PL233106B1 - Bending element reinforced concrete reinforcement - Google Patents

Description

Description of the invention

The subject of the invention is the reinforcement of a reinforced concrete bending element.

The invention is used in construction and in reinforced concrete structures for the reinforcement of bent elements, especially beams.

A commonly known method of reinforcing beams is to place reinforcing bars in the tensile zone with an appropriate cross-sectional area and working in tension. The bending capacity of a beam is influenced by the appropriate bearing capacity of both the longitudinal reinforcement in the tension zone and the strength of the concrete in the compression zone. The preferred, i.e. signaled, beam failure mechanism for bending is to start this process from plasticizing the reinforcement in the tension zone. As a result, a significant increase in the elongation of the tensile zone reinforcement leads to an increase in the shortening of the concrete on the compression side, and consequently to its plasticization and, ultimately, exhaustion of deformation possibilities. The concrete of the compression zone is damaged by crushing and chipping. In the described case, the value of the resultant force transferred by the concrete in compression during failure may not exceed the value resulting from the limit, limited height of the compression zone. Therefore, also, for a specific concrete class and cross-sectional geometry, it becomes impossible to increase the bending resistance above a certain limited value.

Another known solution for increasing the bending capacity of the cross-section above the limited value is to strengthen the concrete zone under compression with longitudinal bars i, i.e. the use of the so-called double reinforcement. The use of the cooperation of the bars in compression with the concrete in compression is secured by the use of shear stirrups. In the current standard PN-EN 1992-1-1: 2008 / NA: 2010 Eurocode 2 Design of concrete structures. Part 1-1: General rules and rules for buildings recommended in this case stirrup spacing every fifteen bar diameters in compression reinforcement.

Another known solution is to increase the bending capacity of the cross-section by replacing the basic class of concrete of the element, only in the compression zone, with concrete of sufficiently high strength (BWW).

The patent description PL 218096 describes a prefabricated reinforced concrete element made of normal strength concrete and having a reinforcing insert placed in a recess made of high-strength concrete, in which shear stirrups with a conventional spacing are embedded. These stirrups are permanently connected to each other with at least two assembly bars. The vertical ends of the stirrup bars extend beyond the surface of the high-strength concrete insert and are permanently connected to the reinforcement skeleton by means of at least two assembly bars. The stirrups protect high-strength concrete against shearing and detachment from the beam concrete, which has a lower strength than the concrete of the insert. The mounting bars used in this case only maintain the shape and spacing of the stirrups, serving as a minimum structural reinforcement and do not constitute classic compression reinforcement. In this case, the reinforcement of the reinforced concrete beam is only due to the use of high-strength in the compression zone of the concrete, and not to the use of additional compressive reinforcement.

The main drawbacks of the above solutions, aimed at increasing the bending capacity of the cross-section, are the uniaxial stress state of the concrete in the compression zone, which may reduce its strength and often insufficient protection of the compression zone reinforcement against buckling in the area of the plastic stress range of this reinforcement. The use of a high-strength concrete insert makes it necessary to concret the beam in two cycles, which may cause delamination between the insert and the remaining standard quality concrete performed in a different concreting cycle. Moreover, the reinforcement in the compression zone of high-strength concrete according to the description PL 218096 is only an assembly reinforcement and, due to the small cross-section specific to assembly reinforcement, transmits compressive stresses to a very small extent. Additionally, the stirrups of this insert are projected beyond its outline, which makes it impossible to constrain transverse deformations of high-strength concrete. An additional problem is that the failure of the beam, with a high degree of tension reinforcement, occurs at very small angles of rotation of the cross-section, which is disadvantageous from the point of view of the load-bearing capacity of statically indeterminate structures, as it limits the redistribution of bending moments. On the other hand, the buckling of the bars in compression causes, among others. crushing of the concrete compression zone, which further reduces the load-bearing capacity and stiffness of the element. Then, the exhaustion of the beam capacity is not preceded by large, clearly visible and signaled deflections. It makes it impossible

Proper protection of the overloaded structure may be the cause of un signaled elastic-brittle failure.

Reinforcement of a reinforced concrete bending element, especially beams, containing longitudinal compressed bars and longitudinal tensile bars as well as classic four-angle stirrups placed at least every fifteen diameters of longitudinal reinforcement and holding the longitudinal bars in a given position and transferring shear, is characterized by the fact that in the compressed zone of the beam, near the neutral axis of the section, it has a longitudinal anchor bar and triangular stirrups encircling the longitudinal compression bars and an anchor bar, which stirrups are spaced every five to seven diameters of the longitudinal compression bars. Densely arranged triangular stirrups, embracing the longitudinal bars of the compression zone and the longitudinal anchor bar, prevent buckling of the bars in compression and restrain the part of the concrete in the compression zone that is inside the contour of the triangular stirrups.

Such positioning of additional, densely spaced triangular stirrups including the compression bars and the anchor rod allows obtaining a high-load-bearing bending reinforced concrete element made of normal strength concrete.

In another version of the solution, the reinforcement of a reinforced concrete bending element, especially beams, containing longitudinal compression bars and longitudinal tensile bars and classic square stirrups placed at least every fifteen diameters of the longitudinal reinforcement and holding the longitudinal bars in a given position and transferring shear, is characterized by that in the compressed zone of the beam, near the neutral axis of the cross-section, it has a longitudinal anchor bar and a broken helix formed from one bar with a triangular outline and a small pitch of five to seven diameters of compression reinforcement, which helix encircles the longitudinal compression bars and the anchor bar. The helix with a triangular outline and a small pitch, embracing the longitudinal bars of the compression zone and the longitudinal anchor rod, prevents buckling of the bars of the compression reinforcement and restrains the part of the concrete in the compression zone that is inside the triangular contour of the spiral cross-section.

In the solution according to the invention, additional, densely spaced triangular stirrups or a single-bar broken helix with a triangular outline and a small pitch do not transfer shear loads, as the classic square stirrups used, but tensile forces. These forces result from the transverse deformation of compression concrete of ordinary quality and the lateral displacements of the compression bars related to their tendency, due to instability phenomena, to buckling in the plastic range.

A small spacing of triangular stirrups or a small pitch of a broken helix with a triangular outline including the bars in compression and the anchor rod constrains some of the compressed concrete and significantly reduces the buckling lengths of the bars of compression reinforcement, which significantly increases the load-bearing capacity and safety of the element. The anchor rod, located near the neutral axis of the cross-section, prevents the tearing of triangular stirrups or a broken helix with a triangular shape from the compressed concrete zone due to buckling of the compressed bars. The construction of the reinforcement with the use of triangular stirrups or a broken helix with a triangular outline, according to the invention, causes that in the compressed zone of the beam it works in tension, and not shear, as in a classically reinforced beam. The concrete in the beam is the same throughout its cross-section, and the element is made in one concreting cycle, which is extremely advantageous from the technological, structural and strength point of view.

The main effect of the application of the invention is to increase the load capacity of the cross-section as a result of securing compressed reinforcement bars against plastic buckling and obtaining conditions for triaxial compression of concrete by limiting its transverse deformation due to restraint by means of densely spaced triangular stirrups or a broken helix with a triangle outline and a small pitch cooperating with compression reinforcement and an anchor rod.

The effect of limiting transverse deformations of both the compressed bars and the concrete has a positive effect on increasing the strength and limit deformability of the entire compression zone of the element's cross-section. The external energy required to destroy the constrained concrete compression zone and the buckling of the constrained bars of compression reinforcement increases, increasing the beam's bending capacity. If, as a result of overloading the structure, the beam is damaged, it will be well signaled, tough and delayed, which will allow for appropriate protection. When this solution of reinforcement of the compression zone is used, an increase in the angles of rotation over the values achieved with the previous solutions is obtained at the same time. This influences a favorable change of the mechanism of possible beam failure from the nonlinear elastic-brittle model, in which the failure occurs suddenly and without previous signs of reaching the ultimate limit state, to the nonlinearly elastic-plastic model, where failure occurs slowly and is signaled much earlier

PL 233 106 B1 by distinct beam movements. Such a model of destruction significantly increases the safety of the structural element, as the previously signaled displacements enable the beam to be protected against its destruction.

The subject of the invention is shown in the drawing, in which fig. 1 shows a longitudinal section of the reinforcement of a reinforced concrete element bent with triangular stirrups, fig. 2 - a cross section of a reinforced concrete beam with an anchor rod and triangular stirrups, fig. 3 - reinforcement of a reinforced concrete element bent in broken spiral with a small pitch, fig. 4 - cross-section of a reinforced concrete beam with an anchor rod and a triangular helix, fig. 5 - expansion of the reinforcement walls with a broken helix, fig. 6 - axonometric view of a broken helix with a triangular outline.

P r z k ł a d I

In the embodiment of the invention shown in Fig. 1 and Fig. 2, in the compression zone of the beam 1, the longitudinal bars 4 and the anchor bar 5 are chained with triangular stirrups 3 with a spacing not exceeding five to seven diameters of the compression bars 4. The stirrups 3 encircle the reinforcement 4 and the bar. anchoring 5, reducing the buckling lengths of the bars in compression 4, which prevents their buckling and constrains, in the transverse direction, part 2 of the compressed concrete zone. The longitudinal bars 7 constitute the classic reinforcement of the tension zone of the beam 1, and the quadrangular stirrups 6, spaced at a distance of not less than fifteen longitudinal bars' diameters, are the classic shear reinforcement.

P r z x l a d II

In the embodiment of the invention shown in Fig. 3, Fig. 4, Fig. 5 and Fig. 6 in the compressed zone of the beam 1, the longitudinal bars 4 and the anchor rod 5 are bound with a spatial broken helix 8 with a triangle outline with ABC vertices and a pitch not exceeding five to seven diameters of the compression rods 4. The broken helix 8 encircles the reinforcement 4 and the anchor rod 5, reducing the buckling lengths of the compression rods 4, preventing their buckling and restraining, in the transverse direction, part 2 of the compressed concrete zone. On the walls of the restrained concrete body with edges a, b, c, the helix 8 leaves a trace on the unfolding of the walls (Fig. 5) with straight lines that are mutually parallel with shifts equal to the value of the spiral pitch. The longitudinal bars 7 constitute the classic reinforcement of the tension zone of the beam 1, and the quadrangular stirrups 6, spaced at a distance of not less than fifteen longitudinal bars' diameters, are the classic shear reinforcement.

Claims (2)

Patent claims 1. Reinforcement of a reinforced concrete bending element, especially beams, containing longitudinal compression bars and longitudinal tensile bars, girded with classic stirrups arranged no more than fifteen diameters of longitudinal reinforcement bars and keeping the longitudinal bars in the given cross-section, position and transmitting cross-sectional transverse forces of the reinforced concrete element bending, characterized in that in the compressed zone of the beam (1), near the neutral axis of the cross-section, it has a longitudinal anchor rod (5) and triangular stirrups (3) surrounding the longitudinal compression rods (4) and an anchor rod (5), which are stirrups (3) are spaced every five to seven longitudinal diameters of the compression bars (4). 2. Reinforcement of a reinforced concrete bending element, especially beams, containing longitudinal compressed bars and longitudinal tension bars, girded with classic stirrups arranged not more than fifteen diameters of longitudinal reinforcement bars and keeping the longitudinal bars in the given cross-section, position and transmitting cross-sectional transverse forces of the reinforced concrete element bending, characterized in that in the compressed zone of the beam (1), near the neutral axis of the cross-section, it has a longitudinal anchor rod (5) and a broken spiral with a triangle shape (8) formed from one bar, surrounding the longitudinal compressed bars (4) and the the anchor bolt (5), the helix (8) having a pitch of five to seven diameters of the longitudinal members of the compression bars (4).