RU2415397C1 - Material fatigue tester - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: proposed fatigue tester comprises housing accommodating gear wheel and two racks articulated therewith, eccentric drive coupled with first rack, two specimen grippes, one arranged on second rack and another supporting inertial weight secured thereon. Note here that second rack is articulated with gear wheel via link with retainers for jointing with gear wheel and housing.

EFFECT: higher validity of test data, minimum time lag and loads.

2 cl, 1 dwg

Description

The invention relates to testing equipment, to strength tests.

A known installation for testing fatigue of samples of materials (RF patent No. 1672283, class G01N 3/34, 1991), comprising a housing, a gear placed therein and two racks kinematically connected to the gear, an eccentric drive associated with the first rack, two grippers for the sample, one of which is mounted on the second rail, and an inertial load secured to the second gripper.

The disadvantage of the installation is that tests are not feasible on it with an adjustable ratio of compressive and tensile loads.

A known installation for testing fatigue of samples of materials (RF patent No. 1769072, class G01N 3/34, 1992), comprising a housing, a gear placed therein and two racks kinematically connected to the gear, an eccentric drive associated with the first rack, two grippers for the sample, one of which is mounted on the second rail, and an inertial load secured to the second gripper.

The technical result of the invention is to increase the reliability of the information obtained by providing tests with minimal inertia in the process of changing loading conditions and load levels.

The technical result is achieved by the fact that the installation for fatigue testing of samples of materials comprises a housing, a gear placed therein and two racks kinematically connected to the gear, an eccentric drive connected to the first rack, two grippers for the sample, one of which is mounted on the second rail, and an inertial load is fixed on the second grip, according to the invention, the second rail is connected to the wheel by means of a link, on which clamps are mounted for connecting to the wheel and to the housing.

The technical result is also achieved by the fact that the latches are made electromagnetic.

The link with two latches allows you to play all the prototype modes, however, this only happens by switching the pair of latches on the wings, without stopping one drive, while in the prototype it is necessary to carry out a combination of actions with turning on and off the four drives. Actions with the prototype require time to accelerate and stop the drives, i.e. the process of changing modes and load ratios is inertial, and the test results are unreliable. The proposed installation is devoid of this drawback, especially when the design of the electromagnetic clamps, which is achieved by the technical result.

The drawing shows the installation diagram.

The fatigue testing apparatus for samples of materials comprises a housing 1, a gear wheel 2 and two racks 3, 4, kinematically connected to the gear wheel 2, an eccentric drive 5 connected to the first rack 3, two grips 6, 7 for the sample 8, one of which 6 is installed on the second rail 4, and the inertial load 9, mounted on the second grip 7.

The second rail 4 is connected to the wheel 2 through the wings 10, on which the latches 11, 12 are installed for connection with the wheel 2 and with the housing 1.

The latches 11, 12 are made electromagnetic.

Installation works as follows.

The drive 5 is turned on and the rack 3 is moved back and forth. To load the sample 8 with alternating axial loads, the latch 12 is connected and the link 10 is connected to the housing 1. The rail 4 moves reciprocally and the inertial load 9 loads the sample 8 with an alternating axial load. For tests with alternating bending, the latch 12 is turned off and the latch 11 is turned on, thereby connecting the link 10 to the wheel 2. The rail 4 makes rotational movements, and the inertial load 9 loads the specimen 8 with an alternating bending. For tests with asymmetric axial cycles, tests are carried out with a fixed inclination of the rail 4. If, with a fixed inclination of the rail 4, the load 9 is higher than the specimen 8, then the compressive load in the cycle is greater than the magnitude of the tensile load, and vice versa, if the load is lower than the specimen, then the tensile load more compressive. Moreover, the difference in effort is greater, the closer the position of the rack 4 to the vertical. Changing the loading conditions and the ratio of loads in cycles occurs with minimal inertia, without stopping the drive, i.e. without slowing down and stopping the load, only by switching the clamps.

The installation increases the reliability of the information obtained by providing tests with minimal inertia in the process of changing loading conditions and load levels.

Claims (2)

1. Installation for testing fatigue of samples of materials, comprising a housing, a gear placed therein and two racks kinematically connected to the gear, an eccentric drive connected to the first rack, two grippers for the sample, one of which is mounted on the second rack, and an inertial load is fixed on the second grip, characterized in that the second rail is connected to the wheel by means of a link, on which clamps are mounted for connecting to the wheel and to the housing. 2. Installation according to claim 1, characterized in that the latches are made electromagnetic.