RU2377373C1 - Reinforcing rod of alternate section - Google Patents

Abstract

FIELD: building.

SUBSTANCE: reinforcing rod consists of at least three parts wherein cross section of rod is increased comparing to base cross section; also there are even transitions between parts with base and increased cross sections. Structure of metal of the rod corresponds to hot deformed condition on each part with increased cross section. Position on the core of each part with increased cross section corresponds to coordinates of stress zones of a building structure equipped with reinforcing rods. Parts with increased cross section are distributed along whole length of the rod; each part is characterised with coordinate of position, length and cross section altered according to acyclic law. Cross section of parts situated on ends of the rod is increased comparing to parts located between them. The technical object is achieved due to creation of characteristic zones of increased diametre on the rod; these zones are fixed in volume of a reinforced structure, where there are present local bends of generatrix of the reinforcing rod; i.e. the object of the invention is met with essential difference between base and locally changed section of the steel reinforcing rod.

EFFECT: structure of reinforcing rod facilitating fixed position of steel reinforcing rod in concrete even under condition of lost connection of rod with concrete along base lengthwise steel surface.

5 cl

Description

The proposed invention relates to the field of construction. A more specific area of use of the proposed invention is the production of building structural materials.

In industrial and civil engineering, concrete structures are widely used. In the production of building blocks and panels, concrete structures are reinforced with various materials (reinforced concrete, fiber concrete, etc.). To ensure reliable adhesion of reinforcement to concrete, the surfaces of the reinforcing rods or reinforcing wire give a profiled view. For any type of profile periodicity, in accordance with current regulatory documents (GOST 5781-82), reinforcing bars in any cross section have a constant area and are characterized by constant mass per unit length. Other methods are also known for increasing the reliability of adhesion of concrete to the surface of a steel reinforcing bar, for example by using an end anchor: direct end of a bar with an increased cross section, for example, welding of an end element to a bar, etc. (Code of design and construction rules. SP 52-101-2003. Moscow. 2004. Section 8, US Standard ASTM A970).

As the closest analogue of the proposed technical solution, the technical solution described in the published patent application of Japan JP 2001323958 is selected. JP 2001323958 describes a reinforcing bar of variable cross section, the design of which includes sections whose cross section of the bar is increased compared to the base section of the same bar. According to JP 2001323958, the design of the rod provides for smooth transitions between areas with a base and enlarged cross-section. However, this local increase in the cross section of the reinforcing bar is not intended to form an anchoring portion of the reinforcing bar, and, in addition, in places of increased cross section, the surface of the bar is not directly in contact with concrete. A local increase in the cross-section of the rod ensures the achievement of another goal: holding in a fixed position a special element worn on a reinforcing bar and playing the role of an anchor. An anchor made in this way has the form of a large washer, the outer surface of the element is in contact with the concrete surrounding it, and the inner surface of the element has an annular recess in which the entire area of the reinforcing bar with an enlarged section is placed.

That is, the reinforcing bar described in JP 2001323958 provides, as a separate and mandatory component, the use of a separate element of a special shape in which the deformed metal is placed, and the forming element has a through hole and is put on the rod through the necessarily free end of the rod. Also, the use of a rod of known design is not possible for extended products of a non-linear appearance, for example, for reinforcing bars rolled up for delivery to bays, riots or coils. Also in the known reinforcing bar, a certain extraneous element is used, constantly covering the bar around the perimeter and ensuring the creation of an anchor after completion of technological procedures. Upon completion of concrete work, this element plays the role of a portion of the rod with an increased diameter, although it is not a direct element of the rod, does not have a chemical composition corresponding to the composition of the rod, and does not form a uniform structure with the rod.

Under operating conditions of the reinforced concrete structure, the profiled surface of the reinforcing bars or the made anchors provide reliable adhesion of the reinforcement to concrete. However, the steel surface, developed in area and complex in shape (as a result of periodic profiling), increases the intensity of metal corrosion on the surface of reinforcing bars. This manifests itself especially intensively when moisture penetrates into the building structure and at temperature extremes. The ribs and protrusions on the surface of the periodic profile are stress concentrators under dynamic loads. Corrosion of steel reinforcing bars and uneven stress state of the metal cause a decrease or loss of contact interaction of concrete and the steel surface of the reinforcing bars. The negative effects listed above are amplified when additional elements are included in the design of the reinforcing bar, similar to those used in JP 2001323958.

The objective of the proposed invention is the creation of such a structure of a reinforcing bar, which could ensure the production of reinforced concrete building structures, operable with significant corrosion damage to the steel reinforcing bar and with local or general loss of connection of steel with concrete.

The main objective of the proposed invention is to create a structure of such a reinforcing bar, which would ensure the performance of reinforced concrete products in the conditions of the development of real corrosion damage to the surface of the reinforcing bar, including the complete loss of connection between the surface of the steel bar and the surrounding concrete.

It is also an object of the invention to create real possibilities for maximizing the use of smooth steel reinforcing steel in construction instead of periodic steel reinforcing steel. Both of these goals are achieved using a reinforcing bar with a variable cross section along its length.

As a result, the strength properties and service life of both the reinforcing bar and individual building structures will be increased, in the manufacture of which such reinforcing bars will be used, as well as the operational characteristics of the buildings and structures being constructed. In addition, the proposed invention will provide the opportunity to use the "individual approach" in the design of block building structures, which is especially important in the design and construction of buildings and structures, the quality of which is subject to increased requirements.

The technical result expected from the use of the proposed technical solution is achieved by the fact that the proposed reinforcing bar of variable cross section, including sections of the bar, the cross section of which is increased compared to the base cross section, in the presence of smooth transitions between areas with the base and increased cross section, also in each of the sections of the rod with an increased cross-section, the structure of the material of the rod corresponds to a hot-deformed state.

In contrast to the known technical solutions, the cross section of the rod is increased in comparison with its basic cross section in at least three sections distributed along the length of the rod. In this case, the areas on which the cross-section of the rod is to be increased correspond to the position of the stress zones of the building structure equipped with reinforcing bars and distributed along the entire length of the bar, with a change in their position coordinates, lengths and cross-sections according to a non-periodic law. The cross section of sections located at the edges of the rod is increased by at least three times compared with the sections located between them. In particular cases of the implementation of the proposed technical solution, the surface of the core part with a basic cross section is smooth or with periodic corrugation, in addition, a protective coating can be applied along the entire length of the core or in separate selected areas.

In accordance with the invention, sections are formed on the reinforcing bar along its entire length, the cross section of which is increased in comparison with the cross section of the reinforcing bar provided for by standard regulatory documents (i.e., compared with the base cross section) and the calculated value for the reinforcement. Each of these sections is characterized by the state of the core material, which is characteristic of a hot-deformed state, and at the same time does not differ in chemical composition from the material of the entire core, that is, along the entire length of the core, regardless of section, the core material will have the same composition (i.e. for the manufacture of the entire rod the same material will be used, steel, titanium or another alloy). The increase in cross-section performed on any of the sections of the rod exceeds the tolerances specified in the normative documentation for the initial calculated (base) diameter of the rod. At least three sections with an enlarged cross-section are provided on the bar: for example, two sections at the ends of the reinforcing bar, or at a selected distance from the ends of the bar, and the sections between them. At the same time, when forming sections on each of them, a smooth transition from a basic cross section to an enlarged one is ensured.

Depending on the type of standard reinforcing bars - blanks, the reinforcing bar in its base part will either be made smooth or will have a surface of a periodic profile. Thus, in accordance with the invention, an enlarged cross-section in selected areas ensures the creation of special zones along the length of the shaft of the distributed system with an anchoring effect in the concrete volume.

The sections of the reinforcing bar, providing the creation of this effect, are "tied" to the most loaded areas of the building structure based on the following provisions of the invention. The location along the length of the reinforcing bar of the special characteristic sections, the cross section of which is increased, correspond to the position of the stress zones of the building structure. The geometric parameters of the characteristic sections on the rod: their length and cross sections are set from specific operating conditions, i.e. change according to non-periodic law and cannot be described by any regular dependence. At the same time, they strive to increase the cross section of the sections located at the edges of the rod in comparison with the sections located between them by at least three times. In various versions of the new reinforcing bar, its base surface may be smooth or have a periodic profile, or with a protective coating applied to the surface of the bar (in whole or in its individual sections). The preferred option selected from technical and economic considerations is the use of a reinforcing bar with a smooth surface.

Anchoring zones distributed and “tied” to the most loaded areas of the building structure, due to their increased cross section, are fixed in the concrete volume of the building structure, which ensures the resistance of the reinforcing bar to shear. Even in the event of a loss of contact interaction of concrete with the entire surface of the steel reinforcing bar along its generatrix, the use of the bar of the proposed design does not lead to a loss of its bearing capacity, since the bulk of the loads are transmitted in the axial direction, and a much smaller one is transmitted through its extended surface. Due to the increased cross-section, the position of the reinforcing bars in the building structure becomes determined and does not depend on the quality of contact of concrete with the material of the reinforcing bar. The presence of smooth transitions from the base cross section to the enlarged section prevents stress concentration on the reinforcing bar. The manufacture of a reinforcing bar from one material will eliminate the occurrence of corrosion due to the difference in electrochemical potentials. Thus, the possibility of long-term operation of a building structure under conditions of exposure to a corrosive environment and excessive loading is provided.

Before starting the production of the reinforcing bar, the locations of the sites are selected, the cross section of which is increased compared to the base cross section. For this, preliminary modeling of the building structure is carried out, in the manufacture of which reinforcing bars will be used, and in which the locations of the stressed sections are determined. In accordance with the specific locations of the alleged stressed "critical" sections of the reinforced concrete structure on the reinforcing bars, the places where the areas with the increased cross section should be located are determined, and the arrangement of the reinforcing bars in the building structure is also selected. In this case, a non-periodic law is selected (there is no mathematical dependence that could characterize the change in the cross section of the rod), according to which the length and cross sections of these sections will change, that is, there is no connection between the geometric characteristics of the shape of the rod and the technology of its manufacture. For example, a simulation of reinforced concrete blocks (or rings or other products) is performed based on the specific locations of each of the blocks in the building structure. Modeling of operating conditions will allow predicting the most dangerous places of the block and, accordingly, determining the location of anchoring zones on reinforcing bars.

Further, to locally increase the cross section in a selected section of the rod, a zone of the required width is heated (using a gas flame burner, electric current passes through the rod under the influence of magnetic induction current or otherwise) to a state of high plasticity of the product material, followed by local deformation of the rod in the axial direction . For this, sections located at a certain distance from the heating zone are fixed with clamps for movement, and counter-axial movement is carried out, deforming the heated sections to the state when their geometric dimensions correspond to the dependence defined above. Since this causes a bending of the forming surface of the rod, and the heated metal is bulging out physically, a section with an increased cross section is formed on the rod in which the structure of the metal of the rod corresponds to the hot-deformed state of the metal.

By adjusting the heating mode and the applied forces, it is possible to form the desired geometric shape of the area with an increased cross section. Technologically, the maximum metal temperatures in the heating zone, the profile of the temperature field along the axis of the rod, the distribution of heat sources along the rod, the exposure time between the end of heating and the beginning of axial deformation, the heating rate of the rod, the cooling rate of the rod after axial deformation, the force and the axial force deformation. A protective coating, such as a zinc coating, may be applied to the deformed areas. The listed procedures are repeated for each of the selected sections of the product. It is obvious that in the composition of the reinforcing bar made according to the described technology, welding and forging operations are excluded, there will be no welds, cast elements or sections that differ in chemical composition.

The reinforcing bar of the proposed design can be used in the production of any building structures made of reinforced concrete or fiber concrete. In addition, with small diameters of the order of 1 mm, such a rod with an arbitrary arrangement of small sections of increased diameter can be used as a long and continuous steel fiber element for the manufacture of fiber concrete.

Thus, in the proposed design of the reinforcing bar, the position and operability of the bar itself will not depend on the quality of contact of concrete with the material of the reinforcing bar. As a result, the service life of both individual building structures and constructed buildings and structures will be extended. Also, the proposed invention will provide the opportunity to use the "individual approach" in the design of block building structures, which is especially important in the design and construction of buildings and structures, the quality of which is subject to increased requirements, for example, to earthquake-resistant structures. As a result, the use of the proposed invention will in many cases make it possible to abandon the use of steel reinforcing bars with a periodic profile due to the use of smooth profile reinforcing bars, which in turn will make it possible to use cheaper rolling rolls and more economical technology for hot rolling of a smooth profile in the production of reinforcing bars.

Claims (5)

1. A reinforcing bar of variable cross section, including sections of the bar, the cross section of which is increased compared to the base cross section, in the presence of smooth transitions between sections with the base and enlarged cross section, while on each of the sections of the bar with an increased cross section, the structure of the bar material corresponds to a hot deformed state, characterized in that the cross section of the rod is increased compared to its basic cross section in at least three sections, p distributed along the length of the rod, corresponding to the position of the stress zones of the building structure equipped with reinforcing bars, and distributed along the entire length of the rod, with a change in their position coordinates, lengths and cross sections according to a non-periodic law, and the cross section of the sections located along the edges of the rod is increased compared to with sites located between them, at least three times. 2. The reinforcing bar of variable cross-section according to claim 1, characterized in that the surface of the part of the bar with a basic cross section is smooth. 3. The reinforcing bar of variable cross-section according to claim 1, characterized in that the surface of the part of the bar with a basic cross section is made with periodic corrugation. 4. Reinforcing rod of variable cross-section according to any one of the preceding paragraphs, characterized in that the protective coating is applied to the surface of the rod. 5. The reinforcing bar of variable cross-section according to claim 4, characterized in that the protective coating is applied to individual sections of the rod.