RU2251676C1 - Method and device for tension testing - Google Patents

Abstract

FIELD: testing engineering.

SUBSTANCE: device comprises member of heightened rigidity, system for loading the zone of deformation localization, self-centering grips mounted inside the member and provided with the thread for securing the specimen, and system for gathering and processing information. The device is portable. The method comprises stretching the specimen monotonically with increasing load up to the breaking down. The load is monotonically decreases up to the zero at the moment when the value of specimen deformation coincides with the maximum possible residual deformation of material. The deformation is recorded during stretching, and complete deformation diaphragm is plotted.

EFFECT: enhanced reliability of testing.

2 cl, 3 dwg

Description

Tests of materials with the construction of fully equilibrium strain diagrams are more informative in comparison with standard tests. They give a logically complete idea of the resistance of the material to deformation, fully reflecting the physical processes occurring in it, revealing the reserve of bearing capacity. Tests show that the ultimate state of fracture of a material is determined both by its properties and loading conditions, which is easy to verify by testing samples with different degrees of structural heterogeneity and different lengths. The slope modulus, which determines the steepness of the falling branch of the full deformation diagram, is known to be closely correlated with the crack resistance of the material. Through periodic unloading, one can find a defect in the elastic modulus, which determines the degree of destruction (loosening) of the material, etc.

The invention relates to testing equipment, mainly to static tensile testing of materials over the entire deformation range, and can be used to study the rheologically unstable state of the material (softening zone) under tension.

A known installation for determining the mechanical properties of a material at the softening stage (Mironov V.I., Mikushin V.I., Vladimirov A.P. et al. // Plant. Laboratory, 2001, v. 67, No. 3. - p. 48 -51). It contains fixed and movable platforms, guide rods, fastening rods, an element of increased rigidity of the loading system directly in the sample zone, consisting of two horizontal elastic beams and two vertical rods, inside of which there are self-centering grips with thread for fastening the sample, a hollow duralumin rod or dynamometer DOSM-3-1, pressure screw, worm gear, a strain gauge bridge, a system for collecting and processing information are glued on the lower grip. This installation is the closest in technical essence to the proposed device and is selected as a prototype.

The disadvantages of the known installation include:

1. The use of a device of increased rigidity is possible only together with the installation due to the fact that it is an integral part of the installation, which does not allow the loading with the help of other tensile testing equipment and, especially, compression presses.

2. The bias of the sample due to the non-simultaneous inclusion of parallel rods, making it difficult to ensure uniaxial tension of the sample.

3. A small range of deformations when the rods are engaged due to a small elastic deformation of the rods in the direction of the tensile axis, which does not provide equilibrium deformation of the sample from a sufficiently plastic material.

A known method of testing samples of materials in tension (US Pat. RF No. 4034709 / 25-28, class G 01 N 3/08, publ. 23.02.88, Bull. No. 7), in which the sample is stretched monotonically increasing force until fracture, after reaching on a deformation specimen corresponding to the tensile strength of the material, the force on it is monotonically reduced until it reaches zero at the moment the deformation of the specimen coincides with the maximum possible residual deformation of the material and the deformation is fixed during tension with the construction of a complete deformation diagram

The disadvantages of this method:

1. The need to replace the unloading mechanism when testing samples of various materials, because otherwise, the construction of a complete deformation diagram will not be possible due to the mismatch of the rigidity of the unloading mechanism with the characteristics: deformation corresponding to the tensile strength of the material; maximum total force per sample; maximum possible residual deformation of the material.

2. Deformation in the softening zone occurs by a monotonously decreasing load, due to which the standard sample can fail at any time, because To construct a complete strain diagram, the tensile stress of the sample in the softening zone should be quasistatic (infinitely slow).

3. It is required to create a large tensile force in the loading system due to the use of standard samples and an additional unloading mechanism, which does not allow the use of less powerful and dimensional test installations and presses during testing.

The proposed inventions solve the problem: studying the fracture process by ensuring the equilibrium deformation of the material in the zone of rheological instability (softening) in a simpler way than the known one. The following technical result is achieved: the construction of a complete deformation diagram using a rigid system of loading the strain localization zone.

To obtain such a technical result in the proposed device for testing samples of materials in tension, containing an element of increased rigidity of the loading system of the deformation localization zone, inside which are located self-centering grips with a thread for attaching the sample, an information collection and processing system that contains a message, an element of increased system stiffness loading is made in the form of a ring made of spring steel installed between the stops on the grips (inside and outside), while device is portable.

Distinctive features of the proposed device is that the information collection and processing system contains a message, and the element of increased rigidity of the loading system is made in the form of a ring made of spring steel installed between the stops on the grips (inside and outside), while the device is portable.

This greatly simplifies the design, because there is no original installation for loading the sample; it creates the ability to perform loading using any tensile testing equipment, as well as compression presses. The element of increased rigidity of the sample loading system is made in the form of a ring made of spring steel, which ensures uniaxial tension of the sample and leads to an increase in the quality of tests and a decrease in the complexity of manufacturing, as well as during testing. The range of deformations in the direction of the tensile axis increases due to the use of an element of increased stiffness in the form of a ring made of spring steel, which ensures equilibrium deformation of the sample from a sufficiently plastic material.

To achieve the named technical result, a method for tensile testing of samples of materials is proposed, which, like the closest known one, involves the fact that the sample is stretched monotonically with increasing force until fracture, the force is monotonically reduced until it reaches zero at the moment when the strain value of the sample coincides with the maximum possible residual deformation of the material and fix the deformation in the process of stretching with the construction of a full deformation diagram, but the construction of a full deformation diagram it is carried out using a device that increases the rigidity of the loading system of the deformation localization zone, in which, from the moment of the onset of tension, the sample is quasistatically deformed and the tensile stress on it decreases.

Distinctive features of the proposed method is that the construction of a complete deformation diagram is carried out using a device that increases the rigidity of the loading system of the deformation localization zone, in which quasistatic deformation of the specimen and the tensile stress on it are reduced from the moment of tension.

This ensures stable quasistatic deformation of samples from various materials with the construction of a complete deformation diagram due to the sufficiently high stiffness of the element of increased rigidity of the loading system of the deformation localization zone. A small tensile force is created in the loading system due to the use of single microsamples, which leads to the use of less powerful and dimensional tensile testing equipment, as well as compression presses.

The invention is illustrated by drawings, which depict:

figure 1 - a device for testing samples of materials in tension using test equipment in tension;

figure 2 - a device for testing samples of materials in tension using presses operating in compression;

figure 3 is a tensile test method.

The device consists of self-centering cylindrical grips (figure 1) pos. 1, 2, into which a single microsample pos.3 is screwed. Captures Pos. 1, 2 are located inside the ring pos.4, made of spring steel, on one of the grips there is a mass dose pos. 5 for measuring the force on the sample, pre-pressed with a nut pos.6 to the shoulder of pos.7 of a cylindrical grip. The washer pos. 8 is installed on the grip pos. 2 and is tightened by the nut pos. 9. In the first version (Fig. 1), the device has grips pos. 10, 11 for a tensile testing machine, fixed with grips for fastening the sample with pins pos. 12. The elongation of the sample is measured with a fork type strain gauge. When conducting tests on the press captures pos. 10, 11 are removed, at the ends of the grips pos. 1, 2 for fastening the sample, the nuts pos. 13, 14 (figure 2) with washers pos. 15, 16.

The principle of operation of the ring loading device is as follows.

In the first embodiment, when applying a tensile force Q through the grips pos. 10, 11 (Fig. 1), the ring is deformed, item 4, and in parallel with it, the sample item 3. When stretched, the pre-pressed mass dose pos.5 fixes, using special equipment, a change in the tensile force applied to the sample. In the second embodiment, the tests are carried out on the press by applying a compressive force P to the elastic ring pos.4 (figure 2) perpendicular to the direction of tension of the sample. Otherwise, the principle of operation and the data measurement system are the same as in the first embodiment.

The proposed method of testing samples of materials in tension is as follows.

For a more stable course of quasistatic deformation of the specimen with the construction of a complete deformation diagram, as well as an increase in stiffness and the creation of small tensile forces in the loading system, the construction of a full deformation diagram should be carried out using a device that increases the rigidity of the loading system of the deformation localization zone, in which, from the moment the tensile stress begins quasistatic deformation of the sample occurs and the tensile force on it decreases.

Example. It is required to study the fracture process by equilibrium deformation of the material (according to the proposed device) in the rheological instability zone. If the sample is stretched by a monotonically increasing force until fracture and the deformations are fixed during tension, after reaching the strain corresponding to the tensile strength of the material on the sample, the force on it is monotonically reduced until it reaches zero at the moment the strain of the sample coincides with the maximum possible residual deformation of the material, then to achieve result need for tabular data or the standard test material to determine: deformation corresponding Δl _u tensile strength material, poppy imalnoe total force on the sample Δl _r, the maximum possible permanent deformation of the material F _max; choose the rigidity of the unloading mechanism, stretch the standard sample with a monotonically increasing force, after reaching the deformation Δl _u (and, accordingly, the force F _max ), the unloading mechanism is included in the work, which creates a force S in the sample, which monotonically increases with further deformation of the sample, and the total the force F per sample decreases, because F = QS. At the moment the strain Δl _r is reached on the specimen, the specimen breaks down, and the force F on it decreases to zero. Based on the data obtained, a complete stress – strain diagram is constructed up to its complete destruction.

According to the proposed method, the construction of a complete deformation diagram should be carried out using a device that increases the rigidity of the loading system of the deformation localization zone, in which quasistatic deformation of the specimen takes place from the moment of tension beginning and the tensile stress on it decreases, i.e. a stable course of quasistatic deformation of the sample is ensured with the construction of a complete deformation diagram, and the rigidity of the loading system also increases.

From the foregoing, it follows that the problem of studying the fracture process by ensuring the equilibrium deformation of the material in the zone of rheological instability (softening) is solved. At the same time, the design of the device was greatly simplified, the quality of tests improved and the complexity of manufacturing decreased, and during testing equilibrium deformation of the sample from a sufficiently plastic material is ensured, therefore, there is the possibility of studying the fracture process and equilibrium deformation of the sample in the rheological instability zone is ensured.

The proposed invention is simple, reliable, economical, suitable for widespread use in testing equipment.

Claims (2)

1. A device for testing samples of materials in tension, containing an element of increased rigidity of the loading system of the localization zone of deformation, inside which are located self-centering grips with threads for mounting the sample, a system for collecting and processing information, characterized in that the system for collecting and processing information contains a message, and the element of increased rigidity of the loading system is made in the form of a ring made of spring steel installed between the stops on the grips (inside and outside the ring), while device is portable. 2. The method of tensile testing of samples of materials, namely, that the sample is stretched monotonically with increasing force until fracture, the force is monotonically reduced until it reaches zero at the moment the strain value of the specimen coincides with the maximum possible residual deformation of the material and the strain is fixed during stretching with the construction of a complete diagram deformation, characterized in that the construction of a complete deformation diagram is carried out using a device that increases the rigidity of the zone loading system localization of deformation, in which, from the moment of the onset of stretching, quasistatic deformation of the specimen takes place and the tensile force on it decreases, providing equilibrium deformation of the specimen at the softening stage, and the pre-pressed mass dose in the information collection and processing system, stretching, fixes the change in the tensile force applied to the specimen.

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