RU77434U1 - STAND FOR TESTING REINFORCED CONCRETE ELEMENTS FOR A SHORT DYNAMIC BENDING WITH COMPRESSION - Google Patents

Abstract

A bench for testing reinforced concrete elements for short-term dynamic bending with compression can be used in impact tests. A power plant with a load ejector and supports for a reinforced concrete element are mounted on the power floor. The masts of the pile rig are equipped with a load limiter. A loading beam with a force meter fixed to it is installed on the reinforced concrete element. Accelerometers are installed on the load cell and on the load spreader. Additional traverses are installed on both sides of the pile rig. Traverses are interconnected by means of cords. The longitudinal compression of the reinforced concrete element is carried out using a jack mounted on one side of the reinforced concrete element between it and the additional traverse. The compressive load from the jack is transmitted to the beam using metal balls through metal plates. Metal plates are mounted directly at the ends of the reinforced concrete element. The stand is equipped with an insurance system to limit the deflection of a reinforced concrete element. The technical result consists in creating a stress-strain state, characterized by the action of bending moment and longitudinal compressive force during short-term dynamic loading. 1 n.a. and 4 z.p. f-ly, 4 ill.

Description

The invention relates to a testing technique, namely, machines for testing samples for dynamic bending with compression, for example, under the influence of shock loads on a longitudinally compressed sample.

An analogue of the claimed device is a testing machine for mechanical testing of materials according to the patent of the Russian Federation for invention No. 2243535, IPC 7 G01N 3/08, published 2004.12.27. The machine includes a loading device consisting of a base, columns, a crosshead, a load drive, an electrotensometric force sensor, a passive and active gripper, a strain gauge, an active gripper displacement sensor, a strain measurement unit, a load control unit, and a computer. This machine provides axial deformation of the samples. In this case, when the test samples are stretched, misalignment of the grips may occur. This leads to a spread of test results. In the known machine, the strain gauge is made in the form of two metrologically identical, but mechanically and electrically independent strain gauges connected to the measuring unit. The reliability of the tests is increased by automatically calculating the stresses from the accompanying bending.

However, this test machine does not allow to investigate the full operation of the elements during short-term dynamic bending with compression.

The closest device adopted for the prototype is a stand according to the patent of the Russian Federation for utility model No. 48225. This device contains: supporting elements mounted on a power floor,

additional supports located on both sides of the loading device, additional traverses installed on these supports; cords, the ends of which are fixed in additional traverses, three metal plates, rollers, loading traverse, load meter and jack. The loading device is made in the form of a pile rig, the masts of which are equipped with a load limiter. One roller is placed motionless in the cutout of one support element, the other in the cutout of the second support element with the possibility of horizontal movement, two metal plates are placed on the rollers, and the third is fixed on the outlets of the reinforced concrete element. Traverses are made with holes for skipping releases of reinforced concrete element reinforcement. A jack is installed between the third metal plate and the additional traverse. Supports for additional traverses are made with the possibility of adjusting their height. This stand allows you to test reinforced concrete elements for eccentric short-term dynamic tension and to study the operation of the element in the event of bending moments of two planes and the action of longitudinal tensile forces, but does not allow to study the operation of the element in the event of bending moment and the action of longitudinal compressive forces, which, as shown by theoretical studies, in some cases, arise during the operation of reinforced concrete structures. In addition, the well-known stand adopted for the prototype does not allow to fix the moment of the beginning of the fall of the load on the experimental sample, which does not allow to fix the time of the beginning of the dynamic load and expand the scope of the determined parameters.

The objective of the utility model is to expand the range of dynamic studies and provide the ability to conduct dynamic bending tests of reinforced concrete structures under the action of longitudinal compressive force. The technical result, the achievement of which is aimed at solving the problem, is to create a tense

a deformed state characterized by the action of a bending moment and longitudinal compressive force during short-term dynamic loading, and fixing the moment of falling of the load and the moment of impact on the test structure.

The problem is solved as follows.

In common with the prototype is that the claimed device contains: mounted on the power floor, a hammering unit with a load ejector, the masts of which are equipped with a load limiter, supports for a reinforced concrete element, a loading beam with a force meter mounted on it, mounted on a reinforced concrete element, supports located on both the sides of the pile plant, on which additional traverses are installed, interconnected by means of cords, a jack, rollers mounted on supports under reinforced concrete a cement, one of which is motionless, the second with the possibility of horizontal movement, and metal plates.

But, unlike the prototype, this device additionally contains: accelerometers, one of which is mounted on the load shedder, the other on the force meter, strain gages glued to the supports under the reinforced concrete element, and metal balls, while metal plates are mounted directly at the ends of the reinforced concrete element, metal the balls abut against these plates, and the jack is located between the additional traverse and the metal ball.

In the particular case, supports for additional traverses are made with the possibility of adjusting their height. The loading beam is installed on the reinforced concrete element through metal plates, and metal plates are also placed between the reinforced concrete element and the rollers.

In addition, the stand is equipped with an insurance system to limit the deflection of a reinforced concrete element, installed at a distance of its maximum allowable deflection.

The stand also additionally contains damping pads mounted on the load cell.

The location of the metal plates directly at the ends of the reinforced concrete element, the presence of metal balls and the installation of a jack between the additional traverse and the metal ball allows pulling the experimental reinforced concrete element in the longitudinal direction. When struck in a compressed reinforced concrete beam, a bending moment occurs. The stress-strain state at this moment is measured using measuring instruments. The presence of accelerometers allows you to accurately record the beginning of the discharge of the load on the experimental sample, as well as determine the start time of the dynamic load on the experimental sample at the time of impact. Strain gauges glued to supports under a reinforced concrete element record the strength of the support reactions. Therefore, the inventive stand allows simultaneously with the creation of a stress-strain state in the experimental sample to calculate the speed and duration of the dynamic load. In this regard, the range of dynamic testing of reinforced concrete structures under transverse bending with compression is expanding.

The utility model is illustrated by drawings. Figure 1 shows a General view of the test bench; figure 2 is a front view, figure 3 is a side view, figure 4 is a top view.

The design of the stand is installed on the power floor 1, to ensure rigid fastening. It includes supports 2, a copying unit 3. Strain gages are glued to the supports 2, and they, in fact, are dynamometric. An experimental sample 5 is installed on the dynamometer bearings 2. The design scheme is an articulated beam. Under the experimental sample 5 is a system of insurance 4, made to avoid damage to the measuring instruments. It restricts the movement of sample 5 and the boot

traverse 6. The insurance system 4 is installed at a distance of the maximum allowable deflection from the experimental sample 5. Using the loading traverse 6, the load is transferred to the beam in quarters of the design span. A load meter 7 is rigidly attached to the loading traverse 6, which fixes the value of the dynamic load. On the load meter 7 (figure 2) damping pads 8 are installed on top, which allow you to stretch the effect of short-term dynamic load in time. An accelerometer 9 is located on the force meter 7, fixing the time of the onset of the action of the dynamic load. The uncoupling of the load 11, for example, weighing 400 kg, occurs with the help of the load ejector 12. On the masts of the pile rig 3 safety elements 10 are mounted for securing the load 11 after the impact (Figs. 1, 2). The load ejector 12 is triggered by the start of the experiment and pressing the start button of the locking system. An accelerometer is installed on the load ejector 12, which fixes the time instant of the beginning of the fall of the load. The spreader 12 at a predetermined height is held by a system of cargo holders and a spreader 13, which ensures accurate fixation of the load 11 at the required height and protects the load from spontaneous unplanned unhooking. The experimental sample 5 is mounted on the torque supports 2 through the metal plate 14 (Fig. 3), and the loading beam 6 is laid on the experimental sample 5 through the metal plate 15. The metal plate 14 is placed on the rollers placed in the cutouts of the torque supports 2. The stand contains a jack 16 (figure 1). It is located between the metal ball 17, which abuts against the metal plate 18, and the traverse 19. On the opposite side of the experimental sample 5 (reinforced concrete element) is mounted on the support of the traverse 20. At the end of the sample 5 from the side of the traverse 20 there is a metal plate 21 (Fig. 1 , 3, 4). Between the plate 21 and the traverse 20 is a metal ball 22 (figures 1, 4). Traverses 19, 20 are connected by strands 23 (Figs. 1, 3, 4).

The operation of the device is as follows. First, with the help of a jack 16, a compressive load is applied to the experimental sample 5 (reinforced concrete beam). Then, the experimental sample 5 is aged for approximately ten minutes. After this time, a transverse shock is applied. The shock load is created by the mass of the falling load 11. The force of the impact can be varied by changing the mass of the load 11 and the height of the load. The fastening of the jack 16 is carried out by means of a thrust created by means of supporting traverses 19, 20 from two sides, which are connected by rods - rods 23. After installing all the elements, it is adjusted by nuts - holders 24, which are put on the rods 23. The compressive load is transmitted to the beam at the point using metal balls 17, 22 through metal plates 18, 21, which act as distribution plates. The magnitude of the compressive load is fixed by the pumping station, from which oil is supplied to the jack 16. To obtain data on the stress-strain state of the experimental sample, a set of standard measuring instruments is used. At the time of the detachment of the load, the accelerometer on the load ejector 12 is triggered, the information from which is fed to the measuring complex, which records the accelerogram of the change in the sensor’s accelerations. When the load 11 is struck against the experimental sample 5, the accelerometer 10 is activated, which is under the load meter 7. Information from the accelerometer 10 also arrives at the measuring complex. Then, when processing the results of the readings of the accelerometers, you can determine the time of the load falling of a given mass from a given height by the difference between the readings of the accelerometer 10 and the accelerometer on the load ejector. Knowing the time of the fall of the load and the height of the fall, you can determine the speed of the fall of the load and the acceleration of the load at the time of impact. When the load 11 hits the experimental sample 5, the kinetic energy of the impact passes into the potential energy that is spent on the destruction of the sample. In a reinforced concrete sample in the middle of its design span

maximum bending moment occurs. The beam receives certain movements at individual points. Upon reaching the permissible deflection for a particular design, its destruction occurs. The breaking load is fixed by a force meter 7. The magnitude of the support reactions is fixed by processing the readings of the strain gauges glued to the torque supports. All sensors and devices used in the experiment immediately before the experimental studies are calibrated, as a result of which the dependences of the readings of a specific sensor (device) at each stage of loading on the readings of the measuring system in relative units are obtained. The transition to the necessary absolute units when processing the results of the experiment occurs by multiplying the readings of the system for each sensor (device) by the calibration coefficient obtained during calibration.

Claims (5)

1. A test bench for testing reinforced concrete elements for short-term dynamic bending with compression, comprising a hoist mounted on a power floor with a load ejector, the masts of which are equipped with a load limiter, supports for a reinforced concrete element, a loading beam with a force meter mounted on it, mounted on a reinforced concrete element, supports located on both sides of the machine, on which additional traverses are installed, interconnected by cords, jacks, rollers, lips mounted on supports under a reinforced concrete element, one of which is motionless, the second with the possibility of horizontal movement, and metal plates, characterized in that it additionally contains accelerometers, one of which is mounted on a load ejector, the other on a force meter, strain gauges glued on supports under reinforced concrete element, and metal balls, with metal plates mounted directly at the ends of the reinforced concrete element, metal balls abut against these plates, and the jack is laid between an additional traverse and a metal ball. 2. The stand according to claim 1, characterized in that the supports for additional traverses are configured to adjust their height. 3. The stand according to claim 1, characterized in that the loading beam is installed on the reinforced concrete element through the metal plate, and metal plates are also placed between the reinforced concrete element and the rollers. 4. The stand according to claim 1, characterized in that it is equipped with an insurance system to limit the deflection of a reinforced concrete element, installed at a distance of its maximum allowable deflection. 5. The stand according to claim 1, characterized in that it further comprises damping pads mounted on a load cell.