SU1675741A1 - Unit for friction tests of materials - Google Patents

Abstract

The invention relates to a test apparatus, in particular to installations for testing friction. The purpose of the invention is to expand the functionality by providing tests at both constant and alternating efforts to preload the sample and counter piece after 2 .16 1 -t cyclic shock preload with damped amplitude. The installation contains the pickup 2 of the contra-edge 3, the mechanism for moving this gripping device, the gripping device 6 of sample 7, the lifting mechanism and the resetting mechanism of gripping 6. For testing with varying pressing after the shock interactions decay, the installation is equipped with a pressing mechanism of the elastic element 11. The actuator 5 is turned on and the counterpiece is moved 3 until the contacts 19, 20 are closed. A latch 18 is activated, and the elastic element 11 moves the sample 7 before contact with the counter piece 3 in collisions with a damped load amplitude. Then the elastic element 11 presses the sample 7 to the counterpiece 3 with the increasing force due to the pressing of the pusher 12. Use when testing various samples and products. I il. u W ON 2

Description

The invention relates to testing equipment and can be used in testing materials for friction.

The aim of the invention is to expand the functionality by providing tests with both constant and variable force preload of the sample and counter-sample after cyclic shock preload with damping amplitude.

The drawing shows a diagram of the proposed installation, General, ith view.

The installation contains a base 1, a counter-sample capture 3 mounted on it, a counter-sample capture movement mechanism made in the form of a gear rack 4 with a drive 5 for its reciprocating movement in a plane parallel to the base, a sample capture 6, a sample lifting mechanism 7 and a lifting mechanism, including a gear wheel 8, a flexible rod 9 connected to it, fixed at its end A load 10 connected to a gripper 6 of a sample 7, an elastic element 11, one end of which is connected with a gripper 6, and the other with a pusher 12, which in turn hard connected to the second gear rack 13, located perpendicular to the first and installed with the possibility of reciprocating movement.

Wheel 8 engages with both racks 4 and 13.

The drive 5 is made cyclic and consists of an eccentric roller 14, a frame 15 and a platform 16. The connection of the rod 9 with the gear 8 is carried out using the drum 17.

The installation also contains a latch 18 of the initial position of the capture 6. The latch 18 is made electromagnetic and is activated when the contacts 19, 20 are closed.

Installation works as follows.

The drive is turned on and the eccentric roller 14 is driven into rotation. The frame 15, together with the platform 16, makes reciprocating movements. When the site moves to the right (according to the drawing), the rail 4 turns the wheel 8 with the drum 17, the rod 9 sags. The wheel 8 moves the rail 13 with the pusher 12, and the pusher deforms the elastic element 11. At the moment of contact closure of the contacts 19 and 20, the latch 18 is turned off and the gripper 6 with the sample 7 moves in the direction of counter-pattern 3 and shock loads it. After the impact, the gripper 6 under the action of the elastic element 11 rises again and inflicts a second blow of lesser force. A series of shock loading occurs with a damping load amplitude. At the same time, the movement of the pusher 12 continues and the deformation of the elastic element 11 is additionally performed. At the moment the shock loads decay, the sample 7 remains pressed against the counter-sample 3, and the compressive force gradually increases as the gripper 2 moves. When the counter-sample 3 moves backward, the pusher 12 becomes inverse, the compressive force reduced to zero, the drum 17 through the rod 9 raises the grab 6 to its original position before interacting with the latch 18. This completes the loading cycle.

If the rail 13 is removed from the interaction with the wheel 8, then the tests are carried out with constant deformation of the elastic element 11, and after the attenuation of shock cycles, the mutual movement of the sample and the counter-sample occurs with constant mutual compression.

Using the setup allows you to perform tests with a new mode of interaction during friction - with a variable compression load after attenuation of shock interactions, as well as with known modes - with constant compression loads at the same stage of testing. This allows us to study the interaction with displacement in a wider range of conditions and apply the results obtained in practical estimates of the process parameters during friction under similar real conditions.

Claims (1)

Claim Installation for testing materials for friction, containing a base, grips of a sample and a counter sample installed on it, a mechanism for moving a gripper of a counter sample and a mechanism for lifting and resetting a gripper of a sample, including a wheel, associated flexible rod, a load fixed to its end, and an elastic element at one end associated with the capture of the sample, characterized in that, in order to expand the functionality by providing tests with both constant and variable force preload of the sample and counter-sample after cyclic of the shock preload with a damping amplitude, the mechanism for moving the grip of the counter sample is made in the form of a gear rack with a drive of its reciprocating movement in a plane parallel to the base, the installation is equipped with a second gear rack located perpendicular to the first with the possibility of reciprocating movement, and rigidly connected to it by a pusher, connected with the second end of the elastic element, the wheel is gear-shaped and engages with both rails, and the load is rigidly connected with the capture of the sample.