wire is embedded in concrete to improve the strength properties of concrete. Improvement of the connection between concrete and steel wire is achieved by the specific surface finish of the steel wire. Threads of steel wire have been recently developed to provide thread-like finishes, but there are other solutions that reflect surface design.

The steel wire according to the invention is intended to further develop solutions with a threadlike surface.

It should be noted that embedded steel wire is used not only in concrete structures but also in other industrial areas. so e.g. In the rubber industry, there are also products - mainly conveyors, tires - where steel wire is embedded in the rubber to improve the strength properties of the product. However, in view of the fact that the largest weight of steel wire for embedding is used by the construction industry in reinforced concrete structures, the present invention is directed mainly to steel wire for reinforcing concrete.

There is a multidirectional requirement for steel wire for the same purpose as the invention, i.e. for embedding. The requirements relate, on the one hand, to the intrinsic strength properties of the steel wire and, on the other hand, to the working of the steel wire with the concrete embedded in it.

With regard to the strength properties of the steel wire, it is mainly to be kept in mind that the strength, elongation, relaxation, yield strength, fold number of the finished steel wire reaches a certain value.

The surface finish of the steel wire is of decisive importance for the satisfactory working of steel wire and concrete. Surface geometry - or cross-sectional geometry - can greatly influence the anchoring of steel wire in concrete.

The general aspect of the steel wire manufacturing process is that the process improves or at least does not degrade the otherwise possible strength properties of the steel wire, and that it is possible to produce steel wire of the design geometry as simple and inexpensive as possible.

With the use of the steel wires of the invention having a threadlike appearance, a so-called twist phenomenon occurs. This means that such steel wire embedded in the reinforced concrete structure tends to rotate around its own longitudinal axis under load. This rotation, if it occurs, is detrimental because it impairs the anchoring of the steel wire in the concrete and ultimately the strength of the reinforced concrete structure - its bearing capacity - is reduced. To avoid this, they try to create a thread-like geometry on the steel wire that prevents it from being unscrewed during loading.

Steel wire for reinforcing concrete - and other materials - is known in many embodiments and many variations of the methods for their production have been made. As mentioned above, the steel wire according to the invention is intended to further develop solutions with a threadlike shape, and therefore, the present invention is described in relation to the prior art.

In the context of the present invention as well as in the prior art, the term "thread" is understood to mean not or not exclusively geometrically exact thread. As a result, there is no need to think about the geometric exact screw surface behind the word "screw surface". To denote these circumstances, the term "twisted screw" is used in the literature and throughout this description.

A typical example of known solutions is found in HU PS 158 074. The steel wire of the marked form is bounded on opposite sides by longitudinal sides of the steel wire and these planes are connected by cylindrical surfaces. The steel wire of the sketch design is provided with distorted screw thread on the cylinder surfaces. In the production of such steel wire, the circular cross-sectional wire is passed between rollers which result in planar portions facing each other. The steel wire, which has already been flattened, is then pulled through a drawing tool with a torsion screw thread on its inner, i.e. forming surface. This puller may rotate freely but is supported axially.

In the case of the presently known steel wire, flat surfaces are used to prevent the aforementioned twisting. A disadvantage with this product, however, is the fact that there are edges at the intersection of flat surfaces and cylindrical surfaces, which are known to be voltage collecting points. Cracks occur at these locations, which results in a reduction in the strength of the steel wire.

HU PS 204 452 discloses a solution which overcomes some of the shortcomings of the solution described above. The outstanding steel wire of this form has a cross-sectional contour of three-stranded epitrochoid and accordingly has three rib-like torsion-shaped shapes on the steel wire. In the production of steel wire, the starting wire is pulled to the required circular cross-section, then a three-pronged epitrochoidal cross-section is formed with a stationary pulling tool, and the resulting semi-finished steel wire has a constant pitch, is pulled through a free rotating puller.

This steel wire has no voltage collection edges, but can only provide a limited amount of anchoring.

The aim of the steel wire according to the invention was to at least reduce or at least partially eliminate the faults, shortcomings and disadvantages of the known solutions.

Specifically, it is desired to achieve an anchoring property greater than that of the steel wire of the present invention by significantly reducing the tendency to unscrew without compromising the strength properties.

HU 212 747 Β

The steel wire according to the invention enables this object to be achieved because it has an irregular octagonal shape and an irregular octagonal cross section along its length and has a corresponding distorted screw surface. This surface design prevents twisting. With these features, the cross-sectional polygons are sacral rounded and there are no sharp corners or incisions that could lead to cracks.

For forming the cross-section and thus the surface shape of the steel wire according to the invention, square and regular hexagonal cross-section tools can be used, of course with rounded corners. As a result, with the appropriate choice of dimensions, cross-sectional shapes - irregular octagon and decimal - can be formed where the shortest sides of these cross-sections fall on the sides of a square and the other sides are on the sides of a regular hexagon. An irregular octagonal cross-section has two such short sides opposite to each other, and an irregular octagonal cross-section has four such that are not evenly distributed along the circumference.

The suitable size selection indicated above is that the side length of said square is smaller than the diameter of the circle also passing through the vertices of the hexagon, also referred to. Preferably, this diameter is equal to the diameter of the last circular section of the workpiece steel wire during manufacture. Reference is made to the last round section, because during production, the initial steel wire cross section may be reduced in several steps - by cold drawing - while always leaving the workpiece circular, and once a predetermined diameter is reached, the cross section will begin to change and smooth.

In the manufacture of the steel wire according to the invention, the workpiece is pulled through a square hexagonal and a rounded hexagonal hexagonal drawing tool to produce the desired periodically varying cross-sectional shape at the workpiece. The square cross-sectional puller is a stationary pulling stone, while the regular hexagonal cross-sectional puller is free to rotate but is axially supported. The surface of the pulling cavity of the latter pulling tool is the surface of the torsion screw.

The manufacturing process is not affected by the fact that, after multi-stage cross-sectional reduction in a work process, the workpiece-forming steel wire is passed through the square and then the rotary hexagonal cross-cutting tool, or the said cross-sectional pre-forming is performed separately.

Thus, the essence of the steel wire according to the invention is that it has sections of irregular octagon with rounded corners and irregular octagon with rounded corners.

In the preferred embodiment of the steel wire according to the invention, the shortest sides of the cross-section are on the sides of a square and the other sides are on the sides of a regular hexagon.

In a preferred embodiment of the invention, said steel wire has a side length less than the diameter of a circle having a regular hexagon.

It is advisable to select the dimensions so that the radius of the derivative circle of the regular hexagon is equal to the radius of the last circular cross-section of the steel wire during manufacture.

The steel wire according to the invention will be described in more detail with reference to the examples in the drawings. In the drawings it is

Figure 1 is a cross-sectional view of an exemplary steel wire, while a

Figure 2 shows another cross-section of an exemplary steel wire. THE

Figure 3 is a side view of the main parts of an exemplary apparatus for producing the steel wire of the present invention.

The cross-sections of Figures 1 and 2 in the exemplary embodiment of the invention occur periodically along the length of the steel wire. The actual cross-section is the irregular octagon drawn in bold in Figure 1 and the irregular octagon in Figure 2. In these figures the individual shapes are "cornered", but in reality these corners are rounded.

For the purpose of this example, the cross section of radius R of a starting steel wire is represented by circle 1. This cross section may be reduced in one or more steps to a predetermined smaller cross section represented by a circle of radius r. The steel wire with a circular cross-section 2 will now obtain its final shape by subjecting it to a square 3 and a hexagonal shape 4. Since the hexagon 4 is a cross-section of a tension cavity of a rotating tool, an alternating cross-sectional polygon is formed.

In the exemplary steel wire, the side L of the square 3 is smaller than the diameter of the derivative circle of the hexagon. 2 r is the diameter of the 2 circles corresponding to the last circular cross section of the workpiece steel wire. Formula: L <2r.

It can be seen that in the cross-section shown in Fig. 1, the two shortest sides facing each other lie on one side of the square 3, while the other sides lie on each side of the hexagon. The section of Fig. 2 shows an irregular rectangular cross-section with the four shortest sides lying on each side of the square 3 and the other sides of the cross section lying on one side of the hexagon 4.

To illustrate the manufacture of the steel wire according to the invention, the apparatus outlined in FIG. The steel wire 10 forming the workpiece is pulled off the release drum 5 by means of two exemplary drums 8. These tension drums 8 ensure that the steel wire 10 is pulled through the tensioning tool 6 and the tensioning tool 7. These two stationary circular tensioners are designed to reduce the initial cross-section. As mentioned earlier, these preparatory operations can be performed in a separate workflow.

The puller 9 is a stationary square cross-section resulting in the 3 squares shown in Figures 1 and 2. The next step is performed by the pulling tool 11

HU 212 747 Β zi. This is a cavity with a hexagonal cross-section and a surface with a twisted screw. This pulling tool 11 is pivotally mounted but supported axially, which is also illustrated by the schematic representation. After leaving the drawing tool 11, the finished steel wire is placed on the collecting drum 12.

The pulling tools used in the manufacture of the invention can be made simply, relatively cheaply, and the entire process does not require conventional, special technology. The process does not disintegrate the fabric structure of the steel wire, its fiber texture and secondary fiber remain unchanged, thus providing the steel wire with a good strength property.

The small, narrow surfaces of the steel wire are very effective means of preventing unscrewing, while the other surfaces provide a very good anchorage.

It is also evident from the examples that the steel wire according to the invention has no stress-collecting, crack-causing sharp corners and therefore the strength and load-bearing capacity of the reinforced concrete is not reduced by such reasons.

Claims (4)

PATENT CLAIMS A steel wire, in particular for reinforcing concrete, having a variable cross-section along its length and a torsion screw surface, characterized in that it has sections of irregular octagonal and circular-corner irregular octagonal sections. Steel wire according to Claim 1, characterized in that the shortest sides of the cross-section are on the sides of a square (3) and the other sides are on the sides of a regular hexagon (4). Steel wire according to claim 2, characterized in that the side (L) of the square (3) is smaller than the diameter (2r) of the circle (2) written around the regular hexagon (4). Steel wire according to claim 3, characterized in that the radius (r) of the circle (2) around the regular hexagon (4) is equal to the radius (r) of the last circular cross-section of the steel wire (10) during manufacture.