RU2799978C1 - Stand for testing for biaxial tension-compression - Google Patents

Abstract

FIELD: testing the mechanical properties of metallic materials.

SUBSTANCE: invention relates to a device for mechanical testing for biaxial tension-compression. The stand comprises a cruciform base, on which a biaxial loading device is installed, comprising four power units located on mutually perpendicular axes, each of which is connected to one of the four grips of the sample, and four tension-compression force sensors. On a cruciform base made of aluminium alloy, four plates are fixed with rods made of austenitic steel located vertically on the base made of aluminium alloy and having through holes in the centre, four power units, consisting of a motor, a gearbox and a lead screw passing through a through hole in the plate. Between the lead screws and grips made of austenitic steel and equipped with adapters with inserts and fingers made of austenitic steel, there are four load cells. The stand is additionally equipped with four linear displacement sensors located in a holder fixed on the base, and four length-adjustable stop rods with cutouts and four length-adjustable stop rods without cutouts passing through them, located between four plates, as well as a U-shaped electromagnet with a magnetizing winding connected to a controlled current source, and a measuring winding connected to a fluxmeter. The outputs of strain gauges, linear displacement sensors and fluxmeter, as well as the inputs of the motor controllers and the controlled current source are connected to the computer, and the sensor signals are processed automatically in accordance with the program embedded in the computer.

EFFECT: high accuracy and reliability of the testing results and expansion of functionality.

1 cl, 2 dwg

Description

The invention relates to the technical field of testing the mechanical properties of metallic materials, in particular to a device for mechanical testing for biaxial tension-compression.

Known machine for testing on biaxial tension, performing a test sample for tension by stretching the sample in four directions along two axes perpendicular to each other, including: the first and second turntables, which are parallel and can rotate relative to each other in a plane; four connecting mechanisms spaced at 90° intervals on a circle about the axis of rotation, so that one ends of the respective elements of the pair of elements are connected to each other with the possibility of rotation, and the other ends of the respective elements of the pair of elements are attached across the first and second turntables; four sample grippers, which are respectively attached to the connecting mechanisms and hold the test sample (patent US 8671771, IPC G01N 3/08, 2014).

However, the disadvantage of the known machine is the possibility of testing only biaxial tension.

A biaxial tensile/compression testing machine is known, comprising a stand, a positive x direction lead screw module, a negative x direction lead screw module, a positive y direction lead screw module, and a negative y direction lead screw module. A positive x lead screw module, a negative x lead screw module, a positive y lead screw module, and a negative y lead screw module are fixedly arranged crosswise on the stand. The arrangement of four leadscrew modules and synchronous control of servomotors provides synchronous control of the movements of two groups of specimen grippers in the axial direction and allows testing for biaxial tension/compression, while the loads along the axes can have different ratios. Using a known machine, biaxial tension/compression of flat specimens, uniaxial tension/compression of specimens in tension can be performed, and tensile tests with variable load can also be performed (application CN 106525585; IPC G01N 3/04, G01N 3/08; 2017).

However, the functionality of the known testing machine is limited only to the study of the strength characteristics of the material without the possibility of studying the physical properties of the material in the process of deformation. In addition, the design does not provide for control of the position of the center of the sample, which may adversely affect the accuracy of the measurement results.

The closest technical solution to the claimed is a stand for static and cyclic testing of cruciform samples, containing a frame on which a biaxial loading device is installed, containing located on mutually perpendicular axes, at an angle of 90 °, four grips for installing a cruciform sample, each of which is associated with a power unit to create a biaxial loading, each of which contains a means of cyclic loading and a means of statistical loading on a cruciform sample, an ultrasonic flaw detector associated with, at least two ultrasonic sensors installed on both sides of the cruciform sample, and a test chamber for placing a cruciform sample, in which various operating conditions are simulated, the frame is made in the form of a square or in the form of a ring, the cyclic loading means is made in the form of a hydropulsator, the static loading means is made in the form of an electromechanical cylinder (patent RU 2735713, IPC G01N 3/02, 2020) (prototype).

However, a disadvantage of the known device is the impossibility of conducting static tests on cruciform samples without a crack-like stress concentrator, since changes in the flaw detector signal are caused by crack growth under the action of cyclic loads. Further, despite the expansion of functionality that ensures the choice of optimal options for the material of sheet metal, welding consumables, welding technology at the design stage, testing at low temperatures or in working environments with different contents of corrosive components, there is no possibility to study the physical properties of the material other than strength ones, in particular, the presence of a large number of ferromagnetic structural elements, leading to distortion of the results of studies of the magnetic properties of the tested objects under the influence of the own magnetic fields of the testing machine. In addition, the design does not provide for control of the position of the center of the sample, which may adversely affect the accuracy of the measurement results.

Thus, the authors were faced with the task of developing a design of a stand for testing biaxial tension-compression, which would provide high accuracy of the results obtained along with the expansion of functionality due to the possibility of studying the magnetic properties of the material under study in the process of elastoplastic deformation.

The problem is solved in the proposed test bench for biaxial tension-compression tests, containing a base on which a biaxial loading device is installed, containing four power blocks located on mutually perpendicular axes, each of which is associated with one of the four grips of the sample, four compression-tension force sensors, characterized in that on a cruciform base made of aluminum alloy, four plates are fixed with the help of rods made of austenitic steel , located vertically on the base, made of aluminum alloy and having through holes in the center, four power units, consisting of a motor, a gearbox and a lead screw passing through a through hole in the plate, and between the lead screws and grippers made of austenitic steel and equipped with adapters with inserts and fingers made of austenitic steel, there are four strain gauges, while it is additionally equipped with four linear displacement sensors located in the holder, fixed on the base, and four length-adjustable stop rods with cutouts and four length-adjustable stop rods without cutouts passing through them, located between four plates, as well as a U-shaped electromagnet with a magnetizing winding connected to a controlled current source, and a measuring winding connected to a fluxmeter, while the outputs of strain gauges of tension/compression forces, linear displacement sensors and fluxmeter are connected to a computer, moreover, the sensor signals are processed automatically in accordance with the program embedded in the computer.

At present, from the patent and scientific and technical literature, the design of the test bench for biaxial tension-compression tests is not known, equipped, in addition to tension-compression force sensors, in particular strain gauges, linear displacement sensors, length-adjustable stop rods with cutouts and four length-adjustable stop rods without cutouts passing through them, as well as a U-shaped electromagnet with a magnetizing winding connected to a controlled current source, and measuring windings oh, associated with a fluxmeter, which in turn is connected to a computer for automatic processing of the results using a program embedded in the computer.

In FIG. 1 and FIG. 2 shows the proposed stand for testing for biaxial tension-compression, which includes a cruciform base (1) made of an aluminum alloy, for example D16T, fixed with rods (2) made of austenitic steel with paramagnetic properties, for example, 08X18H10T, four plates (3) made of an aluminum alloy with paramagnetic properties, for example D16T, and located vertically to the base (1 ), and having through holes in the center, four power blocks, each of which consists of a lead screw (4) and a motor with a gearbox (5), four load cells (6), for example, of a strain-resistive type, each of which is located between the sample grip (7) made of austenitic steel, for example, 08X18H10T, and the lead screw (4), while the grips (7) are equipped with adapters (8) with inserts (9) and fingers (10) for the possibility of installing samples of various sizes, moreover, the grippers (7), adapters (8), liners (9) and fingers (10) are made of austenitic steel, for example, 08X18H10T, four linear displacement sensors (11) installed in the holder (12), four length-adjustable stop rods with cutouts (13) and four adjustable length stop rods without cutouts (14) passing through them to protect power units from transverse loads during the destruction of the sample, as well as a U-shaped electromagnet (15) with a magnetizing winding connected to a controlled current source (16), and a measuring winding connected to a fluxmeter (17), while the outputs of strain gauges (6), linear displacement sensors (11) and fluxmeter (17), as well as the inputs of motor controllers (5) and controlled current source (16) are connected to the computer, and the sensor signals are processed automatically in accordance with the program embedded in the computer.

The work of the proposed stand for testing biaxial tension-compression is as follows. The test sample (18) is fixed in four sample grips (7) attached through strain gauges (6) to the lead screws (4). To fix small-sized samples, four adapters (8) can be additionally used, while in the heads of small-sized samples, grooves for inserts (9) and holes for fingers (10) must be made for a strong connection of the sample with adapters (8). The required plastic deformation or elastic loading of the sample is carried out in manual or automatic modes using four motors (5) connected through gearboxes with lead screws (4). In addition, for the possibility of moving the lead screws in manual mode, handwheels are installed on the axis of the motors (5). Linear displacement sensors (11) fixed in the holder (12) track the movements of four points on the edges of the sample. The operation of these sensors in pairs in the differential mode (algebraic difference mode) allows you to control the movement of the sample center and, if necessary, compensate for this movement by the lead screw (4). After setting the required load or deformation, a U-shaped electromagnet (15) with a magnetizing winding connected to a controlled current source (16) and a measuring winding connected to a fluxmeter (17) is installed in the center of the sample, and the magnetic hysteresis loop of the sample material is measured in a given stress-strain state. After the measurement, the sample (18) is demagnetized using the magnetizing winding of the electromagnet with a current with decreasing amplitude. The signals of strain gauges, linear displacement sensors and fluxmeter are transmitted to the computer and processed automatically in accordance with the program embedded in the computer.

The use of a U-shaped electromagnet as a structural element of the stand, connected to a fluxmeter, which in turn is connected to a computer for automatic processing of the results using a program embedded in the computer, provided that all parts of the stand are made of non-magnetic materials (aluminum alloys and austenitic steel), excludes the influence of the own magnetic fields of the stand parts and allows, in addition to the strength characteristics of the material under study, to determine its magnetic characteristics, establishing a relationship between strength and magnetic characteristics. The additional use of linear displacement sensors allows to increase the accuracy and reliability of test results due to the possibility of determining the displacement of the center of the test sample during the measurement process and compensating for this displacement by the lead screw.

To determine the performance of the design of the proposed stand for testing biaxial tension-compression tests were carried out in laboratory conditions at an ambient temperature of 25°C. The tests were carried out on a cruciform specimen made from a 6 mm sheet of low-carbon steel grade st3. In the center of the sample, a circular area 50 mm in diameter and 4 mm thick was milled, in which the maximum mechanical stresses are localized during testing. The tests were carried out according to the following schemes: 1) elastic uniaxial deformation - loading along one axis ( x ) up to 20 kN with stops every 5 kN; 2) elastic biaxial deformation - loading along the second axis ( y ) up to 20 kN with stops every 5 kN at an effective load of 20 kN along the x axis; 3) plastic biaxial deformation - symmetrical loading with the same loads along the x and y axes from 20 to 50 kN with stops every 5 kN. At each test step, a U-shaped electromagnet with magnetizing and measuring windings was installed in the center of the sample, and by means of a quasi-static change in the current in the magnetizing winding, the magnetic hysteresis loops of the material were measured in different directions (by rotating the attached magnetic device from 0 to 360° in 15° increments). Tests have shown that the test stand allows arbitrary biaxial deformation of the sample and measurement of the magnetic hysteresis loops of the material in the plane stress state. In this case, the largest changes in the parameters of the magnetic hysteresis loop of steel st3 were recorded during asymmetric biaxial deformation.

Thus, the authors propose a test bench for biaxial tension-compression testing, which provides high accuracy and reliability of the results obtained along with the expansion of functionality due to the possibility of studying the magnetic properties of the material under study.

Claims (1)

A stand for testing for biaxial tension-compression, containing a base on which a biaxial loading device is installed, containing four power blocks located on mutually perpendicular axes, each of which is connected to one of the four grips of the sample, four tension-compression force sensors, characterized in that on a cruciform base made of aluminum alloy, fixed with rods made of austenitic steel, four plates located vertically on the base, made of aluminum alloy and having through holes in the center, four power units, consisting of a motor, a gearbox and a lead screw passing through a through hole in the plate, and between the lead screws and grippers made of austenitic steel and equipped with adapters with inserts and fingers made of austenitic steel, there are four load cells, while it is additionally equipped with four linear displacement sensors located in a holder fixed to the base, and four adjusting along the length of the stop rods with cutouts and four length-adjustable stop rods without cutouts passing through them, located between four plates, as well as a U-shaped electromagnet with a magnetizing winding connected to a controlled current source, and a measuring winding connected to a fluxmeter, while the outputs of strain gauges, linear displacement sensors and a fluxmeter, as well as the inputs of motor controllers and a controlled current source are connected to a computer, moreover, the sensor signals are processed automatically in accordance with the program embedded in the computer.