RU145786U1 - STRENGTH TESTING MATERIAL - Google Patents

Abstract

A device for testing the strength of materials, containing a bed with guide columns, a crosshead, movably mounted on the columns with the possibility of its fixation relative to the bed, a loading plate with a reversible servo drive and a control unit, removable grips for securing the test specimen under tensile load, removable equipment for fixing the test sample under compression load, the load force sensor mounted on the traverse, and the displacement sensor of the actuator actuator connected an information processing unit, characterized in that the device is equipped with a deformation sensor mounted on the test sample and connected to the information processing unit, and the snap-in for securing the test sample under compression load is made in the form of an upper support mounted by means of a flange connection on the lower support traverse, installed using a flange connection on the loading plate and having a concave spherical bearing surface, and spacers with a convex spherical bearing surface, conjugated with PORN lower support surface, wherein the upper bearing and the spacer are provided with carbide inserts, secured rigidly to them to be mounted between the test sample under a load of liners compression.

Description

The utility model relates to testing equipment, namely, to testing the materials for strength and can be used to test titanium disk alloys in the computational simulation of the method of inelastic smoothing of blades of gas turbine engines.

A device for testing the strength of materials is known, comprising a bed with guide columns, a crosshead, movably mounted on the columns with the possibility of its fixation relative to the bed, a load plate with a reversible drive and a control unit, removable grips for securing the test specimen under tensile load, load force sensor mounted on the traverse, and the displacement sensor of the actuator of the servo drive connected to the information processing unit (AS USSR No. 1490557).

The known device provides a reduction in the measurement error of the onset of deformation of the test sample during a single and cyclic tensile loading. However, the functionality of the known device is limited in that it is impossible to carry out compression testing of the prototype.

A device for testing the strength of materials is known, comprising a bed with guide columns, a load beam, movably mounted on the columns and connected with a reversible servo drive and a control unit, removable grips for securing the test specimen under tensile load, and removable snap-in for securing the test specimen under load compression, load force sensor mounted on the traverse and connected to the information processing unit (AS USSR No. 1357766).

In the known device, a removable snap-in for securing the test specimen under compression load is made in the form of a hollow cylindrical support mounted on the bed coaxially to the axis of the passive gripper, and two additional grippers made in the form of glasses mounted on the active gripper body and at the end of the cylindrical support. This performance snap allows you to simplify the operation of the device in hard-to-reach conditions.

However, this embodiment of the device significantly reduces the functionality during tensile and compression tests of the test samples, because Allows you to determine only the fracture force of the test sample without taking characteristics of its deformation under the influence of the load.

Closest to the proposed is a device for testing materials for strength, containing a bed with guide columns, a crosshead, movably mounted on the columns with the possibility of its fixation relative to the bed, a loading plate with a reversible servo drive and a control unit, removable grips for fixing the test specimen under tensile load , a removable snap-in for securing the test sample under compression load, a load force sensor mounted on the traverse, and the displacement sensor will execute Body servo ceiling elements connected to the information processing unit (Russian patent №53444).

In the known device, the removable snap is made in the form of two tables fixed on a bed and a movable traverse, between which a test sample is installed. With this arrangement, rigging for fixing the test specimen under compression load imposes strict requirements on the accuracy of installation of the test specimen in the direction of the load force and the absence of mutual distortions of the supporting surfaces of the tables, since failure to comply with these conditions will lead to a significant distortion of the test results.

In addition, in the known device, the deformation of the test sample during loading is judged only by the displacement sensor of the actuator, which reduces the accuracy of the measurements and does not allow to exclude measurement errors due to deficiencies of the test equipment.

The technical result, the achievement of which is aimed at creating a utility model, is to increase the accuracy of recording test results and obtain reliable data on the deformation of the test sample to build a hardening curve.

The specified technical result in the implementation of the utility model is achieved by the fact that the device for testing the materials for strength, comprising a bed with guide columns, a crosshead movably mounted on the columns with the possibility of its fixation relative to the bed, a load plate with a reversible servo-drive and a control unit, removable grips for fixing test specimen under tensile load, removable equipment for securing the test specimen under compression load, load force sensor installed mounted on the traverse, and the actuator actuator displacement sensor connected to the information processing unit is equipped with a deformation sensor mounted on the test sample and connected to the information processing unit, and the snap-in for securing the test sample under compression load is made in the form of an upper support installed with using a flange connection on the traverse, a lower support installed with a flange connection on the load plate and having a concave spherical bearing surface, and spacers with ukloy spherical support surface mating with the support surface of the lower support, said upper support and spacer is provided with carbide inserts, secured rigidly to them to be mounted between the test sample under a load of liners compression.

Achievement of a technical result - increasing the accuracy of recording test results and obtaining reliable data on the deformation of the test sample in a utility model is carried out by combining all of its distinctive features. Improving the accuracy and reliability of the test results is achieved both by directly measuring the deformation of the sample with a strain gauge installed on the test sample, and by constructively fitting to fix the test sample under compression load, which eliminates measurement errors due to deficiencies of the test equipment by self-installation spacers with the test sample relative to the direction of action of the load force.

The essence of the utility model is illustrated by drawings, where

figure 1 presents a General diagram of a device for testing materials for strength;

figure 2 presents a longitudinal section of a removable tool for fixing the test sample under compression load;

figure 3 is a General view of a removable snap-in to secure the test sample under compression load.

A device for testing the strength of materials contains a frame 1 with four guide columns 2, a crosshead 3, movably mounted on the columns 2 with the possibility of its fixation relative to the frame 1 using clamps 4, and a load plate 5, rigidly connected with a reversing servo drive 6 and a control unit 7 . On the traverse 3 and the load plate 5, removable grippers 8 are mounted to secure the test specimen 9 under tensile load. The device has a load force sensor 10 mounted on the traverse 3, a deformation sensor 11 mounted on the test sample 9, and a displacement sensor 12 of the actuator actuator 6. Sensors 10, 11 and 12 are connected to the information processing unit 13 connected to the control unit 7.

The rigging under compression load is made in the form of an upper support 14 mounted with a flange connection 15 on a crossarm 3, a lower support 16 mounted with a flange connection 17 on a load plate 5 and having a concave spherical bearing surface 18, and spacers 19 with a convex spherical the supporting surface 20, conjugated with the supporting surface 18 of the lower support 16, and the upper support 16 and the spacer 19 are equipped with carbide inserts 21 and 22, rigidly fixed to them with the possibility of installation between the inserts 21 and 22 of the test 23, with the sample being compression load.

The hardness of the liners 21 and 22 should exceed the hardness of the material of the test sample by not less than 5 HRC _{E. The} fastening of the liners 21 and 22 in the upper support 16 and spacer 19 can be carried out by thermal assembly, which significantly reduces the complexity of manufacturing tooling.

The reversing servo drive 6 is made in the form of a hydraulic cylinder 24 with an actuator in the form of a piston with a rod 25, rigidly connected to the load plate 5, and a slide switch 26, the drive of which is connected to the control unit 7. The working cavity of the hydraulic cylinder 24 is hydraulically connected to the source through the slide valve 26 the pressure of the working fluid 27 and the drain cavity 28. A hydraulic drive can be used to move the beam 3.

To conduct temperature tests, the device can be equipped with a removable high-temperature furnace 29, the casing of which serves as a protective shield to ensure safety during testing.

The device operates as follows.

In the tensile test, the traverse 3 moves along the columns 2 to the required position and is fixed motionless relative to the bed 1 using the clamps 4. The test sample 9 from the test material is fixed in the grippers 8, the strain gauge 11 is installed directly on the test sample 9.

When applying pressure to the hydraulic cylinder 24, the load plate 5 creates a tensile load force of the test sample 9, and the signals from the load force sensor 10, the strain sensor 11 and the displacement sensor 12 are sent to the information processing unit 13, from which they are sent to the control unit 7 to form the control the signal for the servo drive 6. The magnitude of the gradually increasing efforts of the tensile load acting on the test sample 9, is set and supported by a change in pressure in the hydraulic cylinder 24 according to the signal of the control unit 7.

The magnitude of the load increases until the destruction of the test sample 9, while at the time of destruction of the test sample 9 by the signal of the load force sensor 10, the control unit 7 turns off the servo drive 6.

Throughout the entire testing process, signals from sensors 10, 11 and 12 synchronously arrive at the information processing unit 13, and the final information about such test parameters as stress, relative deformation of the sample and the curve of deformation of the sample, after computer processing can be presented on the monitor and graphic form.

To carry out a compression test, the installation is retrofitted: the grippers 8 are dismantled, the upper support 14 is mounted using a flange connection 15 on the cross beam 3, the lower support 16 is mounted using a flange connection 17 on the load plate 5, and the spacer 19 is a convex spherical bearing surface 20 mounted on concave spherical bearing surface 18 of the lower support 16.

The test specimen 23 under compression load is fixed between the carbide insert 21 of the upper support 14 and the carbide insert 22 of the spacer 19. The actuator 6 is reversed and when the pressure is applied to the hydraulic cylinder 24, the load plate 5 creates a compressive load on the test specimen 23. Possible deviations of the longitudinal axis of the test sample 23 from the direction of the compression load is compensated by the self-installation of the spacer 19 on the concave spherical bearing surface 18 of the lower bearing 16, therefore, additional operations On checking the coincidence of the longitudinal axis of the test sample 23 with the direction of the compression load is not required.

The compression test process is similar to tensile testing. During the entire testing process, the information processing unit 13 receives signals from sensors 10, 11 and 12, which are used to construct a compression diagram of the prototype based on reliable data on the deformation of the test sample. The final information on such test parameters as stress, relative deformation of the sample and the curve of deformation of the sample after computer processing can be presented on the monitor and in graphical form.

Experimental tests of the installation showed that the compression tests of the samples are carried out under conditions that provide the minimum allowable eccentricity of the load application, which allows to obtain reliable data on the nature of its deformation using the deformation sensor installed directly on the test sample. These conditions are fulfilled by self-aligning the spacers with the test specimen relative to the direction of action of the load force, which prevents possible distortions of the tooling and elimination of the associated bends of the test specimen.

The fastening of the upper support directly to the traverse, and the lower to the load plate allows for high structural rigidity, thereby eliminating the need to take into account the rigidity of the test setup, which also helps to increase the accuracy of the tests.

This implementation of the tool allows you to install the strain gauge directly on the sample, which helps to increase the accuracy of measurements and obtain reliable data on the deformation of the test sample to build a hardening curve.

Claims (1)

A device for testing the strength of materials, containing a bed with guide columns, a crosshead, movably mounted on the columns with the possibility of its fixation relative to the bed, a loading plate with a reversible servo drive and a control unit, removable grips for securing the test specimen under tensile load, removable equipment for fixing the test sample under compression load, the load force sensor mounted on the traverse, and the displacement sensor of the actuator actuator connected an information processing unit, characterized in that the device is equipped with a deformation sensor mounted on the test sample and connected to the information processing unit, and the snap-in for securing the test sample under compression load is made in the form of an upper support mounted by means of a flange connection on the lower support traverse, installed using a flange connection on the loading plate and having a concave spherical bearing surface, and spacers with a convex spherical bearing surface, conjugated with PORN lower support surface, wherein the upper bearing and the spacer are provided with carbide inserts, secured rigidly to them to be mounted between the test sample under a load of liners compression.