SU1265529A1 - Device for bending test of plate specimens - Google Patents

Abstract

The invention relates to a testing technique and can be used for testing laminar bending specimens. The purpose of the invention is to provide different bending radii of the sample. The test specimen is placed in a circular recess, made in the center of the elastic square plate, and pressed against its similar elastic square plate. The diameter and depth of the notch, as well as the thickness of the support and pressure plates, are chosen from the condition that the pressure and support plates are more rigid than the rigidity of the test sample and the influence of the sample geometry on its shape is excluded. At least one of the plates is made of a material that is transparent to the radiation emitted during the test on the sample, which also makes it possible to observe it. The corresponding plate tops are kinematically connected by elastic split rings and, using a force driver interconnecting with the plates, bend the sample to a predetermined radius. During the test, the bending radius of the sample is changed until it is destroyed, and the distribution of the properties of the sample material over its cross section is determined. 2 hp f-ly, 2 ill. N5 ate | S co

Description

The invention relates to testing equipment, and in particular to devices for testing plate samples for bending.

The purpose of the invention is the provision of studies of the dynamic properties of the material of the sample by continuously changing the bending radius of the sample.

- In FIG. 1 shows a diagram of the proposed device; in FIG. 2 - the same, top view.

The device comprises a base 1, on which a clip consisting of two parts is mounted: a support made in the form of an elastic square plate 2, and a clamp made in the form of a similar plate 2 of an elastic square plate 3. In the center of the plate 2 is made a circular recess 4, diameter L _K which is selected from the condition

L «.4 ^ -Lo, (1) where L _o - side length of square plates 2 and 3.

The depth d _{t of the} recess 4 and the thicknesses d ₀ and d _n, respectively, of the support plate 2 and the pressure plate 3 are selected from the condition

4d _B ^ do <d _n . (2)

The corresponding vertices of the plates 2 and 3 are kinematically connected to each other with the help of elastic elements made in the form of split rings 5. On the base 1, a power exciter is installed, made, for example, in the form of a screw 6, which interacts with the support plate 2 through a ball placed at its end 7. A load meter is installed on the screw 6, made in the form of a strain gauge 8.

The device operates as follows.

Place the plate sample 9 in the recess 4 of the support plate 2. The thickness of the sample 9 should not be less than the depth d _{B of the} recess 4. Press the sample 9 with the pressure plate 3 to the support plate 2 and connect the tops of the plates 2 and 3 using split elastic rings 5. After that by rotating the screw 6, the plates 2 and 3 are loaded with the sample 9 placed between them to bend to a predetermined radius of curvature, which is determined by the magnitude of the deflection using strain gauges, for example, optical (not shown), and using the strain gauge 8, determine the load zki. In the process of testing, the bending radius of sample 9 is measured until the latter is destroyed, and after destruction, sample 9 remains in the recess 4, which makes it possible to study the distribution of the properties of the material of sample 9 over its cross section during deformation and beyond the ductility limit. Correspondence of the geometric characteristics of plates 2 and 3 to ratios (1) and (2) provides greater rigidity of plates 2 and 3 in comparison with the rigidity of the test sample 9 and excludes the possibility of the geometry of the sample influencing the shape of its bend, and also provides an allowable deviation of <10% from the specified bending radius. When fixing plates 2 and 3 at two opposite vertices, sample 9 is bent along a cylindrical surface, and when fixing at four vertices, along a spherical surface.

When studying the effect of radiation on the plasticity of the material of sample 9, as well as when observing sample 9, at least one of the plates 2 or 3 is made of a material that is transparent to the acting radiation. For example, to observe samples of semiconductor materials in the study of their photoluminescence, plates 2 and 3 are made of quartz.

Claims (3)

This invention relates to a testing technique, namely, devices for testing plate-shaped bending specimens. The purpose of the invention is to provide a study of the dynamic properties of the sample material by continuously changing the bend radius of the sample. - FIG. 1 shows a diagram of the proposed device; in fig. 2 - the same, top view. The device comprises a base 1, on which a holder is installed, consisting of two parts: a support, made in the form of an elastic square plate 2, and a clamping, made in the form of a similar plate 2, an elastic square plate 3. In the center of the plate 2, a circular notch 4, diameter Ljj of which is chosen from the condition, (1 side length of square plates 2 and 3. Depth di, notch 4 and thickness do and dn, respectively, support plate 2 and pressure plate 3 are chosen from the condition 4dB4do dn. The corresponding vertices of plates 2 and 3 are kinematically connected each other with the help of elastic elements made in the form of split rings 5. On the base 1, there is an exciter, made, for example, in the form of a screw 6, which interacts with the support plate 2 through the ball 7 placed at its end 7. On the screw 6 there is a force meter, made in view of the strain gauge 8. The device operates as follows: plate-shaped sample 9 is mixed in the recess 4 of the support plate 2. The sample 9 should not be less than the depth db of the recess 4. The sample 9 is pressed against the pressure plate 3 to the support plate 2 and the vertices are connected plates 2 and 3 using split elastic rings 5. After that, rotating the screw 6 loads plates 2 and 3c with a bend placed between them sample 9 to a given radius of curvature, which is determined by the amount of deflection using means of measuring strain, for example, optical (not shown ), and with the help of a strain gauge 8, the load value is determined. During the test, the bend radius of sample 9 is measured until the latter is destroyed, and after destruction, sample 9 remains in recess 4, which makes it possible to study the distribution of material properties of sample 9 over its cross section during deformation and beyond the plasticity limit. The conformity of the geometric characteristics of plates 2 and 3 of ratios (1) and (2) provides greater rigidity of plates 2 and 3 compared to the rigidity of the test sample 9 and eliminates the possibility of the specimen's geometry on the shape of its bend, and also provides a tolerance of 10 from a given bend radius. When plates 2 and 3 are fastened at two opposite vertices, sample 9 is bent along a cylindrical surface, and at fastening by spherical molding at four peaks of the surface. When studying the effect of radiation on the ductility of the material of sample 9, as well as when observing sample 9, at least one of the plates 2 or 3 is made of a transparent material for the affected radiation. For example, to observe samples of semiconductor materials in the study of their photoluminescence, plates 2 and 3 are made of quartz. Claims 1. A device for testing plate-shaped bending specimens containing a base, a clip mounted thereon, made of two parts, a support and a pressure one, for mixing the test specimen between them, and interacting with an energizer, characterized in dynamic properties by continuously changing the bend radius of the sample, parts of the clip are made in the form of elastic square plates with the side LO, in the center of the support plate there is a circular notch, the diameter LK which is selected from the conditions, the depth of the recess and de thickness do, and dn respectively supporting presser plates and are selected from the conditions 4dB do du, and the corresponding top plate is kinematically coupled by means of resilient elements. 2. A device according to claim 1, characterized in that the elastic elements are made in the form of split rings. 3. The device according to claim 1, characterized in that, in order to study the effect of radiation on the samples and to observe them during the test, at least one of the plates is made of a material transparent to the radiation-affecting material.