NO156015B - Reinforcing steel with high mechanical strength. - Google Patents

Description

This invention relates to a reinforcing steel or a reinforcing bar steel with high mechanical strength which is weldable up to a specific carbon content, is resistant to atmospheric corrosion and optimally satisfies the requirements of the modern building industry. This steel is particularly advantageous in the construction of concrete elements with complicated properties that must show good characteristics in terms of load-bearing capacity, and which can be used at relatively high temperatures, and for the production of structures using these concrete elements.

Concrete is one of the most used building materials, which exhibits a high compressive strength, but a low tensile strength. This disadvantage of concrete has been overcome by introducing in the stress zones of the concrete elements steel rods or steel reinforcements which take up tensile stresses and relieve the concrete from such stresses. These steel reinforcements are called rebars. The reinforcing bars can be divided into two groups depending on the method

on which they are introduced, or the stresses for which they are ufcsted. At the same time, the method of application determines the requirements placed on these types of steel.

In one application, the reinforcing bars have the task of absorbing or eliminating - in the concrete construction - the tensile

and shear stresses to which the structure is exposed. These rebars are hot-rolled; most often it concerns reinforcing bars that are not alloyed or that are only lightly alloyed and equipped with ribs and of a quality that may or may not be welded.

Hot-rolled reinforcing bars should have a guaranteed apparent yield strength, a suitable ductility, the ribs increase the bond strength necessary for the transmission of forces and, if necessary, they should be able to be welded.

In the second method of application, the construction's tensile stresses of the reinforcing bars are eliminated through a prestressing of the concrete elements. This method of use makes it possible to reduce the construction's weight considerably. In this case, the reinforcing bars or reinforcing bars are stretched with a tensile force corresponding to the elastic limit, they are prestressed and laid down in the concrete in this state.

The concrete element is thereby prestressed under pressure by the reinforcing steel buried in it after the concrete has hardened; the prestress corresponds to the stress used during the prestressing of the steel. Thus, the stress resulting from the structural stresses exerted in the concrete element is reduced to a minimum value acceptable for concrete. The prestressed reinforcing steel should thereby act as a tension spring, which determines the requirements for such steel.

The requirements for prestressed reinforcing bars are different from those for hot-rolled reinforcing steel, because their respective functions are not the same. Their apparent yield strength should amount to at least 80% of their tensile strength;

furthermore, the elasticity should exhibit minimal bending, an appropriate relaxation and a negligible susceptibility to corrosion under stress.

The high tensile strength of reinforcing steel is also an essential industrial requirement. The higher the tensile strength of the steel, the greater is generally its permissible useful load.

This increases the value of the use of prestressed reinforcing bars, and

the loss in tensile strength which is inevitable due to shrinkage and slow deformation of the concrete, thereby loses its significance.

In principle, for this reason, it would be possible to use in concrete as a reinforcing bar a type of steel in which the change in length resulting from loads is small, but in which the range of variations in shape is sufficiently wide.

Non-prestressed reinforcing steel to be used in concrete should exhibit a plasticity which means that cracking of the concrete as a result of bending stresses in the construction can be tolerated, but which, however, prevents the reinforcing steel from being subjected to corrosion from the environment due to this cracking.

Reinforcing steel suitable for prestressing should also exhibit favorable rheological properties as well as a good resistance to corrosion under load.

Reinforcing steel which can be used with or without prestressing and which exhibits good mechanical strength properties is known. The chemical composition of reinforcing steel types not used for prestressing is characterized by the fact that the carbon content is most often a maximum of 0.60% by weight, and the manganese content is between 0.50 1.6% by weight. Some steel types also contain 0.2-0.6% by weight of silicon and 0.3% by weight of niobium or vanadium. The steel types that are used in hot-rolled form and which are unsuitable for prestressing are usually weldable up to a carbon content of a maximum of 0.2%. Their tensile strength is usually between 350 and 600 N/mm<2>, and they can be used in 40 to 60% of constructions. The tensile strength of the non-weldable area is between 600 and 800 N/mm<2>, but only 30 to 40% can be used to transfer a bend that does not necessitate a permanent change in shape.

Reinforcing steel used for prestressing is produced by methods for hot or cold deformation and treatment, which are expensive and complicated, or by a combination of these methods. Their chemical composition can be characterized in that their carbon content is usually between 0.50 and 0.80% by weight, and their silicon content is between 1.00 and 2.00%, manganese 0.70-

1.20%, as well as some other elements, and even 0.50-1.50% chromium and 0.30-0.80% molybdenum. Characteristic of their mechanical properties is a tensile strength between 1300 and 1850 N/mm<2> and a stress that requires a deformation of 0.05% which is between 800 and 1200 N/mm<2>. Relaxation of these steel types shows a load of 70% of the tensile strength and good relaxation.

Known and used reinforcing steel types exhibit relatively

weak strength. They can only be welded within very narrow limits of strength, and they can be manufactured by complicated technical processes that require a lot of work to achieve the suspension effect necessary for modern use and construction.

The purpose of the invention is the production of a reinforcing steel with high mechanical strength even in the hot-rolled state and which can be welded up to a specific carbon content, and which after a simple water treatment can be used as prestressed reinforcing steel with a higher carbon content than was previously possible, which exhibits an excellent relaxation and a corrosion resistance under load and which is suitable for use in the production of concrete elements or embedding structures, which optimally meet the construction requirements and can also be used at high temperatures.

The invention thus relates to a reinforcing steel with high mechanical toughness, weldable up to a certain carbon content and resistant to atmospheric corrosion, characterized in that, in addition to iron and the usual residual elements, it mainly consists of, by weight% According to a preferred embodiment, the reinforcing steel consists of

Some of the alloying elements form, in proportions according to the invention, complex metal compounds which partly, even in the casting stage, form active nuclei which prestress the iron by partly entering into interstitial solution, and which in this way multiply the lattice defects.

Other alloying elements form metallic precipitates that exhibit a high shear strength, which in a binding manner increases and stabilizes the internal tension of the basic grid.

Other alloying elements are enriched by taking up the lattice defects at the grain boundaries, so that the non-cohesive precipitation phenomenon is delayed. In this way, the enrichment of such precipitates along the grain boundaries is prevented, the homogeneity of their distribution is ensured and the grain boundary strength is increased.

As the number of crystal seeds with the correct sizes is increased, the crystallization ability of the steel is improved, and the solidification time and size of the primary grains is reduced. In this way, the grain boundary surface in the base mass is greatly increased so that the possibility of enrichment formation is noticeably reduced, and the specific stress resulting from the stress is also lowered significantly.

The properties of the constituents and their appropriate proportions in the alloy system according to the invention form such physico-chemical, kinetic and chemical-acting conditions that - during dissolution, solidification, recrystallization and hot deformation - the availability of constituents to enter interstitially into solution,

the amount of these components and the number and degree of tension in the prestressed grids are in this way considerably increased. Thanks to the increase in the number of lattices exhibiting interstitial bias and their degree of stress, there is a noticeable increase in the number of metallurgically formed dislocations that promote and control the formation of metal precipitates and the density of their distribution, resulting in the enhancement of the effectiveness of the anchoring function of the precipitates during the frontal movement of the displacements caused by the loads.

Thanks to the elements contained in and enriched in the grain boundary defects, the rate of diffusion or the number of nearby metal atoms is reduced, thereby also reducing the formation of incoherent nuclei. This avoids the formation of a non-homogeneous zone along the grain boundaries by alloying elements or precipitates, and that their mechanical strength or yield strength is reduced. Thereby, a burst that previously occurred at the grain boundaries as a result of the loads is delayed, and their elongation and shrinkage during straining is increased.

Because of this phenomenon, the plasticity, the ability to hot and cold deformation and useful strength of the reinforcing steel are increased considerably.

The elements according to the present invention and the parts thereof make it possible to automatically provide a remarkable metallurgical quality to the reinforcing steel during processing. In the area of welding, the mechanical strength and durability limit of the steel are increased several times without cold treatment or deformation, but with an effective combination of the consolidation mechanism. In the non-weldable area, it is possible in a simple way and at low costs to achieve considerably higher mechanical strength and more favorable rheological properties than for known reinforcing steels.

The reinforcing steel according to the present invention also contains in its chemical composition alloying compounds which - if necessary - are concentrated at the surface of the steel during the hot deformation process, and which over time form a protective layer as a result of atmospheric impact on this surface. This layer protects the steel against air corrosion and clearly reduces the corrosion rate compared to known non-alloyed reinforcing steels.

The reinforcing steel according to the invention can easily be welded up to a certain carbon content, and its properties in the zone affected by heat during welding are like the properties of the starting product.

The reinforcing steel according to the invention can be produced and processed with the same equipment as known reinforcing steel, which means that it does not require new facilities and investments to be produced in large quantities. It exhibits remarkable mechanical properties and guarantees, if necessary, resistance to air corrosion, and it extends the area in which assembly by means of welding can be used.

As regards the transmission of forces, a reinforcing steel cross-section is required which is clearly smaller, and thus the weight of the concrete structure can be significantly reduced while maintaining the prescribed concrete layer.

The manufacturing costs for products made from the steel according to the invention do not exceed the prevailing average level due to the improved mechanical strength.

The industrial results achieved thanks to the technical advantages of the reinforcing steel according to the invention, such as reduction in weight, energy saving and low maintenance costs, etc., are not burdened by high costs which are necessary to produce and use the new material.

The reinforcing steel according to the invention and its mechanical properties are further illustrated by the following examples.

EXAMPLE 1

Tre.charger of a steel according to the invention was produced. Chargers designated 1 and 2 which belonged to the weldable range, were manufactured in a 70-ton arc furnace and were cast in 3.5-ton square block molds. The resulting cast ingots were then rolled under normal conditions into square ingots,

180mm x 180mm; then they were rolled into rebars with grooves and with a diameter of 16 mm and allowed to cool in air on a cooling device.

Charge 3, which does not belong to the weldable range, was produced in a 20-ton arc furnace and cast in a 6-ton square block mold. This charge was then rolled in a similar way to charges 1 and 2 and was produced in the form of a spirally twisted reinforcing bar with grooves and 8 mm diameter and air-cooled. The results of testing the materials are as follows: The charges are produced by normal metallurgical methods which consist of melting the iron charge in the furnace described above, analysis of the composition of the melt as well as the possible addition of additional ingredients to balance the composition. The molten charge is superheated 80°C above the casting temperature and poured into casting ladles. The various alloying elements indicated in Table 1 were added to arrive at a final composition as indicated in Table 1. The contents of the ladles are then poured into molds or in a continuous casting plant as indicated above.

The method and the equipment used are described by L. Backer and

P. Gosselin in Journal of Metal, May 1971 No. 23 page 16 to page 27.

Claims (2)

1. Reinforcing steel with high mechanical strength, weldable up to a certain carbon content and resistant to atmospheric corrosion, characterized in that, in addition to iron and the usual residual elements, it mainly consists of, in % by weight 2. Reinforcing steel according to claim 1, characterized in that it consists of, in addition to iron and the usual residual elements