RU2522824C2 - Setup for physical and mechanical tests of material samples - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: invention refers to test equipment, to strength tests. Setup includes a bed carrying sample grips and cyclic load device in the form of cog wheel interacting with mobile rack linked to one of the grips, a bar connected by an end to the cog wheel, and load mounted on the other bar end. In addition, the setup includes second rack linked to the second grip, and shock load devices matching the number of shock momentums, each device in the form of cog wheel interacting with the second rack, arm with rotation axis coaxial to the cog wheel and rotating independently, load mounted on the arm, and two rests mounted on the cog wheel and interacting with the arm, the load is located higher than arm rotation axis, the arm is positioned between the rests with a gap, and the rests on each cog wheel are tilted in comparison to the rests of the other cog wheels.

EFFECT: increased information content of material sample tests by superposition of compressing and extending shock momentums on damped load oscillation cycles.

2 cl, 1 dwg

Description

The invention relates to testing equipment, to strength tests.

Known installation for physico-mechanical studies of samples of materials (RF patent No. 1807327, class G01N 3/34, 1993), containing the frame, mounted on it the grips of the sample and the cyclic loading mechanism, made in the form of a gear wheel interacting with a gear rack, installed with the possibility of axial movement and associated with one of the grips, the rod, the end connected to the gear, and the load mounted on the other end of the rod.

The disadvantage of the installation is the lack of the ability to conduct research when applying compressive and tensile shock pulses to cycles of damped load oscillations.

A known installation for physico-mechanical studies of samples of materials (RF patent No. 1672279, CL G01N 3/32, 1991), adopted as a prototype. The installation comprises a bed, sample grips installed on it and a cyclic loading mechanism made in the form of a gear wheel, a gear rack interacting with it, mounted with the possibility of axial movement and connected with one of the grippers, a rod connected to the gear by the end face, and a load installed on the other end of the bar.

The disadvantage of the installation also lies in the lack of the ability to conduct research when applying compressive and tensile shock pulses to cycles of damped load oscillations. This reduces the information content of experimental studies.

The technical result of the invention is to increase the information content of studies of material samples by testing when applying compressive and tensile shock pulses to cycles of damped load oscillations.

The technical result is achieved by the fact that the installation for physicomechanical testing of samples of materials containing a bed, sample grips installed on it and a cyclic loading mechanism made in the form of a gear wheel, a gear rack interacting with it, mounted with the possibility of movement and connected with one of the grippers , the rod end connected to the gear, and the load mounted on the other end of the rod according to the invention has a second gear rack associated with the second capture, and mechanisms load loading in accordance with the number of shock pulses, each of which is made in the form of a gear wheel interacting with the second rack, a lever with an axis of rotation mounted coaxially to the wheel with the possibility of independent rotation, a load mounted on the lever, and two stops mounted on the wheel with the possibility of interaction with the lever, while the load is located above the axis of rotation of the lever, the lever is located with a gap between the stops, and the stops on each wheel are angularly displaced relative to the stops on the other wheels.

The technical result is also achieved by the fact that between the second gripper and the bed is installed an elastic element.

Figure 1 presents the installation diagram.

An apparatus for physicomechanical testing of samples of materials contains a frame 1, grips 2, 3 of sample 4 mounted on it, and a cyclic loading mechanism made in the form of a gear 5, a gear rack 6 interacting with it, mounted for movement and connected with one of the grippers 2, the rod 7, the end connected to the gear 5, and the load 8 mounted on the other end of the rod 7.

The installation has a second gear rack 9 associated with the second grip 3, and shock loading mechanisms in accordance with the number of shock pulses, each of which is made in the form of a gear wheel 10 interacting with the second rack 9, a lever 11 with an axis of rotation 12 mounted coaxially to the wheel 10 with the possibility of independent rotation, the load 13 mounted on the lever 11, and two stops 14, 15 mounted on the wheel with the possibility of interaction with the lever 11. The load 13 is located above the axis 12 of rotation of the lever. The lever 11 is located with a gap between the stops 14, 15. The stops 14, 15 on each wheel 10 are angularly displaced relative to the stops on the other wheels 16.

Between the second gripper 3 and the bed 1, an elastic element 17 is installed. To remove the rod 7 from the equilibrium position, use a winch 18 with a rod 19 and a latch 20. The grips 2, 3 with the sample 4 are moved in the guide 21.

Installation works as follows.

The winch 18 with the rod 19 and the latch 20 remove the rod 7 from the equilibrium position, after which the rod 7 makes damped oscillations under the influence of the load 8 and, by means of the wheel 5, the rod 6 and the gripper 2, loads the sample 4 with damped cyclic loads. The parameters of the cyclic load are set by the stiffness characteristic of the elastic element 17 and the resistance to axial movement of the rod 9.

The rod 9 also performs reciprocating movements, as the rod 6, while turning the wheels 10, 16 of the mechanisms of shock loading. When the wheels 10, 16 are turned, the corresponding stops 14, 15 turn the levers 11, which after moving through vertical positions move with acceleration under the action of the corresponding loads 13, strike the corresponding stops and through the corresponding wheels and rail 9 with the capture 3 create shock pulses on the sample 4. When the lever 11 hits the stop 14, the sample 4 experiences a tensile impulse, and when it hits the stop 15, a compressive impulse. The delay of pulses from different shock mechanisms is set between tests by the angular displacement of the pair of stops 14-15 on the wheel 10 relative to the pair of stops on the wheel 16. The magnitude of the pulses is set by the weight of the loads 13. The asymmetry of the pulses on each mechanism of shock loading is determined by the asymmetric arrangement of the stops relative to the vertical line on each wheel before starting the test.

The installation provides testing samples of materials in new conditions - when applying compressive and tensile shock pulses to cycles of damped load oscillations. This increases the information content of experimental studies of the properties of materials.

Claims (2)

1. Installation for physico-mechanical testing of samples of materials containing a bed, grips mounted on it and a cyclic loading mechanism made in the form of a gear wheel, a gear rack interacting with it, mounted with the possibility of movement and connected with one of the grips, rod, end connected to the gear wheel, and the load mounted on the other end of the rod, characterized in that it has a second gear rack associated with the second capture, and shock loading mechanisms in accordance with breaking of shock pulses, each of which is made in the form of a gear wheel interacting with the second rack, a lever with an axis of rotation mounted coaxially to the wheel with the possibility of independent rotation, a load mounted on the lever, and two stops mounted on the wheel with the possibility of interaction with the lever, wherein the load is located above the axis of rotation of the lever, the lever is located with a gap between the stops, and the stops on each wheel are angularly displaced relative to the stops on the other wheels. 2. Installation according to claim 1, characterized in that between the second grip and the bed is installed an elastic element.