RU2607301C1 - Device for determining compression strength of composite materials (versions) - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to investigation of physical and mechanical properties of composite materials, namely to investigation of elastic-strength characteristics at compression (strength, modulus of elasticity). Device consists of two lower and two upper gripping L-shaped appliances. In two upper gripping devices through cylindrical holes are made, in which there are cylindrical hinge elements. Device is fixed on sample by means of bolt joint. In cylindrical holes cylindrical guide rods are placed, which are rigidly fixed in lower gripping devices and on lower gripping appliances central support plates are arranged, or in cylindrical holes cylindrical guide rods are placed, while at said rods independent support plates freely move.

EFFECT: technical result: adding structural elements, making it possible to use reusable suspended strain sensors for determining deformation characteristics, provision of axial stability of sample during loading, high reliability of measured data.

10 cl, 4 dwg

Description

The invention relates to the field of research of physicomechanical properties of composite materials, namely to the study of elastic-strength characteristics under compression (strength, elastic modulus).

A device for determining the compressive strength of composite materials, consisting of four parts and two cylindrical guide rods (American standard: ASTM Standart D6641-09 (2009), "Test Method for Determining the Compressive Properties of polymer Matrix Composite Laminates using a Combined loading Compression (CLC) Test Fixture ”, American Society for Testing and Materials, West Conshohocken, Pennsylvania (first issued in 2001)). 4 parts are closed in pairs on the sample and tightened with bolted joints. In this device, the end part of the sample is not closed.

The disadvantages of this device are that:

- the peculiarity of the location of the sample in the device makes it difficult to measure the modulus of elasticity and deformation of the sample by mounted extensometers or non-contact optical measuring instruments;

- this device provides for the use of strain gauges only.

A device for determining the compressive strength of composite materials, consisting of two parts and two cylindrical guide rods and a hydraulic unit for fixing the sample (Patent DE 10344544 B3, G01N 3/04, 05.01.2005). Using the pressure of the plungers of the gripping parts, the sample is securely fixed between them.

The disadvantages of this device are that:

- the device has a large mass;

- the design requires the use of a hydraulic unit;

- high cost of the device.

A device for determining the compressive strength of composite materials, consisting of two pairs of wedge clamps enclosed in a cylindrical body (GOST 25.602-80 "Test method for compression at normal, elevated and low temperatures"). Twisting of wedge-shaped clamps is excluded due to the use of roller guides.

The disadvantages of this device are that:

- the device has a rather complicated design;

- the peculiarity of the location of the sample in the device makes it difficult to measure the modulus of elasticity and deformation of the sample by mounted extensometers or non-contact optical measuring instruments;

- this device provides for the use of only strain gauges;

- fixed width of the sample.

The prototype is a device for determining the compressive strength of composite materials, consisting of four parts and four cylindrical guide rods (DF Adams and JS Welsh, “The Wyoming Combined Loading Compression (CLC) Test Method”, Journal of Composites Technology and Research, Vol. 19, No. 3, 1997, pp. 123-133). The sample is located in the center between the four cylindrical guide rods and parallel to them. It is fixed between the two lower parts of the device, then fixed in the upper parts of the device, which are interconnected in pairs (two upper and two lower) are bolted together. Thus, between the two upper and two lower parts of the device there is a gap (unsupported area of the sample), called the working area of the sample. By applying pressure to the upper part of the device and its free movement along the cylindrical guide rods of the lower half, the load is transferred to the sample with its maximum concentration in the working area of the sample. The two upper parts have the same geometric proportions, the lower parts with cylindrical guide rods.

The disadvantages of this device are that:

- four cylindrical guide rods make it difficult to use mounted extensometers;

- the device has a large mass;

- with an increase in the working part of the sample, there is a large loss of axial stability and distortion, thereby the measured values.

The technical task of this invention is to provide a device that allows mechanical compression tests of composite materials with a combined method of application of the load to determine the elastic strength characteristics. Also, one of the tasks was to fulfill the conditions for maintaining the stability of the sample under its loading.

The technical result of this invention is the addition of structural elements that allow the use of reusable mounted strain gauges to determine the deformation characteristics, ensuring axial stability of the sample under loading, increasing the reliability of the measured data. Also, this design of the device allows you to measure the deformation of the sample by contactless strain gauges on its front surface.

To achieve the technical result, a device for determining the compressive strength of composite materials is proposed, consisting of two lower and two upper grippers of a L-shaped shape, characterized in that through the upper two grippers are made through cylindrical holes in which cylindrical hinge elements are fixed, moreover, in the aforementioned cylindrical holes are cylindrical guide rods, which are rigidly fixed in the lower gripping when posobleniyah furthermore, on the lower central gripping devices disposed support plates, wherein the device is fixed on a sample by bolting.

Preferably, a coating is applied to the sample fixing portion to prevent slipping of the sample.

Preferably, notches are applied to the sample fixing portion to prevent slipping of the sample.

Preferably, the central support strips are equipped with tabs located at the point of contact with the sample.

Preferably, inlays made of anti-friction material are used.

The technical result is also achieved by a device for determining the compressive strength of composite materials, consisting of two lower and two upper grippers of a L-shaped shape, characterized in that through the upper two grippers are made through cylindrical holes in which cylindrical hinged elements are fixed, in cylindrical holes are cylindrical guide rods, and independent supporting straps, while the device is fixed on the sample by means of a bolted connection.

Preferably, a coating is applied to the sample fixing portion to prevent slipping of the sample.

Preferably, notches are applied to the sample fixing portion to prevent slipping of the sample.

Preferably, the independent support bars are equipped with tabs located at the point of contact with the sample.

Preferably, inlays made of anti-friction material are used.

The invention is illustrated by drawings.

In FIG. 1 shows an isometric view of the proposed device with a rigidly fixed central support strips, where:

1 - upper grippers;

2 - lower grippers;

3 - cylindrical hinge elements;

4 - cylindrical guide rods;

5 - threaded holes;

6 - sample;

7 - plot fixing the sample;

8 - through cylindrical holes;

9 - fixed central support strips;

13 - bolted connection.

In FIG. 2 shows an isometric view of the proposed device with independent support bars, where:

1 - upper grippers;

2 - lower grippers;

3 - cylindrical hinge elements;

4 - cylindrical guide rods;

5 - threaded holes;

6 - sample;

7 - plot fixing the sample;

8 - through cylindrical holes;

12 - independent central support strips.

13 - bolted connection.

In FIG. 3.1 and FIG. 3.2 is an isometric view of an independent central support bar, where:

5 - threaded holes;

8 - through cylindrical holes;

10 - a nest of a level;

11 - tabs;

12 - independent central support bar.

In FIG. 4 shows a cylindrical hinge element (3), where: A is a front view; B - top view.

The present invention describes the geometry of a device for testing composite materials for compressive strength with the application of combined loading.

A device with rigidly fixed central support bars (Fig. 1) for testing flat samples of composite materials for compression is made of monolithic parts and contains four L-shaped grippers: two upper (1) and two lower (2). The upper gripping devices (1) have through cylindrical holes (8) in which cylindrical hinge elements (3) are placed (Fig. 4). The lower grippers (2) have cylindrical openings in which the cylindrical guide rods (4) are rigidly fixed. The gripping devices (1) and (2) have threaded holes (5) for locking and fixing the sample (6) by means of a bolted connection (13). Sample (6) is located in the middle of the gripping devices (1) and (2) in the area of fixation of the sample (7) between the two guide rods (4). The device additionally has two L-shaped fixed central support strips (9) in a monolithic design with each of the two lower grippers. The sections of the fixed supporting strips (9) in contact with the sample (6) have a socket for the strip (10), in which tabs (11) are installed that reduce friction during deformation of the sample (6).

A device with independent support bars (Fig. 2) for compression testing flat samples of composite materials is made of monolithic parts and contains four L-shaped grippers: two upper (1) and two lower (2). The upper gripping devices (1) have through cylindrical holes (8) in which cylindrical hinge elements (3) are placed (Fig. 4). The lower grippers (2) have cylindrical openings in which the cylindrical guide rods (4) are rigidly fixed. The gripping devices (1) and (2) have threaded holes (5) for locking and fixing the sample (6) by means of a bolted connection (13). Sample (6) is located in the middle of the grippers (1) and (2) in the area of fixation of the sample (7) between two cylindrical guide rods (4). The device additionally has two independent central support strips (12) in a removable design (Fig 3.1 and Fig 3.2). Planks (12) on one side have a through cylindrical hole (8), which provides free movement on a cylindrical guide rod (4) between the gripping devices (1) and (2). Independent central support strips (12) are closed on the central part of the specimen (6) and fixed by bolt connection (13) in the threaded holes (5). The sections of the independent support strips in contact with the sample (6) may additionally have a socket of the strip (10), in which tabs (11) are installed that reduce friction during deformation of the sample (6) (Fig 3.2).

To conduct mechanical compression tests with the combined load applied, the sample (6) must first be fixed in the device. A pair of lower grippers (2) is closed and mounted on a flat surface so that the protruding cylindrical guide rods (4) are facing up. Then they open slightly and the sample (6) is installed in the middle of the fixation sections of the sample (7). Then, the two lower parts of the grippers (2) are tightened with bolts (13) with little effort, slightly fixing the sample (6). The two upper parts of the grippers (1) also close, but not to the end. They turn upside down and set on a flat surface. The lower grippers (2) with the fixed sample (6) are turned over and inserted by the cylindrical guide rods (4) into the cylindrical holes (8) with the cylindrical hinge elements (3) and the specimen (6) in the specimen fixation section (7) of the upper grippers ( 1) respectively. After that, the upper gripping devices (1) are also tightened by means of a bolted connection (13). All bolts (13) are tightened alternately with the required force. A fixture with a fixed sample (6) is installed between the clamping plates of the test bench, which then close until the sample is destroyed.

In this case, before the movement of the traverse of the testing machine begins, a mounted extensometer is mounted on the fixed sample (6). The deformation is measured within the elastic behavior of the material of the sample (6), then the sample (6) is unloaded and the extensometer is removed.

To select the thickness of the sample, conditions must be met to prevent loss of stability due to bending stresses in the sample (formula 1). This condition is also fulfilled for a configuration with central support bars, taking into account the fulfillment of formula 1 for two working areas.

where h is the thickness of the sample, mm;

l _v - the length of the working area of the sample, mm;

- ожидаемая критическая прочность при сжатии, МПа;

- expected critical compressive strength, MPa;

E ^and - the expected modulus of elasticity in bending, MPa;

G _xy is the interlayer shear modulus, MPa.

Claims (10)

1. A device for determining the compressive strength of composite materials, consisting of two lower and two upper grippers L-shaped, characterized in that the two upper grippers are made through cylindrical holes in which cylindrical hinge elements are fixed, and in the said cylindrical holes are arranged cylindrical guide rods that are rigidly fixed in the lower grippers, in addition, on the lower grippers ra put the central support plates, wherein the device is fixed on a sample by bolting. 2. The device according to claim 1, characterized in that a coating is applied to the sample fixation area to prevent slipping of the sample. 3. The device according to p. 1, characterized in that notches are applied to the sample fixation area to prevent slipping of the sample. 4. The device according to claim 1, characterized in that the central supporting strips are equipped with tabs located at the point of contact with the sample. 5. The device according to p. 4, characterized in that the tabs made of antifriction material are used. 6. A device for determining the compressive strength of composite materials, consisting of two lower and two upper grippers L-shaped, characterized in that the two upper grippers are made through cylindrical holes in which the cylindrical hinge elements are fixed, in the cylindrical holes cylindrical guide rods, with independent supporting strips freely moving along said rods, while the device is fixed on a sample of by bolting. 7. The device according to claim 6, characterized in that a coating is applied to the sample fixation area to prevent slipping of the sample. 8. The device according to p. 6, characterized in that notches are applied to the sample fixation area to prevent slipping of the sample. 9. The device according to p. 6, characterized in that the independent support strips are equipped with tabs located at the point of contact with the sample. 10. The device according to p. 9, characterized in that the tabs are made of antifriction material.

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