KR20120097179A - Tensile test device - Google Patents

Abstract

PURPOSE: A tensile testing device is provided to provide magnetic force on a magnetic grip unit when extending a fixed specimen, thereby preventing the specimen from being slipped from the magnetic grip unit. CONSTITUTION: A tensile testing device comprises a tensile driving unit(100) and magnetic grip units(130). The tensile driving unit is moved up to a direction where an upper body and a lower body are separated from each other, thereby extending the specimen by connecting the specimen to between the upper and lower bodies. The magnetic grip unit is embedded in the lower part of the upper body and the upper part of the lower body and fixes both sides of the specimen by inserting and controls the generation of magnetic force according to supplied power.

Description

Tensile Test Equipment {TENSILE TEST DEVICE}

The present invention relates to a tensile test apparatus, and more particularly, to a tensile test apparatus that can improve the reliability of the tensile test by firmly fixed and tensioned plate-shaped specimens.

In general, tensile tests are conducted to investigate the mechanical properties of materials.

Here, the tensile test is carried out by cutting a tensile test piece (hereinafter referred to as a test piece) from a material and fixing it to a tensile tester.

At this time, the tensile load is gradually applied to the specimen to measure mechanical properties such as yield point and tensile strength of the material. As a result, the specimen should be fixed without shaking to improve the reliability of the test.

An object of the present invention is to apply a magnetic to the gripper (Gripper) to fix the specimen more firmly fixed, thereby preventing the separation of the specimen to extend the life of the gripper, tensile test apparatus that can improve the reliability of the tensile test In providing.

According to the idea of the present invention, the tension driving unit for driving the lifting and lowering in the direction in which the upper body and the lower body are spaced apart from each other to connect and tension the specimen between the upper body and the lower body; And a magnetic grip part inserted into and fixed to both ends of the specimen by being restrained and embedded at the lower end of the upper body and the upper end of the lower body, and controlling the generation of magnetic force according to the supplied power.

First, the magnetic grip portion, the grip body to form a receiving space therein; A magnetic block embedded in the receiving space of the grip body and provided to generate a magnetic force; And a connection cable connected to the magnetic block and receiving power supplied from the outside and transferring the power to the magnetic block.

At this time, the grip body, it is preferable that a plurality of grooves are formed in the longitudinal direction so that the specimen is rubbed on the surface in contact with the specimen.

And the magnetic block is formed in the grip body in one or a plurality, it is preferable that a magnetic force is generated by using the power received through the connection cable.

In addition, the magnetic grip portion is preferably formed so as to be opposite from one side or both sides about both ends of the specimen to insert and fix both ends of the specimen.

The tension driving unit is connected to the side of the upper body and the lower body, the guide shaft for guiding the drive, the lower body of the upper body and the lower body; further comprises a structure.

And tension test apparatus according to the present invention may further include an adjustment control unit for adjusting the lifting, lowering drive and the magnetic force generation of the tensile drive portion.

At this time, the adjustment control unit, the power supply unit is connected to the tension driving unit and the magnetic grip unit for applying power; And a remote switch unit for controlling the tension driving unit and the magnetic grip unit by converting a command input from a user into an electrical signal to control the tension driving unit and the magnetic grip unit to which power is applied by the power supply unit. It is preferable.

The present invention provides a magnetic force to the magnetic grip portion when fixing and tensioning the specimen, thereby preventing the specimen from slipping from the magnetic grip portion, thereby providing an effect of extending the life of the magnetic grip portion to reduce the production cost.

In addition, the present invention provides an effect that can ensure the reliable data of the tensile test by preventing the phenomenon that the specimen is firmly fixed and slipped from the magnetic grip portion.

1 is a view schematically showing a tensile test apparatus according to an embodiment of the present invention,
Figure 2 is a view showing in detail the magnetic grip portion of the tensile test apparatus according to an embodiment of the present invention,
3 is a view illustrating a magnetic grip part detachably mounted to a tension driving part in a tensile test apparatus according to an embodiment of the present invention;
4 is a view showing the operating relationship between the configuration of the tensile test apparatus according to an embodiment of the present invention.

The present invention relates to a tensile test apparatus, although various types of specimens that can be used in the tensile test may be used, and the specimens in the form of plates will be described as examples.

With reference to the accompanying drawings will be described with respect to the bending bending fatigue test breakdown apparatus of the present invention.

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

Referring to FIG. 1, the tensile test apparatus 100 includes a tension driving part 110 driving up and down for tensile test of a specimen, and a magnetic grip part 130 formed to further fix the specimen through magnetic force. do.

First, the tension driving unit 110 will be described.

The tension driving unit 110 is formed in a structure including an upper body 112, a lower body 114 and the guide shaft 116.

The upper body 112 and the lower body 114 are formed to face each other in the axial direction.

And the lower end of the upper body 112 and the upper end of the lower body 114, the magnetic grip 130 is made of a structure that is embedded in the restraint.

The guide shaft 116 is connected to side surfaces of the upper body 112 and the lower body 114.

At this time, the guide shaft 116 is formed to guide the driving of the upper and lower body 112 and the lower body 114, the lowering.

That is, the tension driving unit 110, after connecting the specimen to the lower end of the upper body 112 and the upper end of the lower body 114, the upper body 112 and the lower body 114 by the guide shaft 116 It is preferable to drive up and down in a direction spaced from each other.

Next, the magnetic grip unit 130 will be described.

The magnetic grip part 130 is formed to fix the specimen provided for the tensile test without shaking at both ends in the vertical direction.

In order to fix the specimen as described above, the magnetic grip 130 is embedded in the lower end of the upper body 112 and the upper end of the lower body 114 of the tension driving unit 110, respectively.

The magnetic grip unit 130 may be formed to be opposite to one side or both sides about both ends of the specimen to insert and fix both ends of the specimen.

At this time, when the magnetic grip portion 130 is opposed to both sides can be more effectively fixed to the specimen.

In addition, the magnetic grip unit 130 is formed to adjust the magnetic force generation in accordance with the power supplied from the outside.

That is, the magnetic grip unit 130, through the generation of magnetic force, provides an effect that can more securely fix the specimen.

As a result, the magnetic grip unit 130 may be configured to firstly fix both ends of the specimen, and secondly to more firmly fix the specimen by generating magnetic force.

On the other hand, the tensile test apparatus 100 may further include an adjustment control unit 150 to adjust the magnetic force generation of the tension driving unit 110 and the magnetic grip unit 130 is driven up and down.

The adjustment control unit 150 is connected to the tension driving unit 110 and the magnetic grip unit 130 may adjust the power supply and driving.

Figure 2 is a view showing in detail the magnetic grip portion of the tensile test apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the magnetic grip unit 130 includes a grip body 132 forming a frame, a magnetic block 134 embedded in the grip body 132, and an external supply of the magnetic block 134. It includes a connection cable (not shown) for connecting a power source.

As shown, the grip body 132 forms a receiving space therein.

One side of the grip body 132 is in contact with the specimen. At this time, the grip body 132, it is preferable that a plurality of grooves are formed in the longitudinal direction so that the specimen is rubbed on the surface in contact with the specimen.

In this case, when the specimen is in contact, a strong friction force is applied to the specimen to firmly fix the specimen. In addition, it may be possible to prevent the specimen from falling out during the tensile test.

In addition, since a strong frictional force is applied to the specimen, the specimen may be prevented from slipping from the magnetic grip portion 130.

In addition, as the occurrence of wear is reduced on the surface in contact with the specimen may be provided up to the effect of extending the life of the magnetic grip portion 130.

And by firmly fixing the specimen, it is possible to secure reliable data of the tensile test results.

In addition, the shape of the grip body 132 shown is only one example for schematically illustrating the illustrated drawings, the present invention need not be limited thereto.

And grip body 132 is preferably made of a conductive material.

The conductive material may correspond to a metal and the like, and due to the magnetic block 134 in which magnetic force is generated, the contacted specimen may be more firmly fixed.

The illustrated magnetic block 134 is embedded in the accommodation space of the grip body 132.

In this case, one or more magnetic blocks 134 may be formed in the grip body 132.

Here, the magnetic block 134 may further fix the specimen to be contacted according to the strength and number of the magnetic force. In this case, the specimen is made of a plate shape, preferably made of a conductive material.

In addition, the magnetic block 134 may be a magnetic force is generated using the power received from the outside through a connection cable. Herein, the magnetic block 134 may generate magnetic force only when power is applied.

As a result, the magnetic block 134 is preferably an electromagnet.

As an example of such a magnetic block 134, a solenoid and a superconducting magnet may be used.

In addition, the upper portion of the illustrated magnetic grip portion 130, the screw groove may be formed to be built-in restraint in the tension driving portion.

In this case, the upper portion of the magnetic grip unit 130 is only described as an example to explain the structural positional relationship shown.

In this case, the magnetic grip 130 may be detached from the tension driving unit through the screw groove shown in FIG. This process will be described with reference to FIG. 3.

3 is a view illustrating a magnetic grip part detachably mounted to a tension driving part in a tensile test apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 3, it can be seen that the magnetic grip 130 is detached and mounted on the upper body 112 of the tension driving unit.

At this time, the illustrated magnetic grip portion 130 is shown to be mounted, detached from the lower end of the upper body 112 of the tension driving unit. The removal and mounting process of the magnetic grip unit 130 is just one example, and the present invention is not limited thereto. Therefore, the magnetic grip 130 is preferably made of a structure that is detached and mounted to the upper body 112 and the lower body of the tension driving unit, respectively.

In order to help understand the structure of the detachment and mounting, the positional relationship between the tension driving unit and the magnetic grip unit 130 will be described.

The illustrated magnetic grip portion 130 is restrained and embedded in the lower end of the upper body 112 of the tension driving portion, it may be fastened through the bolt (B) when mounted.

The fastening method through the bolt (B) is just one example, the present invention need not be limited thereto.

4 is a view showing the operating relationship between the configuration of the tensile test apparatus according to an embodiment of the present invention.

Referring to FIG. 4, the tensile test apparatus includes a tension driving unit 110 driven up and down, a magnetic grip unit 130 formed to further fix the specimen S through magnetic force, and a tension driving unit 110. , An adjustment control unit 150 for adjusting the downward driving and generating the magnetic force of the magnetic grip unit 130.

Since the tension driving unit 110 and the magnetic grip unit 130 have been described above with reference to FIGS. 1 to 3, redundant description thereof will be omitted.

The adjustment control unit 150 includes a power supply unit 152 and a remote switch unit 154.

The power supply unit 152 is connected to the tension driving unit 110 and the magnetic grip unit 130 is formed to apply power.

The remote switch unit 154 is formed to control the tension driving unit 110 and the magnetic grip unit 130 to which power is applied by the power supply unit 152.

In this case, the remote switch unit 154 may convert the command input from the user into an electrical signal to control the tension driving unit 110 and the magnetic grip unit 130.

Hereinafter, the operation relationship of the tensile test apparatus will be described.

Tensile test apparatus is driven up and down in the direction in which the upper body 112 and the lower body 114 of the tension driving unit 110 is separated from each other in order to determine the mechanical properties of the specimen (S) is subjected to a tensile test.

In order to perform such a tensile test, first, the specimen (S) is inserted into and connected to the lower end of the upper body 112 and the lower body 114 of the tension driving unit 110.

At this time, the magnetic grip 130, which is restrained and embedded in the lower end of the upper body 112 and the upper end of the lower body 114, respectively, fixes the vertical ends of the specimen (S).

Thereafter, power is supplied to the tension driving unit 110 and the magnetic grip unit 130 through the power supply unit 152 of the adjustment control unit 150.

In this case, each power supply may be supplied through an interconnected cable (not shown).

The tension driving unit 110 and the magnetic grip unit 130 supplied with the power are controlled through the remote switch unit 154.

The remote switch unit 154 controls the tension driving unit 110 and the magnetic grip unit 130 by converting a command input from the user into an electrical signal.

In more detail, the remote switch unit 154, the upper body 112 and the lower body 114 of the tension driving unit 110 may be adjusted in the direction of lifting up and down.

In addition, the remote switch unit 154, the user of the magnetic grip unit 130 may selectively adjust the power to the magnetic block 132.

At this time, when the power is applied to the magnetic block 132 through the remote switch unit 154, the magnetic force is provided to the magnetic grip unit 130 that is fixing the specimen (S) at both ends in the vertical direction, the specimen more firmly (S) can be fixed.

Thus, when the upper body 112 and the lower body 114 of the tension driving unit 110 is adjusted up and down along the guide shaft 116, the specimen (S) fixed to the magnetic grip portion 130 is separated Can be prevented.

In addition, by firmly fixing the specimen (S), it is possible to secure a reliable tensile test data and at the same time reduce the wear of the magnetic grip portion 130, it can provide an effect that can extend the life.

As described above, according to the present invention, a magnetic force may be provided to the magnetic grip portion fixing the specimen, thereby preventing the phenomenon of slipping from the magnetic grip portion fixing the specimen when the specimen is tensioned.

At the same time, by extending the life of the magnetic grip portion, there is an effect that can reduce the production cost.

In addition, by preventing the specimen from slipping from the magnetic grip portion, it is possible to secure reliable data of the tensile test.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, the present invention is not limited to the above embodiments but may be manufactured in various forms, and having ordinary skill in the art to which the present invention pertains. It will be appreciated that the person may embody other specific forms without changing the technical spirit or essential features of the present nickname. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

100: tensile testing device
110: tension driving unit
112: upper body
114: lower body
116 guide shaft
130: magnetic grip
132: grip body
134: magnetic block
150 control unit
152: power supply
154: remote switch unit
S: Psalm
B: Bolt

Claims (8)

A tension driving unit which drives the upper body and the lower body in a direction in which the upper body and the lower body are spaced apart from each other so as to tension the specimen; And
And a magnetic grip part inserted into and fixed to both ends of the specimen by being restrained and embedded in the lower end of the upper body and the upper end of the lower body, and controlling the generation of magnetic force according to the supplied power.
The method of claim 1,
The magnetic grip portion,
A grip body forming an accommodation space therein;
A magnetic block embedded in the receiving space of the grip body and provided to generate a magnetic force; And
And a connection cable connected to the magnetic block and receiving power supplied from the outside to the magnetic block.
The method of claim 2,
The grip body,
Tensile testing apparatus characterized in that a plurality of grooves are formed in the longitudinal direction so that the specimen is rubbed on the surface in contact with the specimen.
The method of claim 2,
The magnetic block,
Tensile test device characterized in that the magnetic body is generated by using one or a plurality of inside the grip body, the power received through the connection cable.
The method of claim 1,
The magnetic grip portion,
Tensile test apparatus, characterized in that the opposite side is formed on one side or both sides with respect to both ends of the specimen to insert and fix both ends of the specimen.
The method of claim 1,
The tension driving unit,
And a guide shaft connected to side surfaces of the upper body and the lower body to guide the driving of the upper body and the lower body.
The method of claim 1,
Tensile test apparatus further comprises; an adjustment control unit for adjusting the lifting, lowering driving of the tension driving unit and the magnetic force generation of the magnetic grip unit.
The method of claim 7, wherein
The adjustment control unit,
A power supply unit connected to the tension driving unit and the magnetic grip unit to apply power; And
And a remote switch unit for controlling the tension driving unit and the magnetic grip unit by converting a command input from a user into an electrical signal to control the tension driving unit and the magnetic grip unit to which power is applied by the power supply unit. Tensile test device characterized in that.

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