RU2758034C1 - Arcuate test device - Google Patents

Abstract

FIELD: testing equipment.

SUBSTANCE: invention relates to testing equipment and can be used to determine the strength of materials on arcuate specimens, in particular for tensile and rupture tests of cut fragments of thin-walled pipes, as well as arcuate specimens cut from the rim of a car wheel in order to obtain a diagram of the deformation of their material under tension. A test device of an arcuate specimen is declared, containing two fragments of a guide with a bearing, mechanisms for fastening an arcuate specimen, grips connected to the rod of the loading device. Additionally, a clamping sleeve mounted on the fork was introduced, an adjusting nut mounted on the threaded part of the fork. Longitudinal horizontal grooves are made in the grippers with holders installed in them, while the holders are equipped with cheeks for stretching the arcuate sample, a removable clamp. A rectangular groove is made in the clamping sleeve, and corrugations are made on the supporting surfaces of the cheeks and clamps. The rods have a zigzag shape and are fixed on the carriages through the axle and the nut with the formation of a gap between the nut and the rod. In this case, a thread is made on the rod end, an angular opening limiter is additionally installed on the grip of a guide fragment, and counterweights are installed on the angular opening limiter, made with the possibility of moving along threaded rods installed in the threaded holes.

EFFECT: increasing the versatility of the application (testing arcuate specimens of different radius of curvature), increasing the measurement accuracy.

1 cl, 6 dwg

Description

The invention relates to testing equipment and can be used to determine the strength of materials on arcuate specimens, in particular, to tensile and rupture tests of cut fragments of thin-walled pipes, as well as arcuate specimens cut from the rim of a car wheel in order to obtain a diagram of the deformation of their material under tension.

In many areas of industry and technology, knowledge of the elastoplastic properties of the material of structures of cylindrical, arched shapes, from which cutting of standard samples for tension is difficult or impossible, is required. To determine the elastoplastic properties of materials of such structures, devices are usually used that provide uniaxial tension of samples along a circular (curved) guide.

A device is known that allows create uniaxial tension during tests cut from the shells of arcuate specimens (patent RU 2402009 with priority from 02.09.2009). For this, circular arched samples are installed on a compound circular guide, consisting of two fragments. Fragments of the circular guide provide the possibility of relative rotation around a common axis, which creates a stress-strain state in the sample, which is almost identical to uniaxial tension. This device provides high-quality results at small radius of curvature of the samples. At large radii of the test specimen, it will have a very large offset from the tensile testing machine, the design does not imply versatility and is intended for testing an arcuate specimen of only one radius. Also, the disadvantages of the device include the need to recalculate the applied load by using levers that have a force shoulder that does not correspond to the average radius of the sample.

A device for testing annular specimens in tension is known ( patent SU 1089470 A with priority from 01/19/1983). The device contains two coaxial rods, the ends of which are designed to interact with the grips of the testing machine, two half-discs pivotally connected to the second ends of the rods, and levers, characterized in that in order to improve the accuracy of tests by taking into account the friction forces between the half-discs and the sample, the levers are installed on both the ends of the half-disks are parallel to the plane of their connector, some ends of the levers are rigidly connected to the half-disks, the other ends of the levers located at the ends of the half-disks lying in the same plane are pivotally connected to each other, and the device is equipped with levers deformation sensors.

The disadvantage of the invention is the need to install strain gauges and their calibration in order to determine the effect of friction forces on the strength indicators, as well as the absence of supporting supports under the annular sample, which can cause the sample to rupture at the point where the half-discs open. In addition, it can be noted that it is necessary to manufacture an annular specimen of a complex shape for testing on this device and the absence of fixing the annular specimen on the surface of the half-discs, which can lead to a displacement of the axis of the working surface of the specimen from the test axis of the device.

A device for testing curved specimens in tension is known (patent SU 382952 A1 with priority from 04/28/1971), containing a template with a supporting surface with a radius of curvature equal to the radius of curvature of the sample, and grips pivotally connected to rods connected to adapters. In order to increase the accuracy of measuring the forces, it is equipped with links pivotally fixed at the ends of the template and adapters, forming an angle with the rods. The links and rods are equipped with elastic elements.

The disadvantage of the invention is the use of a fluoroplastic plate, which reduces the friction force between the arcuate sample and the template, but does not completely exclude its influence (in contrast to the proposed device, where the influence of the friction force is leveled by the teeth (ledges) of the cheeks moving along the circumference in opposite directions). Also, this device is distinguished by the use of rods of complex shapes that require adjustment to ensure the required angle of application of the load to the arcuate specimen.

The closest technical solution (prototype) is a device for tensile testing of arcuate specimens made of conductive material at elevated temperatures ( patent RU 2566393 with priority from 01.09.2014). The invention relates to mechanical testing, and specifically to testing conductive materials in order to obtain a deformation diagram under uniaxial tension and pulsed heating in a vacuum or inert medium. The device is made in the form of a compound circular guide formed by two fragments that can be rotated about a common axis. Their support surfaces coincide in shape with the concave surface of the sample and coaxial hinged shanks connected to the loading device. The supporting surface of both fragments of the circular guide at the points of contact with the sample is made of non-conductive and heat-insulating material, the mechanisms for fixing the sample are made in the form of current leads, while at least one of them is electrically isolated from the device fragments. The device includes sensors of force, deformation, temperature of the sample, an electric current source and a switching device, as well as a sealed enclosing working chamber equipped with current inputs of the power electric circuit for heating the sample and an electrically insulated connector for connecting sensors of force, deformation and temperature of the sample.

The disadvantage of the invention is the use of non-conductive support surfaces and heat-insulating materials that are more fragile in relation to the metal from which the support surfaces of the cheeks and arcuate clamps are made in the proposed invention (structure). So, as in the above patent RU 2402009, the design does not imply versatility and is intended for testing an arcuate specimen of only one radius. The disadvantages include the need to recalculate the applied load by using rods that have a shoulder of force that does not correspond to the average radius of the sample, and are not installed on the middle axis (middle) of the sample. Also, a design drawback is that the sample is clamped using a bolt that has a small sample fixation area and does not provide uniform clamping due to the absence of a radius of curvature at the bolt leg, which presses the sample to the supporting surface.

The technical objective of the present invention is to create such a device that would allow the use of replaceable cheeks and arcuate clamps to increase the versatility of application (testing of arcuate specimens of different radius of curvature), would combine the reliability and simplicity of fixing the specimens, increase the measurement accuracy by adjusting the position of the stretching force (while the axis of load application coincides with the middle of the arcuate specimen), leveling the influence of the friction force of the specimen on the supporting surface of the cheeks due to their multidirectional movement and providing protection against sagging of the specimen. exclude the influence of the moment of inertia on the measurement results (the counterbalance system allows you to set the device in a strictly horizontal position).

The technical result is achieved by the fact that in the test device of the arcuate sample containing two fragments of the guide with the bearing, the mechanisms for fastening the arcuate sample, the grips connected to the rod of the loading device, additionally introduced a clamping sleeve installed on the fork, an adjusting nut installed on the threaded part of the fork, longitudinal horizontal grooves are made in the grips with holders installed in them, while the cheeks are installed on the holders for stretching the arcuate sample, a removable clamp, a rectangular groove is made in the clamping sleeve, corrugations are made on the supporting surfaces of the cheeks and clamps, the rods have a zigzag shape and are fixed on carriages through the axis and the nut with the formation of a gap between the nut and the rod, while a thread is made on the rod end, an angular opening stop is additionally installed on the grip of the guide fragment, counterweights are installed on the angular opening stop, made with the possibility movement along the threaded rods installed in the threaded holes.

The problem is solved using the arcuate test device described below.

Other advantages and features will become more apparent from the following description of the invention with reference to the accompanying drawings.

FIG. 1 shows the general construction of an arcuate test device;

in fig. 2 shows the design of the test device of an arcuate specimen in isometric view (3D model);

in fig. 3 shows the closing of the teeth of the cheeks (the arcuate sample is not shown);

in fig. 4 shows a diagram of fixing an arcuate specimen;

in fig. 5 shows a variant of fastening the axis of the rods to increase the shoulder of force for low-power tensile testing machines;

in fig. 6 shows the grooves on the arcuate pressure and cheek surfaces, which improve the fixation of the arcuate specimen. The shape of the ledge (tooth) on the cheek is also shown, which provides protection against sagging of the arcuate specimen and leveling the friction force of the specimen against the cheek surface.

In all the figures, like reference numerals refer to like elements.

Design test device of the arcuate sample consists of two fragments of guides (1 and 2), with longitudinal, connected monolithically with them, grips (A and B). Longitudinal horizontal grooves are made in grippers A and B. Fragments of the guide with grips A and B are interconnected by a screw (3), which secures (holds) the bearing (4), which, in turn, ensures the ease of rotation of one fragment of the guide relative to the axis of the other. Holders (5) are installed in the grooves of the guides A and B, which are fixed in place by two screws (6). The cheeks (7) are installed on the holders (5) for breaking the arcuate specimen (8). The cheeks (7) are interchangeable (they can have different curvature diameters for testing arcuate specimens of different diameters) and are fixed on the holder (5) by means of four screws (6).

The fixation of the arcuate specimen (8) is carried out by pressing it against the cheek (7) with a removable (resettable depending on the radius of curvature of the arcuate specimen (8)) clamp (9). The pressing force is regulated by the action of the clamping sleeve (10) installed on the fork (11), adjustment is made through the position of the adjusting nut (12) installed on the threaded part of the fork (11). Fastening and removal (dismantling) of the fork (11) from the removable cheek (7) (when reinstalling the cheek of a different radius of curvature) is carried out by means of a screw (13) and a nut (14), the screw (13) freely rotates in the hole of the cheek (7). A rectangular groove made in the clamping sleeve (10) allows the clamping sleeve (10) to come onto the surface of the cheek (7) and provide protection against rotation of the clamping sleeve (10) itself around the axis of the fork (11). Also, the overlap of the groove on the cheek surface avoids backlash (bending, movement over the cheek surface) of the pressed arcuate specimen. The supporting surfaces of the cheeks (7) and arcuate clamps (9) have corrugations that provide improved fixation of the arcuate specimen (8). The latch (26) prevents rotation (displacement) of the fork (11) relative to the axis of the screw (13).

The breaking force is supplied through zigzag rods (15) attached to the carriages (16). The position of the carriage is fixed with a screw (17). The rod is fastened to the carriage by means of an axis (18) and a nut (19). There is a gap between the nut (19) and the rod (15), which ensures free rotation of the rod around the axis (18). The rod has a threaded tip B, which secures it in a loading device (tensile testing machine).

Moving the carriage (16) provides the ability to accurately position the point of application of the breaking force on the middle axis of the arcuate specimen, while moving to the left (see Fig. 5) allows to increase the load application arm and thereby reduce the force applied to the rods, which makes it possible to use low-power loading devices.

To ensure the closing of the grooves on the cheeks (7) and their tight abutment to each other, an angular opening limiter (20) is used. The limiter of angular opening is rigidly fixed on a fragment of the grip guide (2) by means of screws (21), pressing against the grip limiter (1) is carried out using a lock (22) and a nut (23). Loose pressing of the head of the lock (22) and the nut (23) to the surface of the limiter for angular opening allow the lock to slide freely along the groove G. The limiter of rotation simultaneously performs the function of a counterweight.

To balance the structure in order to shift the center of gravity of the loading device, for example, a tensile testing machine (if necessary) on the axis of the rods (18), which provides a horizontal arrangement of the structure (as shown in Fig. 1 and Fig. 5), the use of counterweights (24) is provided. sliding on threaded rods (25) installed in the threaded holes on the rotation stop (20) and on the hinge (2).

Depending on the position of the center of gravity, the number and position of the counterweights (24) can be adjusted (they can be installed either on one or the other side, or not at all).

The principle of operation of the arcuate test device is shown below.

Replaceable cheeks (7) of the required radius (R _BH ) are installed and set at a distance R _BH from the axis of the hinges (the axis of the bolt (3)). The arcuate specimen (8) is fixed on the cheeks (7) using a replaceable arcuate clamp (9) of the corresponding radius (R _HAP ). The thrust axes (18) are set to the middle section of the specimen (R _CP ), in the case of "weakness" of the loading device (tensile machine), the thrust axes move to increase the arm of the force and are set at a distance from the specimen (R _TRACTION ). Then the zigzag rods (15) are clamped in a loading device (tensile testing machine) and the load is applied and the specimen breaks. To give the structure a horizontal position, counterweights (24) are installed (if necessary), which reduce the moment of inertia of the structure (since at first the force of the tensile machine is spent on bringing the structure to a horizontal position).

The proposed test device of the arcuate specimen is simple to manufacture, assemble and configure, the accuracy (due to the installation of the axis of the rods strictly in the middle of the specimen) and the versatility of which has increased (due to the use of replaceable cheeks and arcuate clamps), with improved fixation and fastening of the specimen, with the possibility of adjustment shoulder of the applied load of the tensile testing machine.

The technical result provided by the use of an arcuate test device is expressed in the following.

1. In increasing the measurement accuracy, since the axis of the rods runs strictly along the axis of the sample, there is no need to recount (unlike other prototypes).

2. In increasing the versatility due to the use of cheeks and clamps of any diameter.

3. In improving the degree of pressing the sample due to the use of an arcuate clamp (in patent 2566393, which is closest to our design, the pressing area is small).

4. The possibility of using in weak tensile machines is provided by increasing the arm of force by moving the axis of the rods.

Claims (1)

A test device of an arcuate specimen containing two fragments of a guide with a bearing, fastening mechanisms of an arcuate specimen, grips connected to the rod of a loading device, characterized in that it additionally contains a clamping sleeve mounted on the fork, an adjusting nut installed on the threaded part of the fork, the grips are made longitudinal horizontal grooves with holders installed in them, while cheeks are installed on the holders for stretching an arcuate sample, a removable clamp, a rectangular groove is made in the clamping sleeve, corrugations are made on the supporting surfaces of the cheeks and clamps, the rods have a zigzag shape and are fixed on the carriages through the axis and a nut with the formation of a gap between the nut and the rod, while a thread is made on the rod end, an angular opening stop is additionally installed on the grip of the guide fragment, counterweights are installed on the angular opening stop, made with the ability to move along the thread pins installed in the threaded holes.

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