HU217903B - Cold-rolled reinforcing steel and process for its manufacture - Google Patents

Abstract

In a reinforcing steel that has indentations (4) rolled into a steel rod of approximately circular cross section, the indentations are formed as the reinforcing steel is unwound through circular arcs of different radii set axially symmetrical relative to the indentation. The indentations are rolled into the surface of the rod at a constant depth and have steep flanks. This ensures sufficient bonding despite a lower deformation effort, providing for better ductility parameters. Furthermore, the coiled reinforcing steel has better directivity and improved suitability for welding in the manufacture of welded wire mesh. A process for manufacturing such a reinforcing steel comprises at least two deformation steps.

Description

BACKGROUND OF THE INVENTION The present invention relates to a cold-rolled reinforcing steel having recesses rolled in a circular cross-sectional steel bar which is uniformly distributed in 2-6, preferably 3 longitudinal rows around the circumference of the rod and wherein the boundaries of the recesses are formed by circular arcs are axially symmetrical.

The invention further relates to a method for producing cold-rolled reinforcing steel, wherein the rolled wire is rolled to carbon steel with at least one first cold-forming step having a cross-sectional reduction of 8-20% and in a last cold-forming step bordered by steep sidewalls. Roll flat recesses in 3 longitudinal rows evenly distributed.

Reinforcing steel (prestressed steel) has ribs for reinforcing concrete bodies to ensure proper bonding between steel and concrete. This ensures that the transmission of force between steel and concrete and vice versa ensures that short anchoring or transmission lengths can be achieved in use.

During the development, a number of conditions for the production of reinforcing steels, in particular cold-formed reinforcing steels, such as reinforcing steel mesh or coiled reinforcing steels, have changed. These include, for example, new knowledge in reinforced concrete architecture in the field of non-linear design methods. So far, the bonding of reinforcing steels has only been investigated in the elastic section of the stress-strain diagram of steel. The use of non-linear dimensioning also included the bonding effect over the non-elastic section of the steel as described in DE-A1 -4 011486. It has been shown that an overly "hard" joint formed by ribs in the concrete makes the steel only slightly elongated. Therefore, a joint had to be created which, in use, conforms to the previous building regulations, but is softer on the elastic stretch of the stress-strain curve of the reinforcing steel.

Most of the reinforcing steel is produced by hot or cold forming. The rolled reinforcing steel is then used in the form of rod steel or reinforcing steel mesh. In order to use steel as a reinforcement in concrete, it must be leveled with suitable machines. The cross-section of the ribbed steels is usually different from the round shape. In addition, the ribs are regularly heavily worn during the straightening process. Straightening of reinforcing steel with ribs on their surface causes considerable noise. For this reason, it has been sought to reduce the leveling properties of the rolled concrete and thus the noise generated during the leveling process.

A significant part of the weight of the reinforcing steel is contained in the ribs of the reinforcing steel. The formation of the ribs requires about 25% shaping, which in itself requires high energy expenditure and consequently high energy consumption. Therefore, in order to save energy, it has become necessary to develop a process that reduces the energy used to create the ribs.

The aforementioned high forming requirement (25%) significantly reduces the initial values of the deformability parameters in the cold forming process, such as the ratio of elongation at maximum load and tensile strength to yield strength. The desired ratings (see ENV 10080) are therefore difficult to obtain.

Wire mesh are welded in such equipment. operating at up to 120 beats per minute. Constant welding conditions can only be guaranteed if deviations from the circular cross-section of ribbed reinforcing bars are minimized as much as possible. This is especially true when welding double irons. In view of this requirement, bars with a surface as close as possible to a smooth circular steel should be sought.

Based on the above, the following objectives are given for the surface finish of concrete steels.

For production:

low molding effort, material preferred for cold forming and less power consumption and roll wear in surface design.

For further processing:

good leveling properties with low noise generation, improved welding properties. Prevent damage to the surface of the reinforcing steel and reduce wear on the leveling tool.

For use as concrete reinforcement:

providing satisfactory bonding in service condition and enabling activable steel stretching in concrete (plastic joint), high values of elongation at maximum load and high tensile strength / yield point ratio, low stress concentration and hence high, sustained vibration strength.

Experiments have proven that these objectives are best served by a reinforcing steel which is designated as the subject of the invention.

Such a reinforcing steel is described in DE-AS 10 84 464. This document describes a reinforcing wire or rod, in particular for prestressed concrete, whose surface has regularly reciprocally recessed recesses where the recesses are elliptically formed and extend almost half of the surface of the bar. The recesses are separated by narrow bumps in the direction of their minor axis which are inclined relative to the axis of the rod. These bumps are produced in the same way as slanting ribs by means of milled grooves in the roll, into which the material is pressed during rolling.

GB-PS 1 334 757 discloses a reinforcing steel corresponding to the cold-rolled reinforcing steel designated as the subject of the invention and having recesses formed elliptically, where the major axes of the ellipses may be inclined at an angle of 30 to 70 °. In order to improve the bending properties of the bars, the sides of the recesses are symmetrically formed and the side angles are limited to 50 °.

FR-A-1 207 928 discloses a reinforcing steel which, when making reinforcing steel mesh,

In order to improve weldability, the surface of the reinforcing steel was intended to be a smooth surface. Concrete bars of circular cross-section are rolled into two or more rows of flat recesses of small, constant depth in the form of a rectangle or parallelogram.

FR-A1 202 576 discloses a process for producing a ribbed reinforcing steel in which a round cylindrical wire is cold-drawn and reduced to approximately 20% by cross-sectional steel. The circular steel is then rolled into a cross-section with rounded corners and rolled into the rounded corners to form ribs. The cold forming of the ribs is of the order of 20%.

It is an object of the present invention to provide a surface of a reinforcing steel as described in the subject matter of the invention so that, despite low molding effort, sufficient bonding properties can be achieved which allow for better deformability parameters (elongation at maximum load and tensile strength / yield strength). In the case of plastic reinforcement of the reinforcing steel (non-linear dimensioning), it is necessary to allow for a soft bonding, which allows the greatest relative displacement between the steel and the concrete. At the same time, in order to achieve good leveling properties and improved weldability, the surface of the reinforcing steel should preferably be similar to that of a smooth surface. Due to the high sustained vibrational strength, the voltage concentration should be kept as low as possible. It is a further object of the present invention to provide a method by which the described reinforcing steel can be formed according to the requirements.

SUMMARY OF THE INVENTION The object of the present invention is a cold-rolled reinforcing steel having recesses rolled into a steel rod of circular cross-section which is uniformly distributed in longitudinal rows of 2-6, preferably 3 longitudinal rows, wherein the boundaries of the recesses are formed they are symmetrically arranged in relation to the axes of the recess, wherein flat recesses are rolled into the steel bar and these recesses are bounded by a steep sidewall which defines an angle β of 60-80 ° with the tangent of the steel bar is determined by a reduction in cross-section of up to 7% when rolled into a steel rod.

Another object of the present invention is to provide a method for producing cold-rolled reinforcing steel, wherein the rolled wire is rolled to a stainless steel with at least one first cold forming step with a 8-20% cross-sectional reduction and a final cold forming step bounded by steep sidewalls. flat rolled recesses, preferably in 3 longitudinal rows, are rolled and the rollings are rolled with a 2-7% cross-sectional reduction, and the boundary lines of each recess are formed by circular arcs of different radii symmetrically arranged on the expanded circumference of the reinforcing steel.

While the known reinforcing steel according to DE-AS 10 84 464, which is made especially for prestressed concrete, it was desired to achieve uniformly high tensile strength and high adhesive strength - this was achieved by strong cold forming of a cold drawn smooth round wire and forming bumps according to the invention. In the case of the roll, the forming is small by rolling the recesses, whereby the deformability parameters can be kept at a favorable value. Apart from the rolled recesses, the surface of the round bar remains smooth, that is to say, no bulge formation occurs, on the one hand to improve straightening ability and on the other hand to allow "soft bonding" when reinforcing steel is installed.

By means of recesses formed at different depths, as well as protrusions or recesses formed on the bottom surface of the recesses, a stepped embodiment can be formed. Before the concrete bracket is sheared at a larger recess, it is sheared at a smaller recess, thus leaving a path of extension free. A similar effect occurs when a recess or groove is formed at the bottom of a recess. This mechanism allows greater relative displacements between steel and concrete. The reinforcing steel according to the invention is therefore particularly suitable for use as reinforcing elements in reinforced concrete building blocks, which are dimensioned by utilizing local plastic deformation of reinforcement.

Because the boundary lines of the recesses are made of circular arcs, and there are no straight cuts where the tension stresses can be concentrated, the sidewalls of the recesses are rounded to the bottom surface, and when reinforcing steel is used, the tension stresses that result in long lasting shear strength.

The shape of a recess, similar to an ellipse, for example, when compared to a circular recess, results in an increase in the proportion of the smooth circumference of the goose, thereby improving the leveling property and weldability. In addition, to ensure a good leveling property, the recesses in the adjacent longitudinal rows must be offset relative to one another in the longitudinal direction of the rod.

Given the target and desirable formability parameters, not only keep advisable recesses behengerlésénél the cross-sectional reduction of low, but also the preferred multi-step process used in the manufacture of rolled reinforcing steel, as ^this gy wire rod of the first cold forming step 8 - round bar of 15% cross-sectional reduction is rolled , and in a further cold forming step, the wells are rolled by reducing the cross-section by 2-7%. However, instead of the first forming step, two or three cold forming steps may be employed with a corresponding small cross-sectional reduction, whereby a round cross section is formed on the rod before the recesses are rolled.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the drawings. The attached drawings show

HU 217 903 Β

Fig. 1 is an expanded shell of a reinforcing steel of the invention with three elliptical recesses arranged in three longitudinal rows;

Figure 2 is an enlarged sectional view of the plane II-II in Figure 1, a

Fig. 3 is an elliptical longitudinal row of recesses arranged obliquely on the axis of the reinforcing steel as shown in Fig. 1,

Figure 4 is a diagram of the bonding properties of a reinforcing steel according to the invention compared to a known cold-ribbed reinforcing steel,

Figure 5 is a cross-sectional view of another embodiment of Figure 2;

and a

Figures 6 and 7 are corresponding views of an additional reinforcing steel according to Figures 2 and 3, respectively.

The expanded section of the reinforcing steel shown in Figure 1 has recesses 4 arranged in three longitudinal rows. The longitudinal rows are evenly distributed over the circumference of the reinforcing steel. The recesses of adjacent longitudinal rows are offset in the longitudinal direction of the rod. The offset rate corresponds to one third of the distance between two adjacent recesses of a longitudinal row in three longitudinal rows. Apart from the recesses 4, the surface of the reinforcing bar 5 is smooth, i.e. it corresponds to a smooth cylindrical bar.

The boundary line of the depressions in the expanded steel reinforced concrete shown in Fig. 1 are formed by circular arcs 6 and 7, which have different radii and are arranged symmetrically about the depressions 4. The circular arcs 6 having a smaller radius are symmetrical about the axis of symmetry 8 and the circular arcs 7 having a greater radius are arranged symmetrically about the axis of symmetry 9. The axis of symmetry 9 of the larger radius 7 has an angle of 90 ° with the axis of the bar, i.e. perpendicular to the axis of the bar, and the axis of symmetry 8 is parallel to the axis of the bar. The size and spacing of the recesses 4 according to the exemplary embodiment illustrated in the first example is as follows:

D «0.75 d,

B «0,72 d, s« 0,25 d _s b «0,80 d _s t« 0,06 · d _s , where d _{s is} the nominal diameter of the bar,

D is the extent of the recess towards the perimeter of the rod, a

B is the dimension of the recess in the longitudinal direction of the rod, measured in the center of the transverse dimension D, the distance between the adjacent recesses of the adjacent recesses in the longitudinal direction of the bar, measured in the center of the longitudinal rows depth.

At the given dimensions, the total surface of the recesses is about 40% of the total surface of the bar.

Figure 2 illustrates a cross-section of a recess in the longitudinal direction of the bar. It follows that the recess is flat, rolled to the surface 5 of the bar at a constant depth t and is bounded by a steep side wall 10. The side wall 10 passes into the bottom surface 12 with a small radius 11 of rounding.

The oval shape of the recesses transverse to the rod axis, despite the flat design of the recesses, provides sufficient coupling effect. For sizing, where the local plastic deformation of the reinforcement, i.e. a hinged rotation, is utilized, the reinforcing surface of the reinforcing steel according to the invention is more advantageous than the rods with ribs or protrusions on their surface, since the surface design of the invention provides a "softer" connection.

Figure 3 illustrates a further embodiment of the reinforcing steel according to the invention. In this case, the oval recesses are arranged obliquely relative to the axis of the rod. The angle enclosed by the axis is indicated by α and can be between 60 ° and 90 °. The embodiment of α = 90 ° corresponds to the solution illustrated in Figure 1.

Given the recesses are the size given above

and spacing, it should be noted that the B dimension of the recess, measured in the longitudinal direction of the rod at the center of the D dimension, means that the distance B is measured at the center line of the corresponding longitudinal row of the recesses. The same applies to parameter s, that is, the distance between the boundary lines of adjacent recesses, measured in the longitudinal row of the rod.

The process for producing the reinforcing steel described in the present invention differs from the known processes by first rolling a round wire into a cold-rolled steel by a cold forming process and then rolling the flat recesses into a further cold forming process. The first cold forming process, which can be carried out in two or three steps, is primarily intended to increase the strength of the reinforcing steel. Depending on the starting material

- these may be 380-420 BSTM rolls of wire - 10-20% cross sectional shape is required, which can be split into two or three step cold runs. In the case of a three-step cold-forming, this allows for a precisely round cross-section of the desired size. If the round steel is formed in several cold forming steps, the cross-sectional reduction in the first step may be greater than in the subsequent steps required for producing the steel.

By first reducing the cross-sectional area of the circular wire uniformly by a cold forming process, the stress peaks can be avoided in this process. In the final process step, when the flat recesses are rolled, the cross-sectional reduction is limited to 7%, preferably 5%, whereby, due to the rolling of the flat recesses only, the steel is used relatively uniformly in this cold forming process. The overall forming, including the rolling of the recesses, is thus smooth and smooth in two or three steps, thereby providing excellent forming parameters with respect to the surface geometry of the reinforcing steel. This circumstance is related to the softer bonding achieved by the surface geometry of the reinforcing steel.

EN 217 903 Β pen, with the advantage of local plastic deformation of the reinforcement (articulated rotation).

The reinforcing steel or concrete wire according to the invention is used primarily for the production of reinforcing steel mesh. In this case, a minimum yield point of 500 N / mm ² is required. Rolling wires with a yield point in the range of 380-420 N / mm ² are particularly suitable as starting materials for the production of reinforcing steel and have the following analytical values:

carbon: 0.04-0.14% manganese: 0.35-0.70% silicon: 0.20-0.30%

A specific embodiment will now be described.

In the first step of the process of the invention, a round wire having a diameter of 8.0 mm is rolled with a round wire having a diameter of 7.5 mm. The cross-sectional reduction is 11%.

The material of the starting wire used in the example is as follows:

nominal diameter: 8.0 mm ovality: 7.85-8.17 mm tensile strength: 421 N / mm ² elongation at break (A 10): 34% chemical composition: C: 0.07; Mn: 0.61; Si: 0.20;

P: 0.016; Si: 0.037; Cu: 0.26;

Cr: 0.11; Ni: 0.14; Mo: 0.02;

N: 0.009.

In a second process step, three recesses of a depth of 0.6 mm are rolled into the round wire in a second process step parallel to the longitudinal axis of the wire. The angle with the longitudinal axis is 60 °. The wire is not mechanically de-stressed. The following strength values are obtained:

yield strength: 508-536 N / mm ² tensile strength. melting range 07-110 at maximum load: 4.7-7.1%.

The ranges for the values given above were the result of several experiments.

To test the bonding properties of the reinforcing steel according to the invention so prepared, extraction experiments were performed on concrete bodies with under and overhead test bars in accordance with the specified bonding sections. In addition, experiments have been carried out on a wire with ribs known in the art having cold-formed ribs which had oblique ribs in three longitudinal rows. The experimental parameters are as follows: Position of the bars: Bottom and uppermost concrete direction across the bar axis Concrete cover: 1.75 · Bar diameter concrete quality: B 25

The diagrams in Fig. 4 show the results of the wires according to the invention, where I _{u is} the lower wire and I _o the upper wire. The reference wire is designated II _u and II ₀ respectively. The length of the pull-out path, denoted by s at the stress-free rod end, was applied to the abscissa and the bonding stress to the ordinate.

Comparison of the curves shows that in the case of a small relative offset (ε <0.1 mm), ie in the operating state, the generated bonding voltage is within the normal spreading range. However, at maximum load, the maximum offset is 0.2 and 0.35 mm for the ribbed wire and 0.33 and 0.9 mm for the wire according to the invention.

Thus, the reinforcing steel of the present invention has a similar bond in service condition, but allows for a much greater displacement.

Further improvement of the "soft" joint can be achieved by using an additional measure which can be implemented in a "stepped" embodiment. Such measures are illustrated in Figures 5, 6 and 7, respectively.

In the reinforcing steel of Fig. 5, where the depiction corresponds to that of Fig. 3, that is, the figure shows a longitudinal section through the center of the rod with depressions, the depressions are formed at different depths t1 and t2, respectively. Under load, the concrete bracket is first sheared at a lower depth of section ti before being sheared at a greater depth of section t2. This results in a higher elongation value and thus makes the bond "softer".

A "step effect" can also be achieved if the recesses 4 have different transverse dimensions D, which is the distance (see Figure 3) between the tangents of the recesses 4 perpendicular to the longitudinal axis of the rod.

Furthermore, the same effect can be achieved if - as in this

2 and 3 illustrate Figures 6 and 7 - at least some of the recesses have protrusions 13. The bottom of the recesses can be formed with grooves instead of protrusions.

Claims (15)

Cold-rolled reinforcing steel having recesses rolled into a steel rod of circular cross-section which are uniformly distributed in 2-6, preferably 3 longitudinal rows around the circumference of the rod and wherein the boundaries of the recesses are formed by circular arcs of different radii are symmetrically arranged, characterized in that flat recesses (4) are rolled into the steel rod and these recesses (4) are bounded by a steep sidewall (10) which defines a lateral wall (10) with a tangent to the steel rod it forms an angle (β) of 60-80 ° and the depth of the recesses (4) is determined by a reduction in the cross-section of up to 7% when rolled into a circular steel bar. Concrete steel according to claim 1, characterized in that the boundary line of a recess (4) is two It consists of a radius (7) of radius opposite the scarf (7) and two radii (6) of opposite radius connecting them. The reinforcing steel according to claim 2, characterized in that the axis of symmetry of the larger radius circles (7) forms an angle of 60 to 90 ° with the axis of the rod. 4. A reinforcing steel according to any one of claims 1 to 3, characterized in that the recesses (4) are formed in three longitudinal rows. 5. A reinforcing steel according to any one of claims 1 to 5, characterized in that the adjacent longitudinal rows are offset relative to one another in the longitudinal direction of the rod. 6. A reinforcing steel according to any one of claims 1 to 3, characterized in that the total surface of the recesses (4) on the expanded circumference of the reinforcing steel is 20-50% of the total surface of the rod. 7. A reinforcing steel according to any one of claims 1 to 3, characterized in that the recesses have different depths (D 1) of different depths (ti, t 2) and / or tangential to the longitudinal axis of the recesses, measured perpendicular to the longitudinal axis of the rod. 8. A reinforcing steel according to any one of claims 1 to 3, characterized in that the recesses (4) are provided with protrusions (13) and / or recesses on their bottom surface. 9. A reinforcing steel according to any one of claims 1 to 5, characterized in that on a rod with recesses arranged in longitudinal rows 2-6, the recesses have a size and a distance b = (0.15-0.45) - d _s D = (1,12-1,42) -d _s , n = 2 cases, (0,6-0,90) d _s , n = 3 cases, (0,3-0,65) -d _s , n = 4 cases, (0.1-0, 35) · d _s , n = 6 cases, B = (0.30-0.85) d _s , s = (0, 11, 5) d _s , t = (0.025-0.08) d _s , where d _{s is} the nominal diameter of the rod D is the extent of the recess in the direction of the circumference of the rod between tangents parallel to the longitudinal axis of the recesses, perpendicular to the longitudinal axis of the rod B is the length of the recess, measured in the longitudinal direction of the bar, measured in the center of the transverse dimension D, and the distance between 10. The reinforcing steel of claim 9, wherein for n = 3, the size and distance of the recesses D «0.75-d _s B «0.72 {ζ s« 0.25 d _s b «0.80 -d _s t« 0, 06 d _s 11. A reinforcing steel according to any one of claims 1 to 3, characterized in that the recesses are sized and spaced so that the relative rib surface of the reinforcing steel is between 0.02 and 0.07. 12. The reinforcing steel according to claim 11, characterized in that the reference rib surface is between 0.02 and 0.045. 13. The process is cold-rolled, in particular as described in claims 1-12. For the manufacture of a reinforcing steel according to any one of claims 1 to 4, wherein the rolled wire is rolled to a stainless steel by at least one first cold forming step with 8-20% cross-sectional reduction and a final cold forming step flattened by flat, steep sidewalls. rolling flat recesses, characterized in that the recesses (4) are rolled in a reduction of 2 to 7%, and the boundary lines of each recess are formed by circular arcs of different radii arranged symmetrically on the expanded circumference of the reinforcing steel. 14. The method of claim 13, wherein two or three cold forming steps are used in place of the first cold forming step, in which a round steel is rolled with a maximum reduction of 20% in cross section of the wire. 15. The process according to claim 13 or 14, characterized in that, in addition to the usual alloys and impurities and iron content, the carbon content of the wire rod is 0.04-014, the manganese content is 0.35-0.70 and the silicon content is 0.20-0, Set to 30.