EA035220B1 - Device for determining mechanical characteristics of materials subjected to tension - Google Patents

Abstract

The invention relates to the field of experimental mechanics, in particular, to devices for determining mechanical characteristics of materials subjected to tension and can be used in the road and other industries. The device consists of a steel frame that supports a heating chamber is installed, in which heating elements and a fan are mounted, two steel plates designed to fasten a sample of test material to two rods, the upper rod fixed by a hemispherical hinge to the frame has an adjusting nut, the lower rod is pinched by a latch against the frame is movable freely in vertical direction; it also carries a dynamometer, a loading tank with a shutter and a calibrated opening, while two steel plates on two opposite sides at equal distances from the sample axis have dial indicators to measure sample movements recorded by a high-speed video camera; a control sample of test material with two internal temperature sensors attached to its surface is installed in the heating chamber; the sensors are connected to two programmable temperature controllers showing the current temperature; on the outside of the steel frame, a loading tank with a shutter and a calibrated opening is fixed, connected to the loading tank by a pipeline; further, a device for preparing samples for testing, which comprises a base of aluminium channel bar with an aluminium conductor fixed to it and two aluminium conductors sliding freely in the horizontal plane, four permanent magnets mounted in all conductors; the device itself also has two aluminium platforms with three adjusting screws with nuts on each platform, which allows expanding the temperature range of the test from -301°C to +601°C and determining tensile mechanical characteristics of materials for various types of tests: creep at constant load; creep at step loading; cyclic creep; deformation under loading at constant speed.

Description

The invention relates to the field of experimental mechanics, in particular to devices for determining the mechanical characteristics of materials under tension, and can be used in the road and other industries.

A device is known for indirectly determining the tensile strength of asphalt concrete, which is a mechanical or hydraulic press with two plates, the lower of which moves at a speed of 50 ± 2 mm / min (ST RK 1218-2003 Materials based on organic binders for road and airfield construction. Methods Tests, pp. 27-28).

The disadvantages of this device are the indirect determination of tensile strength, as well as the limited type of test.

As a prototype, a device was selected for determining the mechanical characteristics of materials under tension, including a horizontal steel beam, on which a sample of the test material is attached at one end, and the other end of which is pivotally connected to a loading vessel having an opening corresponding to a certain value of the loading speed and two dial indicators for measuring movements. The installation allows testing at a temperature of 20 ± 2 ° C (Bulletin of the Ministry of Science-Academy of Sciences of the Republic of Kazakhstan, 1998, No. 6, pp. 23-25).

The disadvantages of this installation are the limited type of test (creep at constant load) and a narrow temperature range of the test.

The objective of the invention is to develop a device for determining the mechanical characteristics of materials under tension for various types of tests: creep at constant load; creep at step loading; cyclic creep; deformation under loading at a constant speed.

The technical result consists in expanding the temperature range of the test.

The technical result is achieved by a device consisting of a steel frame on which a heat chamber is installed, providing a temperature in the range from -30 ± 1 ° С to + 60 ± 1 ° С, in which two heating elements and two evaporators with fans, two steel plates are mounted designed for fastening the test material sample to two rods, the upper of which is fixed by a hemispherical hinge to the frame and has an adjusting nut. In this case, the lower rod is pinched by the latch relative to the frame and has free vertical movement. In addition, a flexible steel cable and a segment lever with a flexible steel cable, made in the form of a removable attachment, are mounted on the lower rod through the unit, a dynamometer, a loading container with a shutter and a calibrated hole are installed, and on two steel plates from two opposite sides at equal distances two dial gauges are installed from the axis of the sample to measure the movements recorded by a high-speed video camera. A control sample of the test material is installed in the heat chamber with a temperature sensor mounted inside and a temperature sensor attached to its surface. The temperature sensors are connected to programmable thermostats, which are connected to heating elements, a refrigeration unit, evaporators and fans. On the outside of the steel frame, a loading tank with a shutter and a calibrated hole is fixed, which is connected to the loading tank by a pipeline. There is also a device for preparing samples for testing, which is a base of aluminum channel, on which an aluminum fixed conductor and two aluminum conductors with nuts moving in the horizontal plane are mounted. Four permanent magnets are mounted in the conductors. The device also has two aluminum platforms with three adjusting screws on each platform.

Significant differences of the proposed device from the prototype device is that a frame is used as a steel supporting element and additionally it has a heat chamber, in which heating elements and evaporators with fans are mounted, two steel plates designed for attaching a sample of the test material to two rods, the upper of which is fixed by a hinge in the form of a hemisphere to the frame and has an adjusting nut and an adjusting clutch freewheel. In this case, the lower rod is pinched by the latch relative to the frame and has free vertical movement. In addition, a flexible steel cable and a segment lever with a flexible steel cable, made in the form of a removable attachment, are mounted on the lower rod through the unit, a dynamometer is installed, and the heat chamber has two temperature sensors attached inside and on the surface of the control sample connected to programmable temperature controllers, which are associated with heating elements, a refrigeration unit, evaporators and fans. In addition, there is also a device for preparing samples for testing, which is a base of aluminum channel, on which an aluminum fixed conductor and two aluminum conductors movable in the horizontal plane are mounted. Four permanent magnets are mounted in conductors. The device also has two aluminum platforms with three adjusting screws on each platform. Such a combination of structural elements in the inventive device allows, in comparison with the prototype device, to expand the temperature range of the test from -30 ± 1 ° C to + 60 ± 1 ° C and determine the mechanical characteristics of the materials under tensile stress for various types of tests: creep at constant load; creep at step loading; cyclic creep; deformation under loading at a constant speed.

In FIG. 1 presents the inventive device, including a steel frame 1, on which a heat chamber 2 is installed, providing a temperature in the range from -30 ± 1 ° С to + 60 ± 1 ° С, in which heating elements 3, 4 and evaporators 5, 6 with fans are mounted 7, 8, steel plates 9 and 10, intended for fastening a sample of the test material to the rods 11 and 12, the upper of which has a right-hand thread, is fixed through a sleeve 13 to a rod 14 with a left-hand thread and to a hinge 15 in the form of a hemisphere to the frame 1 and has an adjusting nut 16. The lower rod 11 is pinched by the latch 17 relative to the frame 1 and has free vertical movement. To the lower part of the steel frame 1, a removable bracket 18 with a horizontal axis is mounted on which a lever system is installed, including a sector 19, a small block 20, a large block 21. A flexible steel cable 22 is attached to the upper part of the sector 19, connected to a load capacity 23 having the shutter 24 and the calibrated hole 25 by means of a dynamometer 26. The small block 20 is connected to the lower rod 11 by means of a flexible steel cable 27. The load capacitance 23 is balanced by a load 28 connected to the large block 21 of the lever system by a flexible steel cable 29 passing through the block 30, which connected to the steel frame 1 through the bracket 31. On metal plates 9 and 10 on two opposite sides at equal distances from the axis of the sample, two dial gauges 32 are installed to measure the movements recorded by the high-speed video camera 33. A control sample of the test material 34 is installed in the heat chamber 2 mounted inside the temperature sensor 35 and the temperature sensor 36, attached on its surface. Temperature sensors 35 and 36 are connected to programmable temperature controllers 37 and 38, which are connected to heating elements 3, 4, refrigeration unit 39, evaporators 5, 6 with fans 7 and 8.

On the outer side of the steel frame 1, a loading tank 40 with a shutter 41 and a calibrated hole 42 is fixed. The loading of the test material sample is carried out by filling in small one-dimensional bulk material from the tank 40 into the tank 23 through the pipe 43.

In FIG. 2 presents a device that is included as a structural element in the inventive device and is designed to prepare samples for testing. The device is a base of aluminum channel 44, on which an aluminum fixed conductor 45 and two movable aluminum conductors 46 and 47 are movable in a horizontal plane. Four permanent magnets 48 are mounted in the conductors. Two aluminum pads 49 with three 50 adjusting screws on each site. Fixation of the sample of the test material is carried out by moving conductors using nuts 51.

The device operates as follows. Steel samples are glued to the specimen of the test material of established geometric dimensions using the device (Fig. 2) with a special glue and held until fully seized. In this case, the device used allows for the alignment and parallelism of the plates relative to the test sample. Using the adjusting nut 16, the necessary distance between the rods 11 and 12 for this series is approximately set by the height of the test samples. Precise adjustment of the distance is carried out using the clutch 13. The latch 17, the rod 11 is fixed to the steel frame 1. The sample prepared for the test is installed between the rods 11 and 12 by screwing the rods into the steel plates 9 and 10. Using the clutch 13, the free travel relative to the latch 17 is selected. Attach dial gauges 32 to the right and left to the plates 9 and 10 at an equal distance from the axis of the test specimen so that they record linear elongation under tension. The load is controlled by dynamometer 26. By means of heating elements 3 and 4, installed on the right and left in the heat chamber, and programmable temperature controllers 37 and 38, the set temperature in the control sample 34 is achieved and maintained. To lower the temperature in the heat chamber 2 below the ambient temperature, a cold unit 39 is connected. A high-speed video camera 33 is connected and sent through the viewing window of the thermal camera 2 to the dial indicators 32.

Further, depending on the type of test selected, the following procedures are performed.

Example 1. Creep at constant load

In this type of test, the deformation of the sample occurs under the action of a constant load until a given point in time or until the sample is destroyed. The creep process at constant load is as follows. The shutters 24 and 41 are closed in containers 23 and 40. Small one-dimensional bulk material of a given weight is loaded into the tank 40. The latch 17 is removed. The high-speed video camera 33 is turned on and the change in time of elongation of the test sample is recorded. The shutter 41 opens and the test sample is loaded. After loading, the sample under constant load remains until a given point in time or until the sample is destroyed. At the end of the test, the shutter 25 opens and the material pours out.

Example 2. Creep at a step load.

In this type of test, deformation of the test specimen occurs under the influence of loads,

- 2 035220 creating stresses σ _μ σ ₂ in the sample, the value of which is kept constant during the given time intervals At ₁ , At ₂ , ... and increases stepwise after them. The process of step loading is as follows. The shutters 24 and 41 are closed in the tanks 23 and 40. A small one-dimensional bulk material of a given weight, which creates a voltage of σ _{1, is} loaded into the tank 40. The latch 17 is removed. The high-speed video camera 33 is turned on and the change in time of elongation of the test sample is recorded. The shutter 41 opens and the sample is loaded (stress σ _{1 is created} ). Under the influence of stress σ _{1, the} sample remains during the time At ₁ . The shutter 41 is closed. While the sample is under a voltage of σ ₁ , the next portion of a small one-dimensional bulk material of a given weight is loaded into the container 40, which creates a voltage of σ ₂ along with the achieved voltage of σ ₁ . After the time At ₁ expires, the shutter 41 opens and the sample is loaded (stress σ _{2 is created} ). Under the influence of stress σ _{2, the} sample remains during the time At ₂ . Then, in the same manner, subsequent loading and deformation of the sample under constant stresses to a given point in time or until the destruction of the sample. At the end of the test, the shutter 24 opens and material is poured out.

Example 3. Cyclic creep

In this type of test, the deformation of the test sample occurs under the action of constant stresses σ of the same magnitude for a given time At1, between which the sample is in an unloaded state for a given time At2. The cyclic loading process is as follows. The shutter 24 and 41 in the container 23 and 40 closes. A small one-dimensional bulk material of a given weight is loaded into the container 40, creating a voltage σ in the sample. The latch 17 is removed. The high-speed video camera 33 is turned on and the change in time of elongation of the test sample is recorded. The shutter 41 opens and loading of the sample occurs through the calibrated hole 42. After loading is completed, the sample under the action of stress σ remains for a given time At ₁ . Then the shutter 24 opens and the sample is unloaded through the calibrated hole 25. The sample remains in the unloaded state for a predetermined time At2, after which the following cycles of deformation of the sample in the loaded and unloaded states are repeated in the same way for the required number of cycles or until it is destroyed.

Example 4. Deformation under loading at a constant speed

In this type of test, the sample of the test material is deformed continuously to a given point in time or to failure under the influence of stress, the value of which increases with a constant speed. This process is as follows. The shutters 24 and 41 are closed in containers 23 and 40. Small one-dimensional bulk material of a given weight is loaded into the tank 40. The latch 17 is removed. The high-speed video camera 33 is turned on and the change in time of elongation of the test sample is recorded. The shutter 41 opens and the sample is loaded to a predetermined point in time or to its destruction.

The device was manufactured at the Kazakhstan Road Research Institute JSC and is used in the experimental determination of the mechanical characteristics of asphalt concrete.

Claims (3)

1. A device for determining the mechanical characteristics of materials under tension, consisting of a steel supporting element, a loading container with a calibrated hole and two dial indicators for measuring displacements, characterized in that there is additionally a loading capacity, and a frame on which a frame is used a heat chamber is installed, designed to maintain the sample at a constant temperature, and in which heating elements are mounted, and there are two temperature sensors attached to the surface and inside the test sample and connected to two programmable positive temperature thermostats showing the current values, and a temperature sensor connected to a digital programmable thermostat for negative temperatures, in which heating elements are mounted, as well as a refrigeration unit, evaporators with fans, two steel plates, designed to mount a sample of the test material to two m rods, the upper of which is hinged in the form of a hemisphere to the frame and has an adjusting nut and clutch, and the lower rod is pinched by a latch relative to the frame and has free vertical movement, on which a segment lever with blocks, cables and a dynamometer is mounted. 2. The device according to claim 1, characterized in that the loading and loading capacities have shutters. 3. The device according to claim 1, characterized in that two indicators are mounted on steel plates from two opposite sides at equal distances from the axis of the sample.