KR102104720B1 - Tensile testing apparatus - Google Patents

Abstract

The present invention relates to a tensile testing device. Tensile test apparatus according to an embodiment of the present invention has a jig for gripping the test piece, the test piece that allows the test piece to be tensioned, a tensile test can be made; And a drive unit connected to the test unit to provide power to operate the test unit, wherein the drive unit is provided to drive through gas pressure.

Description

Tensile testing apparatus

The present invention relates to a tensile test device, and more particularly to a tensile test device capable of performing a tensile test at high speed.

The material needs to be identified for its mechanical properties prior to actual use. One of the methods for measuring the mechanical properties of a material is a tensile test. The tensile test grasps the mechanical properties of the material used as the test piece by applying a tensile force to a given test piece. At this time, mechanical properties that can be grasped include yield point, proof stress, tensile strength, proportional limit, elastic limit, elongation, shrinkage, and elastic modulus.

The tensile test is influenced by the size of the load applied to the test piece and the speed at which the test piece is stretched. In addition, in the case of the speed at which the test piece is stretched, it is necessary to be selected according to the way the load is applied to the material in the environment in which the material is actually used.

The present invention is to provide a tensile test apparatus capable of effectively performing a tensile test.

In addition, the present invention is to provide a tensile test apparatus that is provided with a wide range of test capacities.

In addition, the present invention is to provide a tensile test apparatus having a strain rate of 10 or more in a tensile test.

According to an aspect of the present invention, a test unit having a jig for gripping a test piece and allowing the test piece to be tensioned so that a tensile test can be performed; And a driving unit connected to the test unit and providing power to operate the test unit, wherein the driving unit may be provided to drive through gas pressure.

In addition, the jig, a first jig member that can grip one side of the test piece; And a second jig member positioned to face the first jig member and provided to grip the other side of the test piece, wherein the first jig member and the second jig member are in a direction facing each other. A gripping space in which the test piece can be positioned is formed, and may include a roller exposed toward the gripping space.

In addition, the jig, a first jig member that can grip one side of the test piece; And a second jig member positioned to face the first jig member and provided to grip the other side of the test piece, wherein the first jig member and the second jig member are in a direction facing each other. A gripping space in which a test piece can be positioned is formed, and a gripping surface is formed in an area facing each other around the gripping space, and the gripping surface is a direction in which the first and second jig members face each other. A first gripping surface located at; And a second gripping surface positioned in a direction in which the first jig member and the second jig member are spaced apart from each other with respect to the first gripping surface, wherein the second gripping surface is spaced apart from each other with respect to the gripping space. The distance may be formed larger than the distances between the first gripping surfaces.

Further, in the first jig member and the second jig member, a roller exposed toward the gripping space may be positioned on the first gripping surface.

In addition, the rollers may be provided on both sides in the direction facing each other with respect to the gripping space.

In addition, the jig, a first jig member that can grip one side of the test piece; And a second jig member positioned to face the first jig member and provided to grip the other side of the test piece, wherein the test unit includes: a first support member connected to the first jig member; And a second support member connected to the second jig member, wherein the second support member is connected to the second jig member and is movably provided along a longitudinal direction; And it is located on the outer periphery of the drive shaft, including a support for supporting the drive shaft, the drive unit is provided to be connected to the gas supply pipe, to increase the pressure of the gas introduced through the gas supply pipe to enable discharge A pressure increasing member provided; And a driving member configured to move the driving shaft through the gas discharged from the pressure increasing member.

Further, the driving unit may further include a receiving member positioned between the pressure increasing member and the driving member to store gas discharged from the pressure increasing member.

In addition, an opening / closing member is positioned between the receiving member and the driving member, and the tensile testing device opens the opening / closing member when a predetermined amount of gas is received in the receiving member or an inner space of the receiving member reaches a set pressure. It may further include an opening controller.

In addition, an opening / closing member is positioned between the receiving member and the driving member, and the tensile test device opens the opening / closing member when a set time elapses after the pressure increasing member starts supplying compressed gas to the receiving member. It may further include a controller.

In addition, the capacity range in which the test unit acts on the test piece may be 0.5 kN to 10 kN.

According to an embodiment of the present invention, a tensile test apparatus capable of effectively performing a tensile test may be provided.

In addition, according to an embodiment of the present invention, a tensile test apparatus in which a range of test capacities is provided can be provided.

In addition, according to an embodiment of the present invention, a tensile test apparatus having a strain rate of 10 or more in a tensile test may be provided.

1 is a view showing a tensile test apparatus according to an embodiment of the present invention.
FIG. 2 is a side view of the tensile testing device of FIG. 1.
3 is a view showing a jig in which the test piece is located.
4 is a view showing a jig member.
5 is a view showing a time-displacement relationship when the tensile test apparatus according to an embodiment of the present invention is driven without a test piece.
6 to 10 are views showing an instantaneous rate of change of time-displacement data of a tensile test apparatus according to an embodiment of the present invention.
11 is a view showing an instantaneous rate of change of time-displacement data of conventional equipment.
12 is a diagram showing the correlation between the strain rate range and the tensile test.
13 is a view showing the test results of the tensile test apparatus and the conventional apparatus according to an embodiment of the present invention for the same specimen.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be interpreted as being limited to the following embodiments. This embodiment is provided to more fully describe the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings has been exaggerated to emphasize a clearer explanation.

1 is a view showing a tensile test apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the tensile test apparatus 1 includes a test unit 10, a driving unit 30, a measurement unit 40 and a controller 50.

The test unit 10 allows the test piece P to be pulled in a state where the test piece (P in FIG. 3) is held, so that a tensile test can be performed on the test piece P. The test unit 10 includes a jig 110 and support members 121 and 125.

The jig 110 grips the test piece P. The jig 110 includes a first jig member 111 and a second jig member 112.

The first jig member 111 and the second jig member 112 are positioned to face each other, so that the first jig member 111 grips one side of the test piece P, and the second jig member 112 is a test piece ( Grip the other side of P). For example, the first jig member 111 and the second jig member 112 are positioned facing each other in the vertical direction, and the first jig member 111 may be positioned above the second jig member 112. In addition, the first jig member 111 may grip the upper portion of the test piece P, and the second jig member 112 may grip the lower portion of the test piece P.

The support members 121 and 125 are connected to the jig 110 to support the jig 110. The support members 121 and 125 may be fixed to the frame 20. The support members 121 and 125 include a first support member 121 and a second support member 125.

The first support member 121 is connected to the first jig member 111 to support the first jig member 111. For example, the first support member 121 may have a set length in the vertical direction, and a lower portion of the first support member 121 may be connected to an upper portion of the first jig member 111. The first support member 121 may be fixed to the frame 20. For example, the upper portion of the first support member 121 may be fixed to the frame 20. A load meter 122 may be positioned at a portion where the first support member 121 and the frame 20 are connected. The load meter 122 may measure the load generated by the force transmitted from the jig 110 to the first support member 121.

The second support member 125 is connected to the second jig member 112 to support the second jig member 112. For example, the second support member 125 has a set length in the vertical direction, and an upper portion of the second support member 125 may be connected to a lower portion of the second jig member 112. The second support member 125 may be fixed to the frame 20. For example, the lower portion of the second support member 125 may be fixed to the frame 20. The second support member 125 includes a drive shaft 126 and a support portion 127.

The drive shaft 126 may be provided in a rod shape having a set length. One end of the driving shaft 126 is connected to the second jig member 112 and may be provided to be movable along the longitudinal direction. For example, the driving shaft 126 is positioned such that the longitudinal direction is directed upward and downward, so that the second jig member 112 may be moved up and down according to the movement of the driving shaft 126. The support part 127 is positioned around the outer periphery of the drive shaft 126 to support the drive shaft 126. The support 127 may be fixed to the frame 20.

The drive unit 30 is located adjacent to the test unit 10, providing the power to operate the test unit 10. For example, the driving unit 30 is fixed to the lower portion of the frame 20, it may be located under the test unit 10. The driving unit 30 is provided to be driven through gas pressure. For example, the gas used in the drive unit 30 may be air or the like. The driving unit 30 includes a pressure-increasing member 310, a receiving member 320 and a driving member 330.

The pressure-increasing member 310 is connected to the gas supply pipe 311 and is provided to be discharged after increasing the pressure of the gas introduced through the gas supply pipe 311. For example, the pressure intensifying member 310 may be provided as a pressure intensifier including a piston structure. The gas supply pipe 311 may be connected to a gas supply source, such as a gas tank provided to store the gas in a set pressure state, an air compressor capable of inhaling and compressing the air, and then supplying the gas.

At one point of the gas supply pipe 311, a pressure adjusting member 315 capable of adjusting the pressure of the gas flowing through the gas supply pipe 311 may be provided. For example, the pressure regulating member 315 may be provided as a pressure-sensitive valve. Accordingly, the pressure adjusting member 315 may be adjusted so that the pressure increases when rotating in one direction and decreases when rotating in the other direction. Also, the pressure regulating member 315 may allow the gas supply pipe 311 to be opened and closed.

The receiving member 320 may be connected to the pressure increasing member 310 and receive gas discharged from the pressure increasing member 310. The receiving member 320 is provided in a container shape having a set volume, so that a space in which the gas is accommodated may be formed inside the receiving member 320.

The driving member 330 is connected to the receiving member 320 and the driving shaft 126 so that the driving shaft 126 is moved by the gas provided by the receiving member 320. For example, the driving member 330 is provided to include a cylinder and a piston, and the piston is configured to be connected to the driving shaft 126, so that the driving shaft 126 can be moved by the gas flowing from the receiving member 320 have. An opening / closing member 321 may be provided in a path through which the gas flows from the receiving member 320 to the driving member 330. The opening / closing member 321 may open or close a path through which gas is introduced from the receiving member 320 to the driving member 330.

FIG. 2 is a side view of the tensile testing device of FIG. 1.

2, the illustration of the controller 50 is omitted for convenience of illustration.

Referring to FIG. 2, the measurement unit 40 may be located on one side of the test unit 10. The measurement unit 40 may detect a driving state of the test unit 10 or a change state of the test piece P located in the test unit 10. The measurement unit 40 may include a detection sensor 410 and a potentiometer 420.

The sensing sensor 410 may be positioned adjacent to the jig 110. For example, the sensing sensor 410 may be fixed to the top of the frame 20 adjacent to the jig 110. The detection sensor 410 is provided to detect the distance between the first jig member 111 and the second jig member 112 or the test piece P gripped by the jig 110. As an example, the detection sensor 410 may be provided as a laser displacement meter facing the jig 110, so that measurement can be made by receiving a reflected laser after irradiating the laser with the jig 110.

The potentiometer 420 may be positioned to face the jig 110. For example, the potentiometer 420 may be fixed to the frame 20 by a support rod 421 having a set length. The lower portion of the support rod 421 may be connected to the frame 20 by the base 423. The base 423 is provided with a magnetic material, and may be fixed to the frame 20 made of a metal material. The potentiometer 420 is provided to detect the distance between the first jig member 111 and the second jig member 112, or the state in which the test piece P held by the jig 110 is tensioned. For example, the potentiometer 420 is positioned to be connected to the first jig member 111 and the second jig member 112 to detect this when the distance between the first jig member 111 and the second jig member 112 changes Can be provided.

The controller 50 controls the components of the tensile testing device 1. The controller 50 may open the opening / closing member 321 when a predetermined amount of gas is accommodated in the receiving member 320 or when the inner space of the receiving member 320 reaches the set pressure. In addition, the controller 50 may open the opening / closing member 321 when the set time elapses after the pressure increasing member 310 starts supplying the compressed gas to the receiving member 320. The controller 50 may include an operation unit 510 and a display unit 520.

The operation unit 510 allows a user to input a command for operating the operating state of the tensile testing device 1. The operation unit 510 can input a command to start the operation of the tensile test device 1, a command to stop the operation of the tensile test device 1, a command to make the state of the tensile test device 1 to the initial state, and the like. Can be provided.

The display unit 520 may cause the operating state of the tensile test device 1 by the controller 50, a value detected by the load meter 122, or a value detected by the measurement unit 40. For example, the display unit 520 is the force acting on the test piece P by the jig 110, the separation distance between the first jig member 111 and the second jig member 112, the test piece (P) is tensioned Length, etc. can be displayed.

3 is a view showing a jig in which the test piece is located, and FIG. 4 is a view showing a jig member.

Since the first jig member 111 and the second jig member 112 are symmetrically positioned with respect to adjacent surfaces, the structures are the same or similar, and thus will be described together.

3 and 4, the test piece P connects the first gripping region P1 and the second gripping region P2, and the first and second gripping regions P1 and P2. And a connection region P3 having a narrower cross-sectional area than the second gripping regions P1 and P2. The jig members 111 and 112 may be provided in a block shape having a set volume. The gripping space 115 is formed on one side of the jig members 111 and 112. The first jig member 111 and the second jig member 112 are arranged such that the gripping space 115 faces each other. The gripping space 115 of the first jig member 111 grips the first gripping area P1, and the gripping space 115 of the second jig member 112 grips the second gripping area P2.

The gripping space 115 is provided in the form of a groove from the outside of the jig members 111 and 112 toward the center region, and the jig members 111 and 112 are wavered in regions facing each other around the gripping space 115. The ground 116, 117 is formed. As for the gripping surfaces 116 and 117, the jig members 111 and 112 are located in a direction in which the jig members 111 and 112 face each other, and the jig members 111 and 112 are located relative to the first gripping surface 116. It may be divided into a second gripping surface 117 positioned in the spaced apart direction. The distance between the second gripping surfaces 117 spaced apart from each other about the gripping space 115 is formed to be larger than the distance from which the first gripping surfaces 116 are spaced apart from each other. Accordingly, when the test piece P having a shape corresponding to one end of the gripping space 115 is located in the gripping space 115, the test piece P is supported by the first gripping surface 116, and the jig member (111, 112) can be prevented from falling out in the direction apart from each other.

 The jig members 111 and 112 may be provided with rollers 118 and 119. The rollers 118 and 119 may be provided in a form exposed toward the gripping space 115. The direction of the rotation axis of the rollers 118 and 119 may be provided in a direction perpendicular to the direction in which the jig members 111 and 112 are spaced apart from each other and the direction in which the gripping surfaces 116 and 117 face each other. The rollers 118 and 119 may be provided on both sides of the gripping space 115 facing each other. The rollers 118 and 119 may be located on the first gripping surface 116. The first rollers 118 are provided in a pair, and are spaced apart from each other by a predetermined distance, coupled to the lower end of the first jig member 111, and provided to be rotatable relative to the first jig member 111. The second roller 119 is provided in a pair, and is spaced apart from each other by a predetermined distance, coupled to the upper end of the second jig member 112, and provided to be rotatable relative to the second jig member 112.

Hereinafter, an operation process of the tensile test apparatus 1 according to an embodiment of the present invention will be described.

The gas at the set pressure is supplied to the pressure increasing member 310 through the gas supply pipe 311. At this time, the pressure of the gas supplied to the pressure increasing member 310 may be adjusted through the pressure adjusting member 315. The gas supplied to the pressure increasing member 310 may be filled in the receiving member 320 after the pressure is increased by the pressure increasing member 310. The process of increasing the pressure by the pressure-increasing member 310 and storing the gas in the receiving member 320 may be performed until the set amount of gas is stored in the receiving member 320 or the pressure of the gas received in the receiving member 320. It can be done until the set pressure is reached. In addition, the amount of gas accommodated in the receiving member 320 or the pressure of the gas received in the receiving member 320 may correspond to the test capacity when the tensile testing device 1 is operated. Accordingly, when performing a tensile test, depending on the load applied to the test piece P, the amount of gas accommodated in the receiving member 320 or the pressure of the gas received in the receiving member 320 may be changed. For example, the user may select a capacity to be used in the process of performing a tensile test through the operation unit 510, and correspondingly, the amount of gas accommodated in the receiving member 320 or the pressure of the gas received in the receiving member 320 Can be adjusted.

When the set amount of gas is received in the receiving member 320, the controller 50 opens the opening / closing member 321 so that the gas accommodated in the receiving member 320 flows into the driving member 330, and accordingly the drive shaft By operating 126, the first jig member 111 and the second jig member 112 are spaced apart from each other to increase the tensile test.

5 is a view showing a time-displacement relationship when the tensile test apparatus according to an embodiment of the present invention is driven without a test piece.

5, the tensile test apparatus 1 according to an embodiment of the present invention is provided to be driven by adjusting the gas accommodated in the receiving member 320, the capacity range used in the tensile test is 0.5kN to 10kN As such, a wide range of test doses can be provided.

6 to 10 are views showing an instantaneous rate of change of time-displacement data of a tensile test apparatus according to an embodiment of the present invention.

Figure 6 shows the instantaneous speed at 0.5 kN capacity, Figure 7 the instantaneous speed at 1.0 kN capacity, Figure 8 the instantaneous speed at 2 kN capacity, and Figure 9 the instantaneous speed at 5 kN capacity. 10 is a diagram showing an instantaneous velocity at a capacity of 10 kN.

5 to 10, in the tensile test apparatus 1 according to an embodiment of the present invention, even when the capacity used for the tensile test is changed, the value of the displacement generated by the tensile test appears faster than the conventional equipment .

Specifically, the tensile test apparatus 1 according to an embodiment of the present invention is about 500 mm / s at a capacity of 0.5 kN, about 1400 mm / s at a capacity of 1.0 kN, about 2000 mm / s at a capacity of 2 kN, 5 kN Testing is possible at a speed of about 4000 mm / s at a capacity and about 6000 mm / s at a capacity of 10 kN. Accordingly, while the tensile test apparatus 1 according to an embodiment of the present invention is provided with a wide range of tensile tests, the test can be completed in a short time.

11 is a view showing an instantaneous rate of change of time-displacement data of conventional equipment.

5 and 11, the displacement value of the conventional equipment (Static) appears slower than the displacement value when using the tensile test apparatus 1 according to an embodiment of the present invention, and the value of the time axis is enlarged and observed If it does, it has a value close to 0.

12 is a diagram showing the correlation between the strain rate range and the tensile test.

Referring to Figure 12, depending on the range of the strain rate, the type of tensile test corresponding to this varies.

The strain velocity (ε / s) can be defined as the displacement velocity divided by the gauge length of 180 mm. Strain rates of 10 ^-6 or less can occur in creep. Strain rates below 10 ^-4 can occur at quasi-static loads. Strain rates of 10 ^-5 to 10 ¹ can occur in dynamic loads such as vehicle collisions or earthquakes. Strain rates of more than 10 ¹ can occur at explosive impact loads such as explosions.

The strain rate (A) by conventional equipment could only be carried out by tensile tests corresponding to some sections of quasi-static loads or dynamic loads of about 10 ^-4 .

On the other hand, the tensile test apparatus 1 according to an embodiment of the present invention has a strain rate range (B) of 2.8 Х 10 ⁰ to 3.3 Х 10 ¹ . Accordingly, the tensile test apparatus 1 according to an embodiment of the present invention is capable of experimenting to simulate dynamic loads and impact and explosion loads.

13 is a view showing the test results of the tensile test apparatus and the conventional apparatus according to an embodiment of the present invention for the same specimen.

In the tensile test, a fiber drawing test piece (P) in which straight steel fibers were inclined at an angle of 45 degrees was used for ultra-high performance concrete.

Referring to FIG. 13, when the test was performed in the form of a static load by a conventional device, the maximum load is about 75 N.

On the other hand, when tested at 8 kN capacity by the tensile testing device 1 according to an embodiment of the present invention, it can be seen that the maximum load increased more than 2 times even though the maximum load was about 169 N. This difference is influenced by the load speed, and when the tensile test is performed at a high speed, such as the tensile test apparatus 1 according to an embodiment of the present invention, it is possible to grasp the change in material properties according to the load speed.

The above detailed description is to illustrate the present invention. In addition, the above-described content is to describe and describe preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications and environments. That is, it is possible to change or modify the scope of the concept of the invention disclosed herein, the scope equivalent to the disclosed contents, and / or the scope of the art or knowledge in the art. The embodiments described describe the best conditions for implementing the technical spirit of the present invention, and various changes required in specific application fields and uses of the present invention are possible. Accordingly, the detailed description of the invention is not intended to limit the invention to the disclosed embodiments. In addition, the appended claims should be construed to include other embodiments.

10: test unit 20: frame
30: drive unit 40: measuring unit
50: controller 110: jig
121: first support member 125: second support member
310: boosting member 320: receiving member
330: driving member 410: detection sensor
420: potentiometer

Claims (10)

In the tensile test apparatus for a test piece having a connection region having a cross-sectional area narrower than the first and second gripping regions, connecting the first gripping region and the second gripping region, and the first and second gripping regions,
A test unit having a jig for gripping the test piece and allowing the test piece to be tensioned so that a tensile test can be made; And
A driving unit connected to the test unit, the driving unit providing power to operate the test unit,
The test unit
A first jig member having a gripping space in which the first gripping region is located;
A second jig member positioned below the first jig member and having a gripping space in which the second gripping area is located;
A pair of first rollers spaced apart from each other by a predetermined distance, coupled to the lower end of the first jig member, and rotatable relative to the first jig member; And
It is disposed parallel to each other with the first roller, and coupled to the upper end of the second jig member, and includes a pair of second rollers that are rotatable relative to the second jig member,
The first rollers grip the upper ends of the connection areas on both sides of the test piece,
The second rollers grip the lower ends of the connection areas on both sides of the test piece,
The tensile test apparatus has a strain rate range of 2.8 X 10 ⁰ to 3.3 X 10 ¹ , and a tensile test apparatus capable of simulating impact and explosion loads. delete delete delete delete According to claim 1,
The test unit,
A first support member connected to the first jig member; And
Further comprising a second support member connected to the second jig member,
The second support member is connected to the second jig member, the drive shaft is provided to be movable along the longitudinal direction; And
Located on the outer circumference of the drive shaft, and includes a support for supporting the drive shaft,
The drive unit,
A pressure-increasing member provided to be connected to a gas supply pipe, and provided to be discharged after increasing the pressure of the gas introduced through the gas supply pipe; And
Tensile test apparatus including a driving member to move the drive shaft through the gas discharged from the pressure increasing member. The method of claim 6,
The drive unit,
Tensile test device further comprises a receiving member that is located between the pressure-increasing member and the driving member to store gas discharged from the pressure-increasing member. The method of claim 7,
An opening and closing member is positioned between the receiving member and the driving member,
The tensile testing device further comprises a controller for opening the opening / closing member when a predetermined amount of gas is accommodated in the receiving member or the inner space of the receiving member reaches a set pressure. The method of claim 7,
An opening and closing member is positioned between the receiving member and the driving member,
The tensile testing device further comprises a controller for opening the opening / closing member when a set time elapses after the pressure increasing member starts supplying compressed gas to the receiving member. According to claim 1,
Tensile test apparatus, the capacity range of the test unit acting on the test piece is 0.5kN to 10kN.

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