CN212539956U - Uniaxial compression test device for rock and concrete - Google Patents

Abstract

The utility model discloses a uniaxial compression test device for rock and concrete, which comprises a sample, a pressure head and a base; the sample comprises thick columns at two ends and a thin column in the middle, a transition area is arranged between the thick columns and the thin column, and grooves are respectively formed in the center positions of the thick columns at the two ends, which are far away from the thin column; the pressure head comprises a first cylinder, and a first bump matched with the groove is arranged at the center of one end of the first cylinder; the base comprises a disc base, a second column body is arranged at the center of the disc base, and a second bump matched with the groove is arranged at the center of one end, far away from the disc base, of the second column body; the first lug and the second lug are respectively inserted into the grooves on the thick cylinders at two ends; the utility model discloses can effectively eliminate the influence of tip friction effect among rock and the concrete unipolar compression test, the test result is reliable.

Description

Uniaxial compression test device for rock and concrete

Technical Field

The utility model relates to a civil engineering technical field specifically is a unipolar compression test device for rock and concrete.

Background

In laboratory tests on rock and concrete materials, uniaxial compression tests are an extremely important type of test, and end effects are widely present in all types of uniaxial compression tests. Numerous studies have found that tip effects have different effects on the test results under different test conditions. Under the condition of uniaxial compression, the end effect not only can cause the test result to generate larger deviation, but also can change the failure mechanism and failure mode of the sample, the obtained result has great difference with theory, and the measured compressive strength has great deviation with the true value, thereby bringing misleading and puzzlement to related research.

According to the relevant specifications and recommendations, cylindrical specimens with a diameter of about 50mm and a height of about 100mm are currently the most suitable choice for uniaxial compression tests. Because the metal pressure head and the rock or concrete material sample have larger difference in the aspects of elastic modulus, material roughness and the like, the deformation between the two materials is not coordinated when the metal pressure head and the rock or concrete material sample are pressed, so that the shearing stress which is unevenly distributed is caused on a contact surface, and in addition, the outer sides of the two ends of the sample are respectively fixed with the pressure head and the base through the hose clamp, so that the stress field at the end part of the sample generates great deviation from the ideal condition. Numerical simulation and tests show that stress fields at two ends of the sample are funnel-shaped under the influence of the end action, and the overall strength and deformation parameters of the sample are influenced by the uneven distribution and transmission of the stress, so that the measured data are unreliable. Many existing techniques and methods can only reduce the effect of the end effect to some extent, but none of the effects are very desirable. In addition, in the uniaxial compression test, the traditional method is difficult to ensure that the center lines of the sample, the pressure head and the base are superposed, so that the axial eccentric compression is caused, and certain errors are brought to the test.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a unipolar compression test device for rock and concrete to solve the unipolar compression test device among the prior art and application method and can only reduce the influence of tip effect to a certain extent, but the effect is not very ideal problem yet.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a uniaxial compression test device for rock and concrete, which comprises a sample, a pressure head and a base; the sample comprises thick columns at two ends and a thin column in the middle, transition areas are respectively arranged between the thick columns at the two ends and the thin column in the middle, the thick columns, the transition areas and the thin columns are integrated, and grooves are respectively formed in the center positions of the thick columns at the two ends, which are far away from the thin column; the pressure head comprises a first cylinder, a first lug matched with the groove is arranged at the center of one end of the first cylinder, and the first cylinder and the first lug are integrated; the base comprises a disc base, a second column body is arranged at the center of the disc base, a second lug matched with the groove is arranged at the center of one end, away from the disc base, of the second column body, and the disc base, the second column body and the second lug are integrated; the first lug and the second lug are respectively inserted into the grooves on the thick cylinders at two ends.

Furthermore, the side of first cylinder is equipped with two wings, and two wings are mirror symmetry, and two wings and first cylinder are integrative, correspond respectively on the two wings and offer the mounting hole that is used for placing LVDT displacement sensor.

Furthermore, a sensor interface is arranged around the second column body on the disc base.

Further, the groove is a cylindrical groove, and the first lug and the second lug are both cylindrical; the depth of the groove is smaller than the length of the thick cylinder; the cross section shape of the first cylinder and the cross section shape of the second cylinder are the same as the cross section shape of the thick cylinder.

Furthermore, the first bump and the second bump are respectively sleeved with a gasket, and the gaskets are respectively arranged between the thick cylinders at the two ends and the first cylinder and the second cylinder.

Further, rubber sleeves are sleeved on the periphery of one end, close to the gasket, of the first column body, the periphery of the gasket and the periphery of one end, close to the gasket, of the thick column body; rubber sleeves are sleeved on the periphery of one end of the second column, the periphery of the gasket and the periphery of one end of the thick column, which is close to the gasket; the periphery of the rubber sleeve is sleeved with a hose clamp.

Furthermore, the shapes of the thick cylinder, the thin cylinder, the first cylinder and the second cylinder are all cylinder shapes or right prism shapes.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model provides a unipolar compression test device for rock and concrete, including sample, pressure head and base, can fall into four parts with the sample from the angle of mechanics: the thick cylinder part at the bottom of the groove is a pressed area, the thick cylinder parts at two sides of the groove are constraint areas, the thin cylinder part is a test area, and the part between the thick cylinder and the thin cylinder is a transition area; the first lug on the pressure head and the second lug on the base are respectively inserted into the grooves on the thick cylinders at two ends, the lower end of the pressure head and the upper end of the base are both contacted with the pressed area of the sample, when axial pressure is applied, the constraint areas at two sides of the groove can enable the central axes of the sample, the pressure head and the base to be accurately coincided, the pressure action is transmitted from the pressed area to the transition area, finally, a uniform pressure stress field is formed in the test area, and test data acquisition is carried out in the test area, so that the influence generated by an end effect is eliminated, and the reliability of a test result is ensured;

the utility model can reliably and conveniently complete the uniaxial compression test of (class) rock materials, obtain the compressive strength of the tested materials, avoid the error influence caused by the end friction effect, and effectively keep the coincidence of the center lines of the sample, the pressure head and the base by the groove design of the sample, thereby avoiding the influence of eccentric compression;

the utility model can effectively eliminate the influence of the end friction effect in the uniaxial compression test of the rock and the concrete, so that the reliability of the test result is greatly improved; the utility model provides a unipolar compression test device for rock and concrete simple structure, convenient to use has wide application prospect in civil engineering technical field.

Drawings

FIG. 1 is a schematic structural diagram of a uniaxial compression test device for rock and concrete according to an embodiment of the present invention;

fig. 2 is an exploded view of a uniaxial compression test device for rock and concrete according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a single-shaft compression testing apparatus for rock and concrete according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of another example of a uniaxial compression test device for rock and concrete according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a pressure head in a uniaxial compression test device for rock and concrete according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a base in a uniaxial compression test device for rock and concrete provided by an embodiment of the present invention.

In the figure: 1-sample, 11-thick column, 12-thin column, 13-transition zone, 14-groove, 2-pressure head, 21-first column, 22-first bump, 23-wing, 24-mounting hole, 3-base, 31-disc base, 32-second column, 33-second bump, 34-gasket, 5-rubber sleeve, 6-sensor interface, 7-compression zone, 8-constraint zone and 9-test zone.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by changing the material type, the shape and the size of the test piece without creative work by those skilled in the art all belong to the protection scope of the present invention.

As shown in fig. 1 to 6, a uniaxial compression test device for rock and concrete provided by an embodiment of the present invention includes a sample 1, a pressure head 2 and a base 3, wherein the pressure head 2 and the base 3 are made of high strength stainless steel after quenching treatment; sample 1 includes the thick cylinder 11 at both ends and middle thin cylinder 12, is equipped with transition zone 13 between the thick cylinder 11 at both ends and middle thin cylinder 12 respectively, and transition zone 13 is the arc, and thick cylinder 11, transition zone 13 and thin cylinder 12 are an organic piece, and thick cylinder 11 at both ends is kept away from the one end central point of thin cylinder 12 and is put and set up fluted 14 respectively, can fall into four parts with sample 1 from the angle of mechanics: the thick column 11 part at the bottom of the groove 14 is a pressed area 7, the thick column 11 parts at two sides of the groove 14 are constraint areas 8, the thin column 12 part is a test area 9, and the part between the thick column 11 and the thin column 12 is a transition area 13; the pressure head 2 comprises a first cylinder 21, a first lug 22 matched with the groove 14 is arranged at the center of one end of the first cylinder 21, and the first cylinder 21 and the first lug 22 are an integrated piece; the base 3 comprises a disc base 31, a second column 32 is arranged at the center of the disc base 31, a second bump 33 matched with the groove 14 is arranged at the center of one end of the second column 32, which is far away from the disc base 31, and the disc base 31, the second column 32 and the second bump 33 are integrated; the first lug 22 and the second lug 33 are respectively inserted into the grooves 14 on the thick cylinders 11 at two ends, and the central axes of the test sample 1, the pressure head 2 and the base 3 are precisely coincided through the grooves 14.

Two wings 23 are arranged on the side surface of the first column 21, the two wings 23 are in mirror symmetry, the two wings 23 and the first column 21 are an integral piece, and mounting holes 24 for placing an LVDT (Linear Variable Differential Transformer) displacement sensor are correspondingly formed in the two wings 23 respectively.

A sensor interface 34 is provided around the second cylinder 32 on the disc base 31.

The groove 14 is a cylindrical groove, and the first bump 22 and the second bump 33 are both cylindrical; the depth of the groove 14 is less than the length of the thick column 11; the cross-sectional shape of the first column 21 and the cross-sectional shape of the second column 32 are both the same as the cross-sectional shape of the thick column 11.

The first bump 22 and the second bump 33 are respectively sleeved with a gasket 4, and the gaskets 4 are respectively arranged between the thick columns 11 at the two ends and the first column 21 and the second column 32.

The periphery of one end of the first column body 21, which is close to the gasket 4, the periphery of the gasket 4 and the periphery of one end of the thick column body 11, which is close to the gasket 4, are sleeved with rubber sleeves 5; rubber sleeves 5 are sleeved on the periphery of one end of the second column body 32, the periphery of the gasket 4 and the periphery of one end of the thick column body 11 close to the gasket 4; the periphery of the rubber sleeve 5 is sleeved with a throat hoop 6.

The shapes of the thick cylinder 11, the thin cylinder 12, the first cylinder 21, and the second cylinder 32 are all cylinder shapes or right prism shapes.

The utility model can effectively eliminate the influence of stress redistribution caused by the end friction effect in the uniaxial compression test of rock and concrete, so that the reliability of the test result is greatly improved; the utility model provides a unipolar compression test device for rock and concrete simple structure, convenient to use has wide application prospect in civil engineering technical field.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. A uniaxial compression test device for rock and concrete, characterized in that: comprises a sample (1), a pressure head (2) and a base (3); the test sample (1) comprises thick cylinders (11) at two ends and a thin cylinder (12) in the middle, transition areas (13) are respectively arranged between the thick cylinders (11) at the two ends and the thin cylinder (12) in the middle, the thick cylinders (11), the transition areas (13) and the thin cylinders (12) are integrated, and grooves (14) are respectively formed in the center positions of the ends, far away from the thin cylinders (12), of the thick cylinders (11) at the two ends; the pressure head (2) comprises a first cylinder (21), a first lug (22) matched with the groove (14) is arranged at the center of one end of the first cylinder (21), and the first cylinder (21) and the first lug (22) are integrated; the base (3) comprises a disc base (31), a second column (32) is arranged at the center of the disc base (31), a second bump (33) matched with the groove (14) is arranged at the center of one end, away from the disc base (31), of the second column (32), and the disc base (31), the second column (32) and the second bump (33) are integrated; the first lug (22) and the second lug (33) are respectively inserted into the grooves (14) on the thick columns (11) at two ends.

2. The uniaxial compression test apparatus for rock and concrete according to claim 1, wherein: the lateral surface of the first cylinder (21) is provided with two wings (23), the two wings (23) are in mirror symmetry, the two wings (23) and the first cylinder (21) are integrated, and the two wings (23) are respectively and correspondingly provided with mounting holes (24) for placing an LVDT displacement sensor.

3. The uniaxial compression test apparatus for rock and concrete according to claim 1, wherein: and a sensor interface (34) is arranged around the second cylinder (32) on the disc base (31).

4. The uniaxial compression test apparatus for rock and concrete according to claim 1, wherein: the groove (14) is a cylindrical groove, and the first bump (22) and the second bump (33) are both cylindrical; the depth of the groove (14) is less than the length of the thick cylinder (11); the cross-sectional shape of the first column (21) and the cross-sectional shape of the second column (32) are both the same as the cross-sectional shape of the thick column (11).

5. The uniaxial compression test apparatus for rock and concrete according to claim 4, wherein: the first bump (22) and the second bump (33) are respectively sleeved with a gasket (4), and the gaskets (4) are respectively arranged between the thick columns (11) at the two ends and the first column (21) and the second column (32).

6. The uniaxial compression test apparatus for rock and concrete according to claim 5, wherein: rubber sleeves (5) are sleeved on the periphery of one end of the first cylinder (21) close to the gasket (4), the periphery of the gasket (4) and the periphery of one end of the thick cylinder (11) close to the gasket (4); rubber sleeves (5) are sleeved on the periphery of one end of the second cylinder (32), the periphery of the gasket (4) and the periphery of one end of the thick cylinder (11) close to the gasket (4); the periphery of the rubber sleeve (5) is sleeved with a hose clamp (6).

7. The uniaxial compression test apparatus for rock and concrete according to claim 1, wherein: the shapes of the thick cylinder (11), the thin cylinder (12), the first cylinder (21) and the second cylinder (32) are all cylinder shapes or right prism shapes.

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