LT6275B - Mounting equipment for reinforcing bars group of concrete structural element - Google Patents

Abstract

The invention relates to building construction elements and can be used for manufacturing reinforced concrete construction elements and for testing their mechanical properties. Fixing equipment in both ends of the concrete construction element (1) has two symmetrically installed anchoring units (3) of reinforcing bar (2) consisting of two from each other separated plates (6) connected to the central (7) and at least four rods (8) which has identical orifices through which pass concrete element reinforcement bars (2) which has a gap between the plate (6) poured with concrete (9). Central rod (7) is connected to a stretching machine (4). Among the concrete member (1) and on the anchoring unit (3) is provided a space. Construction element (1) and the anchoring units (3) may be made at the same time with the same or different composition of the core (9). Anchoring units (3) may be made before producing the element (1) or have additional assembling equipment (10).

Description

The invention relates to the field of building structural elements and can be used for the production of reinforced concrete construction elements and their mechanical properties. A known fixture group of reinforcing bars for a concrete structural element is intended for the investigation of simple structural elements reinforced with one rod. Such equipment is described by Keivan Noghabai (2000), Behavior of Tie Elements of Plain and Fibrous Concrete and Varying Cross Sections, ACI Structural Journal. The disadvantage of this equipment is that the primitive fastening of the elements in the reinforcing rod by mechanical clamping of the grips during the test due to the geometric nonlinearity of the element can cause a non-central stretching of the element and an uneven distribution of the cracks. High compressive force can damage the rod structure, so the fastening equipment limits the use of non-metallic reinforcements (carbon, glass, basalt, aramid fibers). The fastening equipment also limits the ability to determine the deformation of the rods in the concrete element. The fastening equipment for simple tensile concrete structural elements was described by Lars Eckfeldt (2013), Design for SLS according to the Fiber Model Code 2010, Structural Concrete. This equipment allows the reinforcement bars to be laid in only one layer and requires a specific test bench. Like the equipment offered by Keivan Noghabai, the mounting method in question prevents the reinforcement of the specimens with non-metallic bars and the measurement of the deformation of the rods.

Attachment of a group of rods for a concrete element of a reinforced concrete element, described by Ekkehard Fehling, Torsten Leutbecher, Friedrich-Karl Roeder (2011), Compression-Tension Strength of Reinforced and Fiber-Reinforced Concrete, ACI Structural Journal for Multi-String Reinforced Elements ( stress in several directions) for stress tests. The disadvantage of this equipment is that this type of fastening equipment requires sophisticated testing machines (hydraulic / electromechanical presses), so this mounting method is not suitable for standard laboratory equipment.

Tensile Equipment, described by Armin Ziari, M. Rėza Kianoush (2009), Investigation of direct tension cracking and leakage in RC elements, Engineering Structures for reinforced rods arranged in two layers. Due to the loading of the sample by two unrelated load attachment devices (jacks), it is difficult to ensure uniform deformation of the sample and the rods in it by using massive twin profile profiles. This type of fastening increases the total weight of the sample, resulting in an uncontrolled frictional effect when the item is in a horizontal position. It is not possible to fix the deformation of the reinforcement bars using the provided fastening equipment. The method of attachment requires specific laboratory equipment.

Anchoring equipment described by E. Volarab, M. M. Kulkarni, C. Ouyang, S. P. Shanh (1996), Response of Reinforced Concrete Panels under Uniaxial Tension, for Investigation of Structural Elements, Mostly Plates Reinforced with Multi-Rods. The main disadvantage of the equipment is that it is extremely difficult to secure and control the reinforcement of the concrete element due to the externally mounted tensioning equipment. Using this mounting method, the specimens are stretched outside the concrete part. Such a test method is specific and is not equivalent to stretching the elements beyond the reinforcing bars. It is not possible to measure the deformation of the reinforcement rods using this mounting method.

The Chinese patent application CN104181020 (A) provides equipment for the production of reinforced concrete elements. The equipment consists of standardized segments for fastening reinforcement bars during concrete forming. In standardized segments, holes are arranged regularly to allow the reinforcement bars to be arranged in different configurations. This equipment allows the production of concrete elements in stages and ensures the design position of the steel reinforcement bars (transverse and longitudinal), but does not ensure uniform reinforcement of the reinforcing rods during loading. Also, this equipment does not allow direct measurement of rod shifts.

Another Chinese patent application CN 104236964 (A) describes a formwork and concrete element fastening device that allows the concrete element to be attached to the tensioning device. The fastening equipment consists of several bars integrated into the standardized formwork. The rods used for fastening allow for the redistribution of element deformations to the central tension of the element. However, this fastening equipment does not provide for reinforcement of concrete elements.

The closest technical solution of the proposed invention is the fastening group reinforcement of the reinforcing group concrete construction element described in Kelvin Fields and

Peter H. Bischoff (2004), Tension Stiffening and Cracking of High-Strength Reinforced Concrete Tension Members, ACI Structural Journal. This fastening device has two anchoring assemblies (massive anchor blocks) at the ends of the tensioning element, which include longitudinal arm groups of the element being tested and anchor rods. The anchoring rods are punctured through each formed support block, where one end of the anchor rods is secured with plates that rest on the inner plane of the concrete block and the other end of the rods are attached to the tensioning machine. Attaching the anchor rods to the test bench requires additional traverses that connect all anchor rods. The reinforced element can thus be connected to the standard test equipment. The fastening equipment described does not guarantee the positioning of the projecting bars in the cross-section of the element. It is also impossible to position the reinforcement bars at a small distance from each other. Due to the massive anchor concrete blocks, the weight of the specimens at the ends of the element increases significantly. With such geometry of the sample, it is difficult to interpret the element's cracking parameters, as it is necessary to know the distance from the anchor block to the crack.

The object of the present invention is to provide a fastening device for a concrete structural element, a reinforced group rod, which could easily provide a central stretch of a concrete element while maintaining the design position of the reinforcing rods. The object of the invention is achieved by the fact that the anchor assembly of the reinforcing rod grouping of the reinforcing element of the concrete structural element comprises two spaced apart plates connected by at least four rods and a central rod connected to the tensioning device. The anchor plate plates have equally spaced holes through which the reinforcing bars of the concrete element are passed, which are filled with concrete (or other composite material) between the plates of the anchorage.

According to the present invention, using a fastening device for reinforcing bars of a concrete structural element, the tensile load from a standard tensioning machine is transmitted to the reinforcing bars in the structural element which pass through the plate holes in the anchoring node. The anchor assembly ensures the design position of the reinforcing bars. In addition, it allows variation of reinforcement material and rod arrangement in the cross-section of the manufactured element. The filler between the anchor node plates allows each reinforcement rod to deform differently in the anchoring zone and thereby to equalize the tension of the reinforcing rods and, consequently, to ensure the center tension of the rod group. This choice of filler composition ensures adaptive deformation of the anchor assembly, as it allows controlling the strength and displacements of the reinforcement rods. This reduces the physical eccentricity of the composite element and allows the variation of the materials used to produce the element.

According to the present invention, the concrete structural element and the anchoring assemblies can be made at the same time and have the same filler, or the anchoring assemblies with the reinforced rods can be made before the concrete element is produced. This makes it possible to prepare the sample (structural element) at different stages and also to produce pre-stressed elements.

There is a gap between the edges of the concrete structural element and the anchorage, which allows direct measurement of the displacement and deformation of the reinforcing bars. Additional anchoring nipple crushing equipment allows for increased reinforcement and stiffness of reinforcement bars. The invention is illustrated by the drawings, in which:

FIG. Fig. 1 is a general diagram of a fastening device for a reinforcing bar group of a concrete structural element;

FIG. 2 is a structural element according to FIG. 1 tensile loading scheme;

FIG. 3a - components of anchorage anchorage for anchorage equipment; FIG. 3b -gating unit with filler and reinforcement bars; FIG. 3c - anchorage with additional crimping equipment.

FIG. Figure 4a shows an example of the use of fastening equipment in laboratory tests; FIG. Fig. 4b shows the load and strain dependence of reinforcement bars obtained during the tests.

The reinforcing bars 2 of the concrete structural element 1 are fastened to the anchoring assemblies 3, which are connected to the standard tensioning machine joints 4 through the spherical hinges 5. The anchor assembly 3 consists of two mounting plates 6 with identical holes in which the reinforcing rods 2 of the concrete element are inserted into the central rod. 7, to which the standard tensioning device connectors 4 are connected, and the four additional connecting rods 8. The spacing between the plates 6 is filled with concrete 9. The node 3 may have additional compression equipment 10 to increase the anchor strength. Spherical hinges can be used to connect the central rods 7 to the tensioning machine (eg UMM-200) for additional (central tensioning) 5. There is a gap between the anchorage 3 and the structural element 1 to provide displacement / strain gauge sensors to the reinforcing bars 11.

The proposed equipment allows the construction of the structural element 1 (sample) in two ways. In the first case, the entire article consisting of anchoring assemblies 3 and the structural element 1 is concreted simultaneously using the same filler 9. Alternatively, the anchoring assemblies 3 and the elements 1 are produced in several stages: the fastening plates 6 and the reinforcing rods 2 through the holes 6 of the fastening plates is poured into concrete 9 before manufacturing the element 1. After the anchoring nodes 3 have been formed, the reinforcing rods 2 may be tensioned at another stage, thereby forming a pre-stressed concrete element 1.

In both methods, the structural element 1 with the prepared anchoring units 3 is connected to the standard tensioning machine via a central rod 7 connected to the mounting plates 6. When using a test machine without integrated flexible joints (drawings not shown), spherical hinges (hinges) 5 or pin hinges (drawings not shown) may be used to fasten element 1. The tensile load is transmitted through the anchor 3 to the existing reinforcement bars in the concrete element 1. Between the anchorage 3 and the structural element 1, a gap is formed allowing the measuring rods 11 to be fixed to the reinforcing bars 2 and to directly observe the deformations of the reinforcing bars 2 and their slip in relation to the concrete. An example of the use of the anchor node 3 and the results obtained are shown in FIG. 4a. A universal tensile machine UMM-200 is connected to the test element 1, which is produced simultaneously with the anchoring members 3 through the spherical hinges 5. The deformation sensors 11 directly measure the reinforcement deformations shown in FIG. 4b. The results in this chart show 2 samples of reinforced rods 4 and 16 (equal total reinforcement area). Known mounting analogues do not allow such measurements. The invention is compatible with reinforcing bars of various materials and different geometry and can be used for the manufacture of pre-stressed reinforced composite structural elements and for axial (central) stretching experimental testing of multi-rod composite elements.

Claims (6)

Definition of the invention 1. Reinforcing bars for reinforcing bars of a concrete structural element, having two symmetrically anchored assemblies (3) of reinforcing rods (2) at both ends of the concrete structural element (1), characterized in that the anchor assembly (3) comprises two spaced apart disconnected plates (6) connected to the central (7) and at least four rods (8), wherein the plates (6) have equally spaced holes through which the reinforcing rods (2) of the concrete structural element (1) pass through the anchor node. (3) the plates (6) are filled with concrete (9), and that the central rod (7) connecting the plates (6) of the anchor assembly (3) is connected to the tensioning machine (4). 2. Reinforcing rod group fastening equipment according to claim 1, characterized in that the concrete structural element (1) and the anchoring units (3) are made at the same time and have the same filler (9). Reinforcing rod group fastening equipment according to claims 1 and 2, characterized in that the composition of the filler (9) of the anchoring unit (3) may differ from the material of the concrete structural element (1). Reinforcing rod group fastening equipment according to claims 1 and 2, characterized in that the anchoring assemblies (3) with reinforcing bars (2) of the concrete element (1) therein can be made before the production of the concrete structural element (1). 5. Reinforcing rod group fastening equipment according to claim 1, characterized in that a gap is provided between the edges and the anchoring units (3) of the concrete structural element (1). 6. Anchor rods anchoring assemblies according to any one of the preceding claims, characterized in that the anchoring assemblies (3) of the reinforcing rods (2) may have additional compression equipment (10).