RU2292030C1 - Device for testing specimen made of shape memory material - Google Patents

Abstract

FIELD: testing engineering.

SUBSTANCE: device comprises housing, member for cyclic heating and cooling the specimen, unit for axial loading, active and passive holder and meter specimen strain. The housing of the twisting loading unit is built in the active holder and rigidly connected with the two-arm lever and head and shank of the active holder. The two-arm lever is made of a pulley and has two guiding members for two ropes. Some of the ends of the ropes are secured to the lever, and the other ends are connected with the weights. Two rolling bearings for the ropes are connected with the housing. The strain meter is made of the casing secured to the housing of the device, and axial and twisting strain meter. The microscope is built in the housing of the deformation meter.

EFFECT: enhanced precision.

3 dwg

Description

The invention relates to the field of testing materials with shape memory under cyclic thermal and mechanical stresses, in particular, to testing machines that can reproduce cyclic heating and cooling on a sample in a temperature range that causes cyclic martensitic transformations of the material structure when the sample material is separately and jointly exposed axial load and torsion load, and carry out measurements under these influences in a reversible sample due to cyclic phase rotations, axial strain and torsional strain.

The special properties of materials with shape memory (Reference publication "Materials with shape memory", edited by V.A. Likhachev, T.1, 1999) find effective application in various branches of technology. It is assumed that in order to improve aerodynamic characteristics, increase the strength, durability, survivability and weight perfection of aircraft structures, materials with shape memory will be used as elements of a “muscle system” that allows you to change the configuration of the structure in terms of its adaptation to flight mode and carry out damping of structural vibrations and reduction of cyclic loads applied to it. However, in order for materials with shape memory to find effective use in aircraft structures, shape memory in the form of reversible deformations must be maintained throughout the life of the aircraft structure. To establish and ensure the stability of reversible deformation values, it is necessary to test samples of materials with shape memory with the repetition of a multiple process of cyclic heating and cooling in them, corresponding to the multiple process of reproducing the martensitic transformation of the structure of these materials under joint loading by tension (compression) and torsion, which is typical for aircraft operating conditions constructions.

A known machine for testing a material sample, comprising a housing, a loading unit, active and passive grips, and a tensile strain gauge of a sample, comprising a flexible thread attached to an active gripper and connected to a drum connected to a force meter (20 t Universal Testing Machine with 10 pulsator vehicle type MUP-20. Manual for the machine. Armavir, 1962, 38 (6)) This machine is designed for testing under the influence of tensile loads on the specimen and does not allow testing when combined with ruzok tension and torsion (FIG. 4).

A known material sample testing machine comprising a housing, an electro-hydraulic loading unit, electro-hydraulic active and passive grips, and a strain gauge in the form of a two-console strain gauge mounted on a sample (1. Solutions for testing aerospace structures MTS. MTS system corporation, www.mts.com 2004. 2. New methods for assessing the resistance of materials to brittle fracture, translated from English under the editorship of academician Yu.N. Rabotnov, M., Mir, 1972 (Fig. 1.42 on p. 80)). With the help of this machine, it is possible to carry out tests and measurements under separate effects on the specimen of tensile (compression) and torsion loads. However, it does not allow testing under the combined effects of tensile (compression) and torsion loads. The design and manufacture of similar machines or their acquisition is associated with high costs of material and financial resources.

A known vertical creep test machine under axial loading together with torsion (AS No. 2152019, IPC G 01 N 3/00), comprising a housing, upper and lower holders and two load nodes, one of which transfers axial load to the sample through the upper holder, and another node, consisting of weights, flexible rods and a disk, transfers the torsion load to the sample through the lower holder. To measure axial and torsional deformations, the displacement sensor of the upper holder and the displacement sensor of the eccentric mounted on the lower holder are used respectively. Since this machine does not provide cyclic heating and cooling of the sample, which are necessary in the case of testing it from a material with shape memory, and accordingly, the reverse movements of the elements of the axial and torsion loading units in each sample are not required to realize reversible deformations in each cycle, then Technical solutions described in this machine may be the source of test errors. The complexity of the design of the machine, the presence of a large number of elements and joints, as well as unaccounted for sliding friction forces in the joints, can lead to a mismatch between the applied samples when reversing movements of the elements of the axial and torsion loading units when they are combined when testing a sample of material with shape memory in this machine torque and the measured reversible twist angle and between the applied axial load and the measured reversible axial deformation. If axial deformation occurs due to the influence of torsion of a sample from a material with shape memory (Strength Problems No. 3, Kiev, Naukova Dumka, 1990, pp. 117-119), if it is tested using this machine, additional errors and ambiguities in the test results may occur. . The disadvantage of the machine is also that the axial and torsional strains of the sample are measured by the displacements of the upper and lower holders, and not on the sample itself. Given the above, this machine cannot be used to test samples of material with shape memory.

A known machine for testing a sample of material with shape memory, comprising a housing, a loading unit, active and passive holders and an axial strain meter, comprising a sensor attached to the sample and connected to an oscilloscope (AS No. 1350576, IPC G 01 N 25/00 ) However, this machine does not allow testing and measurement under the combined effect of axial load and torsion load.

The closest technical solution to the proposed invention is a machine for testing a sample from a material with a shape memory, comprising a housing, a device for cyclic heating and cooling of the sample, an axial loading unit, active and passive holders, and a strain gauge for the sample (US Patent No. 5209568, May 11, 1993 class 374/49). The machine can be used to test a sample from a shape memory material during cyclic heating and cooling and axial loading of a sample and obtain data on measuring axial deformations of the sample. However, due to the lack of a torsion loading unit and torsion strain gauge in this machine, this machine does not allow reproducing the joint action on the specimen during cyclic heating and cooling of the axial load and torsion load and to carry out joint measurements of axial and torsional deformation under these influences

The objective of the invention is the implementation of the possibility of testing a sample of material with shape memory under combined exposure to a sample of cyclic heating and cooling, axial load and torsion load and to carry out joint measurements of axial strain and torsion strain under these influences while ensuring high accuracy of reproduction of these loads and high accuracy strain measurements with such a combined effect.

To solve this problem, using the proposed machine for testing a sample from a material with a shape memory containing a housing, a device for cyclic heating and cooling of the sample, an axial loading unit, active and passive holders and a strain gauge for the sample, the body of the torsion loading unit is integrated into the active holder, rigidly connected to the two-arm lever and to the head of the active holder and connected to the tail of the active holder using a ball joint or tapered roller bearings mounted coaxially to the specimen with the ability to adjust and fix them with nuts on the rear of the active holder and the cover of the torsion loading unit body, said two-arm lever is made in the form of a pulley and has two guides for two cables, one ends of which are fixed to the lever, and to the other weights are suspended at the ends, two rolling bearings for cables are attached to the machine body, each of which is made in the form of a roller mounted on rolling bearings in the support bracket on a fixed axis perpendicular to the direction cable, while the strain gauge is made in the form of a housing attached to the machine body, an axial strain and torsion strain gauge, made in the form of a disk mounted on the sample between the head of the active holder and the device for cyclic heating and cooling of the sample perpendicular to the axial loading direction and in parallel torsion plane, and indicators made in the form of two adjoining scales - a rectangular scale mounted on the meter body parallel to the direction of axial load In the indicated case of the strain gauge, a microscope with the possibility of its movement in different directions relative to the indicator scales is built in the indicated housing and the circular scale printed on the disk.

Figure 1 shows a diagram of the proposed machine for testing a sample with shape memory.

Figure 2 shows a diagram of an active holder with a built-in housing of the torsion loading unit of the sample.

Figure 3 shows a diagram of a meter of axial strain and torsional strain of the sample.

A device 2 for cyclic heating and cooling of sample 3 is attached to the housing or columns 1 of the machine (Fig. 1) and an axial loading unit 4 of the sample 3 is attached. The ends of the sample 3 are fixed in holders 5 and 6, one of which is the active 5 connected to the node 4 axial loading, and the other passive 6 - with the machine body 1 through a screw connection used when setting up the machine at the beginning of the test and to ensure rigid fixation of the passive holder 6 in the machine body 1 during the test. In the active holder 5 is integrated the housing 7 of the torsion loading unit, rigidly connected to the two-arm lever 8 and to the head part 5a (Fig. 2) of the active holder 5 and connected to the tail part 5b of the active holder 5 using a ball joint 9 or using tapered roller bearings 10 mounted coaxially to the specimen with the ability to adjust and fix them with nuts 11 and 12 on the tail portion 5b of the active holder 5 and the cover of the housing 13 of the torsion loading unit. Due to the use of conical rolling bearings 10 in the torsion unit of the torsion loading unit 7, the joint axial load and torsion load are transmitted from the axial loading unit 4 and the two-arm torsion loading lever 8 through the housing 7 to the head part 5a of the active holder 5 and to the sample 3 with the lowest possible coefficient value rolling friction providing a more accurate correspondence between the applied torque and the measured twist angle of sample 3 and between the applied axial load and the reversible crop deformation. The two-shoulder lever 8 is made in the form of a pulley and has two guides for two cables 14, one ends of which are fixed on the lever 8, and weights are suspended at the other ends 15. Two rolling bearings 16 for cables 14 are attached to the machine body 1, each of which is made in in the form of a roller mounted on rolling bearings in a support bracket on a fixed axis perpendicular to the direction of the cable 14. The strain gauge is made in the form of a housing 17 attached to the housing 1 of the machine, a sensor 18 (Fig.3) of axial and torsional deformations made in the form of ska mounted on the sample 3 between the head part 5a of the active holder 5 and the device 2 for cyclic heating and cooling the sample perpendicular to the direction of axial loading and parallel to the torsion plane, and indicators 19 and 20, made in the form of two adjoining scales - a rectangular scale 19 mounted on the meter housing 17 is parallel to the direction of axial loading, and a dial 20 on the disk. In order to achieve high accuracy in measuring axial and torsion strains of sample 3, a microscope 21 is integrated in the housing 17 of the strain gauge with the possibility of its movement in different directions relative to the scales of the indicators 19 and 20.

Testing an appropriately prepared sample from a shape memory material (Semenov V.N., Movchan A.A., Newt Co. Design of a power exciter of torque from an alloy with shape memory. M., Transactions of TsAGI, Issue 2664, 2004, p. 220-230) with the help of the machine is the impact on the sample of cyclic heating and cooling, separate and joint axial loading and torsion loading and joint measurement in these tests of axial and torsional deformation. Under torsion loading, axial deformation of the sample is possible, and under axial loading, torsion deformation of the sample is possible.

When the specimen 3 is subjected only to axial load, the cables 14 are freed from loads 15, the specimen 3 is installed in the device 2 for heating and cooling, the specimen is fixed in the holders 5 and 6, it is loaded using the axial loading unit 4, the specimen is subjected to a cyclic heating process and cooling device 2, in this process the axial deformation of sample 3 is measured using a microscope 21 and a rectangular scale 19, using the edge of the disk 18 as an indicator of axial deformation, and the torsion strain of sample 3 is measured with the microscope 21 and the dial 20, using the edge of the rectangular dial 19 as an indicator of torsion strain.

When sample 3 is exposed only to torsion load, sample 3 is installed in device 2 for heating and cooling, the sample is fixed in holders 5 and 6, loads 15 are suspended on cables 14 and torsion loading of the sample is carried out, the sample is subjected to a cyclic heating and cooling process using device 2 , in this process, the axial deformation of sample 3 is measured using a microscope 21 and a rectangular scale 19, using the edge of the disk 18 as an indicator of axial deformation, and the torsion strain of sample 3 is measured using a microscope 21 and a dial 20 using the edge of the rectangular dial 19 as an indication of torsion strain.

When the axial load and torsion load are applied to the sample 3, the sample 3 is installed in the device 2 for heating and cooling, the sample is fixed in the holders 5 and 6, it is loaded using the axial loading unit 4, loads 15 are suspended on the cables 14 and produced torsion loading of the sample, subjecting the sample to a cyclic heating and cooling process using the device 2, in this process the axial deformation of the sample 3 is measured using a microscope 21 and a rectangular scale 19, using the edge of the disk 18 as a decree ator axial strain and torsional strain of the sample is measured using a microscope 3 and 21, dial 20 using the rectangular edge 19 of the scale as the pointer torsion

Testing of the proposed strain gauge using a built-in microscope showed high accuracy in measuring strain of the sample. An illustration of the assessment of the accuracy of deformations (ε,%) in the case of using a microscope of the MPB-2 type with a sample length of 100 mm located in the zone of cyclic heating and cooling is given in the table.

Table ε,% one 2 3 0.5 0.25 0.2 0.1 0.05 Number of divisions twenty 40 60 10 5 four 2 one microscope scales

To realize this accuracy, it is necessary in the manufacture and fixing of the disk 18 on the sample 3 to ensure the flatness of the disk 18 and its perpendicularity to the axis of the sample 3.

Tests using the proposed machine allow us to study the patterns of behavior of materials with shape memory under cyclic heat and load conditions that mimic the operating conditions of aircraft structures, determine experimental data characterizing shape memory in the form of values of reversible material deformations and establish their stability ranges depending on the number of cycles heating and cooling under separate and combined effects of axial loading and torsion loading. During the tests, it is possible to reproduce certain types of joint effects on the sample, vary the loading, heating and cooling conditions and record deformations, stresses, and temperature. Thus, depending on what parameters are set and the behavior of which parameters is studied, a solution to a large number of combinatorial problems that are important for identifying the properties and behavior of materials with shape memory can be experimentally found.

The application of the described invention can also reduce the cost of testing materials with shape memory, which is achieved due to the fact that there is no need to purchase expensive testing and measuring equipment.

Claims (1)

A machine for testing a sample from a material with a shape memory, comprising a housing, a device for cyclic heating and cooling of the sample, an axial loading unit, active and passive holders and a deformation measuring device, characterized in that the housing of the torsion loading unit is integrated in the active holder and is rigidly connected to a two-arm lever and with the head of the active holder and connected to the tail of the active holder using a ball joint or using tapered roller bearings mounted coaxially with the possibility of adjusting and fixing them with nuts on the rear of the active holder and the cover of the torsion unit, the specified two-arm lever is made in the form of a pulley and has two guides for two cables, one ends of which are fixed to the lever, and loads are suspended at the other ends , two rolling bearings for cables are attached to the machine body, each of which is made in the form of a roller mounted on rolling bearings in the support bracket on a fixed axis perpendicular to the direction of the cable, while measuring l deformations are made in the form of a body attached to the machine body, an axial strain and torsion strain gauge made in the form of a disk mounted on the sample between the head of the active holder and the device for cyclic heating and cooling of the sample perpendicular to the axial loading direction and parallel to the torsion plane, and indicators made in the form of two adjoining scales - one rectangular, mounted on the meter body parallel to the direction of axial loading, and a second circular bar In the indicated case of the strain gauge, a microscope is built-in on the disk, with the possibility of its movement in different directions relative to the indicator scales.

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