RU2624595C1 - Device for fatigue testing samples - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: device includes a base, a passive sample gripper mounted on the base, an active sample gripping, with one end associated with the active gripper and a coaxial aligned lever, an electromagnetic oscillator and a measuring device, a latch designed to periodically link the lever to the base, grippers adapted to fixedly rotate around its axis, the link between the lever and the active gripper is made in the form of a detachable connection, and the exciter and the measuring device are made in the form of two U-shaped magnetic systems fixed at the other end of the lever, one symmetrically different with respect to its axis and two coils fixed to the base, each of which is designed to interact with the corresponding U-shaped magnetic system. The device is equipped with an induction heating unit, the coil of which is located along the perimeter of the test sample and fixed to the base.

EFFECT: increasing the reliability of the test results by eliminating the influence of hardening, when fatigue testing the samples.

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Description

The invention relates to test equipment, and in particular to installations for testing fatigue.

Known methods for testing samples of materials are most fully described in fundamental monographs (see Shkolnik L. M. The rate of crack growth and survivability of metal. - M .: Metallurgy, 1973. - 216 p .; Shkolnik L. M. Method of fatigue tests. Handbook. M .: Metallurgy, 1978.- 304 p.).

The application of a particular method is determined by the purpose of the study of the samples. For fatigue tests, various types of loading of the sample are provided, then its properties are studied, for example, the position and dimensions of microcracks. The number of loading cycles of the sample determines its full service life.

The decisive factor in testing samples for fatigue is the mechanism of microcrack development for various materials. However, the known installations for testing materials for fatigue do not allow observing the development of microcracks during the tests without dismantling the sample. Their distinctive feature is the presence of complex kinematic chains, which leads to a decrease in the durability of the installations. The mechanism of accumulation of fatigue damage is very complex. For example, a factor of increasing the frequency of cyclic loading. Plastic deformation is delayed relative to the applied loading. The longer the duration of the maximum stresses, the more intensive are the hardening processes. For example, in tests with a frequency of 40 cycles / min, the metal acquires its maximum hardness even up to 40 loads, whereas at 2400 cycles / min this requires 100 times more loads, i.e. 4000 cycles. Moreover, in the first case, the degree of hardening of the alloy is 1.5 times greater than in the second, under the same conditions of maximum cycle stresses (see Shkolnik LM Methodology of fatigue tests. Handbook. M: Metallurgy, 1978, p. 113) . It is ambiguous to determine the number of loading cycles at the same value of the increase in hardness due to the influence of hardening, which leads to the uncertainty of the fatigue damage of the samples to fatigue. This is also characteristic when testing samples with cantilever bending with rotation, where the deflections of the samples ambiguously determine the number of loading cycles due to the influence of hardening.

A known installation for fatigue testing of samples of materials (see Installation for fatigue testing of samples of materials: patent for invention 2051359 of the Russian Federation: IPC G01N 3/32 / Lodus E.V. - No. 5003492/28; decl. 09/26/1991; publ. 12/27/1995.), Comprising a housing, two racks located mutually perpendicular to it, a gear wheel interacting with them, a reciprocating movement mechanism interacting with the end of one of the rails, a passive sample holder attached to the end of the second rack, and active inertial load grip Achen for connection with a sample, it is provided with an additional rack mounted parallel to the second rail, an additional toothed wheel cooperating with the main gear and the additional rail, and further active capture inertial load, intended to be connected with an additional sample, and the main inertial load.

The installation allows fatigue testing of two samples.

Samples of the material are fixed on the passive grips belonging to the ends of the two rails, and the active grippers are connected to inertial loads. These two rails are paired with a double link, due to which passive captures receive oncoming movement. The axial movement of the rails is provided from the drive through the reciprocating mechanism, an additional rail and two mating gears.

However, this setup does not allow obtaining information about the current state of material samples, and the mechanical type of loading is associated with its increased wear, which affects the test mode.

A known installation for testing samples of material for fatigue (see Installation for testing samples of materials for fatigue: Pat. For invention 2029281 of the Russian Federation: IPC G01N 3/32 / applicant and patentee Vlasov V.P. - No. 5040478/28; 04/29/1992; publ. 02/20/1995), containing a base, coaxial grips of the sample, a loading device made in the form of a crank-creep mechanism mounted on the basis of a crank, an adjustable length connecting rod connected to a crank-creep mechanism slider mounted on the guide cylinder base A hole in which the slider is located, and a power spring is placed in the guide cylinder, one end in contact with the slider, and the other connected to one of the grippers, and the drive connected to the crank-creep mechanism is equipped with a piston located in the guide cylinder, one end of which is fixed to capture, and the other is in contact with the power spring, and two additional loading devices, each of which is made in the form of a crank-creep mechanism connected to the drive with the direction fixed on the base a sliding slider connected to the last connecting rod of adjustable length, fixed on the base of the blocks with a flexible rod covering them, one end of which is connected to a slider, a power spring connected to the other end of the flexible rod, and a lever connected to the spring, the end of which is fixed to the grip, on which the piston is fixed, the cranks of the mechanisms of the loading devices are mounted coaxially with each other, the levers are located on opposite sides of the grippers, and the other gripper is fixed on the base and provides simultaneously tensile deformation Nia-compression and torsion of the sample.

A sample of material is fixed in the passive grip on the basis of the installation and in the active grip mounted on the two-arm lever. One kinematic chain from the drive through the crank mechanism and a slider with a spring creates an axial load on the sample, two other kinematic chains, in which there are additional flexible rods thrown across the blocks, provide a couple of forces at the ends of the lever with an active grip, creating a torsion strain of the sample.

This installation has the same drawbacks as the previous one: lack of information about the current state of material samples; design complexity; influence on the test mode of clearances and wear in the kinematic chains of the loading device.

A known installation for testing materials for fatigue (see Installation for testing materials for fatigue: Pat. For invention 2373512 of the Russian Federation: IPC G01N 3/32 / Lodus EV, patent holder State educational institution of higher professional education "St. Petersburg State Mining Institute named after G.V. Plekhanov (Technical University) ”(RU) - No. 2008138480/28; claimed. September 26, 2008; published on November 20, 2009) containing a base, three disks placed on it in a row, the middle of which is intended for placing on it an annular mod ztsa and mounted on the base, a lining in the form of a flexible element designed to contact the outer surface of the sample and covering the two extreme disks, disk rotation drives and a platform with a movement drive, characterized in that the two extreme disks are mounted on the platform, a vessel for surfactant, and the platform is made with partial immersion of the extreme disks in the vessel.

The apparatus is designed to test ring samples under conditions of interaction with a surfactant.

The loading device of this installation contains the drives of two disks connected by a flexible element, which interacts with the surface of the annular sample mounted on the base, bringing it into rotation. The disks are mounted on a platform that has its own drive with an eccentric. The swinging platform allows the flexible element to interact with the surfactant poured into the vessel under the discs.

This loading device is also quite complicated, contains three drives. Information on the test results can only be obtained after analysis of the sample. The installation under consideration has a narrow range of sample sizes — only ring samples.

The closest in technical essence of the known is the installation for testing samples for fatigue (see Installation for testing samples for fatigue: ed. Certificate. 1755110 USSR: IPC G01N 3/38 / Ivanov GP, Elgaev N.A., Utkin A.V., applicant, Vladimir Polytechnic Institute - No. 4692360/28; claimed 05.22.1989; publ. 08.15.1992, bull. No. 30), which contains a base, passive sample capture, installed on the base, active sample capture, one the end connected with the active capture and installed coaxially to the lever, the electromagnetic exciter and a measuring device, a latch intended for periodic connection of the lever with the base, the grippers are mounted with the possibility of a fixed rotation around its axis, the connection of the lever with the active gripper is made in the form of a detachable connection, and the exciter and the measuring device are made in the form of two U-shaped magnetic systems mounted on the other end of the lever symmetrically relative to each other relative to its axis and two coils mounted on the base, each of which is designed for interaction actions with the corresponding U-shaped magnetic system.

Thus, this device and all known installations for fatigue tests do not allow to eliminate the influence of hardening on the change in stiffness of the sample during fatigue loading.

The technical result of the invention is to increase the reliability of the test results by eliminating the influence of hardening when testing samples on fatigue.

This goal is achieved by the fact that the installation for testing samples for fatigue, containing the base, a passive grip of the sample, installed on the base, an active grip of the sample, one end connected to the active grip and mounted coaxially with the lever, an electromagnetic oscillator and a measuring device, a latch, made with the possibility of periodic connection of the lever with the base, the grippers are installed with the possibility of a fixed rotation around its axis, the connection of the lever with the active gripper a detachable connection, and the exciter and the measuring device are made in the form of two U-shaped magnetic systems mounted on the other end of the lever one symmetrically to the other relative to its axis and two coils fixed on the base, each of which is made with the possibility of interaction with the corresponding П- shaped magnetic system, equipped with an induction heating device, the coil of which is located around the perimeter of the test sample and is fixed on the base.

An example of the implementation of the proposed device is shown in the drawing of the structural diagram of the installation for testing samples for fatigue.

The device comprises a base 1, a passive grip 2 of sample 3, mounted on the base, an active grip 4 of the sample, one end connected to the active grip and mounted coaxially to the lever 5, an electromagnetic exciter of oscillations 8 and a measuring device 9, a latch 12, designed for periodic connection of the lever with the base, the grips are installed with the possibility of a fixed rotation around its axis, the link of the lever with the active gripper is made in the form of a detachable connection, and the exciter of oscillations and a measuring device They are made in the form of two U-shaped magnetic systems 7 and 10, mounted on the other end of the lever symmetrically relative to each other relative to its axis, two coils 6 and 11, mounted on the base, each of which is designed to interact with the corresponding U-shaped magnetic system , shelf 13, rotary table 16, induction heating device 15, the coil 14 of which is located around the perimeter of the test sample and is mounted on the base.

The installation for testing samples for fatigue is as follows.

The test sample 3 is fixed at one end to a passive grip 2, and at the other end to an active grip 4 mounted on the lever 5, the lever is fixed by the latch 12 located on the shelf 13, while the rotary table 16 is set to zero, release the lever from the latch and the vibration exciter is turned on 8. As a result of the interaction of the current flowing through the coil 6 and the magnetic field of the U-shaped simply connected magnetic system 7, the sample performs a given number of bending vibrations. The induction heating device 15 with the coil 14 is turned on and the hardening is removed. Heating is carried out above the temperature of recrystallization annealing (T _rivers ) _. The heating temperature depends on the type of material and is determined by the formula T _rivers = α × T _melt. , where α is a coefficient depending on the type of material, and T _melt. - melting temperature in degrees Kelvin. Then, fatigue damage is evaluated in various longitudinal planes of the sample, starting from the loading position of the sample, then the lever is fixed with a latch and the sample is released from the active grip. The sample is rotated using the turntable at a certain angle, after which the upper end of the test sample is fixed, the lever is released and fatigue damage is estimated according to information about the oscillation process, which comes from coil 11 to measuring device 9. Then the process is repeated until damage to the specimen in different longitudinal planes will not be evaluated. After setting the sample to its initial position, the next cyclic loading and subsequent assessment of the anisotropy of the fatigue damage are carried out.

The proposed installation allows to eliminate the influence of hardening on the measurement of fatigue damage of the material.

Claims (1)

An installation for testing samples for fatigue, comprising a base, a passive grip of the sample mounted on the base, an active grip of the sample, one end connected to the active grip and coaxially mounted lever, an electromagnetic exciter of oscillations and a measuring device, a latch made with the possibility of periodic connection of the lever with the base, the grips are installed with the possibility of a fixed rotation around its axis, the link of the lever with the active gripper is made in the form of a detachable connection, and excite the oscillation tree and the measuring device are made in the form of two U-shaped magnetic systems fixed on the other end of the lever one symmetrically to the other with respect to its axis and two coils fixed on the base, each of which is configured to interact with the corresponding U-shaped magnetic system, characterized the fact that it is equipped with an induction heating device, the coil of which is located around the perimeter of the test sample and is fixed on the base.

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