DE744483C - Process for the production of splittable composite structures - Google Patents

Description

Process for the production of splittable composite structures Reinforced concrete structures, in which the steel inserts are embedded in the concrete without tension, have a relatively low flexural and tensile strength, and also a low elasticity. It is known that these strength properties can be improved by pretensioning the steel inserts. Commercially available round steel bars were prestressed with the permissible tension, the tension being transferred to the concrete after it had hardened. With the help of special anchoring plates at the ends - of round bars were attached, the concrete was held by transferring the biasing forces under constant .Connect voltage. In this way, prestressed concrete bodies were obtained which improved the elastic properties of ordinary reinforced concrete. It has also been proposed to omit the outer anchoring body in the manufacture of prestressed concrete structures and to transfer the prestressing of the steel inserts to the concrete body only through the natural adhesion of the same. In the practical implementation, round steel bars are used and only relatively low pre-stresses have been transferred to the concrete body.

It was later believed that steel inserts of normal strength no permanently effective tensions could be maintained in the steel inserts, because the concrete, which is under constant pressure, will shorten significantly over time by shrinkage and creep, which causes the prestresses given to the steel inserts get lost again. It was pointed out that the foreshortening of the concrete in stress transfer depending on the shrinkage or load conditions up to Reach three, thousandths and even more. would cause a voltage drop in the pre-stressed steel inserts that would be caused by ordinary. Concrete 6ooo kg / cm2. It was therefore suggested for the reinforcement inserts steel high strength, namely- stronger wire rod up to 16 mm in diameter with a tensile strength of about 10,000 kg / cm2. Straight steel rods have been produced by cold stretching these wires, with at the same time the yield strength of the steels was increased. One also has the use of Steel with a higher elastic limit of up to 16,000 kg / cm2 has been proposed, with an alloy Steels, which are not commercially available. The one used to manufacture Stronger wire rods used by prestressed concrete structures must have at the ends Anchoring plates o. The like. Be provided, as the transmission of the high tension force each individual steel insert on the concrete body only with the help of these outer anchoring bodies is possible.

The use of drawn thin steel wires as reinforcement layers for the production of prestressed concrete structures was considered unsuitable, although with the same, among other things with piano wires, model experiments in the laboratory carried out. would have. Experts believed that these thin steel wires adhere poorly and are also too expensive.

Those used for the practical manufacture of prestressed concrete structures Reinforcing rods made of wire rod were pre-tensioned close to the yield point. The prestressing forces were applied to a high-quality by means of external anchoring bodies Concrete *, which has a very low initial strength in relation to the final strength would have. There was already a hardening of the Portland cement made Concrete for sufficient, which is achieved after 11/2 hours of heating with steam from Zoo ° became. When loosening the prestressing means, this young, fresh concrete got too high Compression stressed because the compressive stress that occurred was almost as high as the compressive strength of the concrete. Considerable voltage drops occur here due to the plastic deformation of the concrete in the steel inserts, so that continuous stresses are obtained, which are only between 1/2 and 2/3 of the yield point are. This plastic change in shape also has the Disadvantage that no precise determination of the amount of remaining bias in the Concrete is possible.

In the production of prestressed concrete structures of this type, one behind the other The individual concrete bodies can only be arranged between two adjacent anchoring bodies be separated. A division of beams and 'panels at any point is not possible, as otherwise the pre-tensioning in the steel inserts will be lost.

In the above-mentioned method, the strength or yield strength is of the stronger wire rods used relatively low, and as a result of the loss of tension the amount of the permanently remaining prestress is limited, so that the high compressive strength a high-quality concrete is not exploited.

In addition, this process requires the steel inserts up to pretension to the yield point. You need almost twice the pretensioning forces for this and accordingly also stronger pre-tensioning devices than to achieve the permanent tension are necessary.

It is also a method of making weak concrete planks known whose M'esen consists in the fact that a large number of thin steel wires without Anchoring means are clamped into the surface of the concrete boards in such a way that that they are close to the outer surface, so that the outermost concrete layer with these thin, tightly juxtaposed steel wires is interspersed. The purpose of the laying the weak wires to the surface is increasing the height of the effective Cross-sectional. Around the thin wires close to each other in a plane and with the surface In order to be able to lay the wires evenly, it is necessary to cut the wires at after placing it in the mold and tightening it until the pale hardens To be left in such a way that they are held in the correct position by the concrete.

The invention relates to a method for producing splittable composite structures made of concrete and prestressed steel inserts of high strength, in which the concrete and the steel inserts are constantly under high tension. The invention consists in that tempered steel wires with a diameter of about 0.5 to 2 mm and a tensile strength of about 1, 000 to 30,000 kg / cm 2 are used as inserts; which have no external anchoring means and are pretensioned to about half the yield point, the pretensioning means being released only after the concrete has reached a correspondingly high degree of hardening.

This new process enables composite structures to be produced made of prestressed concrete, which have a material-like quality in that they are on arbitrary places and can be divided into pieces of any size without doing so the inner tensions are lost. The high preload forces. the steel inserts are only on the. Transfer concrete when it is almost completely hardened and has reached a very high compressive strength, so that the wires as a result of the entered Adhesion strength can no longer relax. Because the pretensioning forces only when the concrete has almost completely hardened, i.e. at a very high level Compressive strength these can be transferred noticeably Voltage drops in the steel inserts also due to shrinkage and creep of the concrete no longer enter. The steel inserts therefore only need that tension to be biased, with which one will later want to stress them continuously.

In the case of the thin steel wires used as inserts according to the invention it is a matter of the kind used, for example, in the manufacture of wire ropes and piano strings are used. The high-quality steel wires, their tensile strength depends on the remuneration, are very elastic and have a very high yield point, which is about go% of the tensile strength.

The preload can therefore also be selected to be correspondingly high and is z. B. in the manufacture of structures according to the new process, if one reckons with the usual double security, about 5,000 to 14,000 kg / cm '.

In order to arrive at the new procedure, there were various prejudices to overcome. So it was of the opinion that with thin steel wires the mentioned Kind of the high strength created by tempering is only temporary, and that these thin wires cannot be used for long-term stress because they would lose strength due to fatigue. Incoming attempts but have provided evidence that such a fatigue strength in these highly tempered Steel wires is still present, and that with the prestresses according to the invention permanent strains that can cause a significant drop in tension, does not occur even after a long time. The invention is therefore based on the knowledge that tempered steel wires of a certain quality can withstand high continuous tension can and therefore for the production of preferred, reinforced, highly prestressed composite structures are suitable.

The invention is still based on the knowledge that in contrast a special anchorage to the steel rods for thin, highly pre-stressed steel wires is not necessary. That high-tension, thin wires in the concrete have no anchoring need, was not foreseen for the expert, since one is with strongly pre-tensioned Reinforcing bars provide a special anchorage. always needed.

So it was to be expected that the thin, drawn wires after loosening the prestressing means would slip into the concrete, and that consequently because of the supposed low adhesive strength of the thin wires a transfer of the high wire tension on the concrete is not possible. Incoming attempts would have however shown that contrary to this assumption in the new process without any special Anchoring means achieved a great adhesive strength of the steel inserts in the concrete which alone is sufficient for the transmission of a high prestress on the concrete and the maintenance of this preload is guaranteed. The great adhesion of the thin wires is achieved in that the pretensioning means are only then released if the concrete has a very high degree of hardening, that of the selected prestressing must correspond, has reached, so is almost completely hardened. The high tension of the wires causes a reduction in the cross section, so that when loosening the - pretensioning means a cross-sectional enlargement occurs mainly at the ends of the steel wires and this creates a considerable pressure on the soffit, which in turn creates a Significant enlargement of the natural occurring between concrete and steel inserts Adhesion resistance has the consequence. It must be taken into account that when using a few steel rods transmit a very large tensile force with each individual rod which is large in relation to the rod surface. Will. but in the sense the invention of the rod cross-section divided into many small wire cross-sections, the surface available for power transmission thus becomes essential enlarged. It should be noted that the tensile force is the square of the wire diameter decreases, the frictional forces on the other hand only linear. If now with machined steel bars If the frictional force is smaller than the tensile force to be transmitted, then with decreasing Diameter the ratio of these two forces always more favorable, until finally with a certain wire diameter (approx. 5 mm) both forces are equal, So the reinforcement no longer slides in the concrete. In case of underruns With this wire diameter, the frictional forces are significantly greater than the tensile force, so that with the diameters on which the invention is based, with certainty Slipping of the wires in the concrete is prevented.

So there is high tension on the concrete through internal, along the Steel wires evenly acting frictional forces. transferred iin. Contrary to that known prestressed concrete; which its compressive stress with the help of special ones on the steel rods fastened anchoring body is given that with external individual forces at the ends of the concrete piece in question act on this. The transmission of tensions on the concrete is thus effected indirectly by the anchoring body, while in the case of the composite structures produced using the new process, the stresses directly from the Steel wires are transferred. This direct has various major advantages. By omitting external anchoring means the production of composite structures is simplified; - you can theoretically unlimited lengths, e.g. B. ioo m length, manufactured and, with regard to the achieved great adhesive strength of the steel wires in concrete, at any point and in any position large sections -be divided without the pretension and thus the strength and elasticity of these sections is lost. Those produced by the new process Composite structures behave insofar, d. H. with regard to this divisibility, similar to a material.

Since the composite structures produced by the new process from numerous thin, highly pre-tensioned steel wires interspersed with great tensile strength there will be an even distribution of the steel inserts on the concrete exerted forces achieved and thus the plastic deformation of the concrete during the Voltage transmission reduced to a minimum value. The one through the plastic Deformation (shrinkage, creep) occurring stress losses are therefore extreme low, mainly because the tension of the steel wires on a concrete with a high degree of hardening, d. H. transferred to an almost completely hardened concrete will. These low voltage losses enable the scheduled initiation of a certain preload, with the calculated and actually occurring stress almost to match. Furthermore, since the steel wires used according to the invention are a very have a low elongation at break of only 2 to 5 ° 1a, this is how the composite structures behave according to the invention elastic almost to breakage.

The new method also enables the greatest possible utilization the strength of both the steel inserts and the concrete. In particular, can the very high compressive strengths of concrete that can now be achieved thanks to high prestressing be fully exploited. The inventive use of the thin high-quality Steel wires result in a considerable saving in steel inserts.

The possibility of using the manufactured according to the new process Composite structure is very versatile.

Claims (1)

PATENT CLAIM: Method for. Manufacture of splittable composite structures from concrete and prestressed steel inserts of high strength, in which the concrete and the steel inserts are constantly under high tension, characterized in that the inserts are tempered steel wires with a diameter of about 0.5 to 2 mm and a tensile strength of about 12,000 until. 30,000 kg / cm2 are used that have no external anchoring means and are pretensioned up to half of the yield point, the pretensioning means being released only after the concrete has reached a correspondingly high degree of hardening. To distinguish the subject matter of the application from the state of the art, the following publications have been considered in the granting procedure: German patents ..... Nos. 53 548, 384 009, 575 973, 581572, 6i8 328, 62-.746, 639 o25; Austrian patent specification. . N-.134 523; French 781206 and additional patent specification No. 36 703; U.S. Patent. . . . . . . . . . No 2,035,977; Beton und Eisen, 1937, issue 1o, p. 161 and ff .; Zement, 1936, pp. 508 ff. Material Handbook; Stahl und Eisen, November 1937, D 11 / 1o; The building advisor by Junk-Herzke, Verlag Springer, Vienna, 1931, p. 4o6; Altgeber, The production of the fluids iron and steel wires, 1926, pp. 81, 82, 104, 105, 114, 115; Hoyer, Der Stahlsaitenbeton, 1939, Verlag Elsner, Berlin, p.79; Brochure from the Wettstein brothers, Prague; Brochure from Gentrup and Petri, Halle a. P. 1929; Brochure from E. Züblin & Co., Strasbourg, about "Sigwart pipes", p.3; Congress of the international association for bridge construction and building construction, 1936, Verlag Ernst & Sohn, Berlin, Referat IIb $, pp. 2o5 to 231; Science et Industrie, 1933, issue i, January 1933, pp. 10, 13, 4; Freyffinet, Une Revolution dans les Techniques du B6ton, 1939, pp. 98 to 100.