KR101642422B1 - Device for adjusting grip gap in high speed tensile tester - Google Patents

Abstract

The present invention relates to a gap adjusting device for adjusting the spacing of jaws of a high-speed tensile tester, which comprises a body coupled to a high-speed tensile tester, a rotating part coupled to the upper end of the body for rotation, ≪ / RTI &
Adjusting the height of the wedge adjusts the spacing of the jaws of the high-speed tensile tester.

Description

TECHNICAL FIELD [0001] The present invention relates to a high-speed tensile tester,

The present invention relates to a gap adjusting device for adjusting the gap of a jaw of a high-speed tensile tester, and more particularly, to a gap adjusting device for automatically adjusting a gap of a jaw of a high-speed tensile tester according to a thickness of a test piece.

Typically, a typical test method used for evaluating mechanical properties of a metal material is tensile test, and data such as yield strength, tensile strength, work hardening index, stress coefficient, and uniform elongation can be obtained. Such a tensile test method serves to calculate the above-mentioned mechanical properties by applying a tensile force to the test specimen, and to contribute to the application of steel having mechanical characteristics to appropriate fields.

Such a tensile test method can be divided into a static tensile test and a dynamic tensile test. The static tensile test is a generally used method in which both sides of a test piece are fixed and at least one of them is pulled by a predetermined hydraulic device or an interpolated screw device to measure the mechanical properties at the time of fracture of the test piece.

As a dynamic tensile test method, a high-speed tensile testing machine is generally used. It is a method of pulling a test piece at a predetermined speed or more and is mainly used for evaluating dynamic properties of a material.

Recently, due to the development of the automobile industry, mechanical characteristics of automobile steel material are mainly required due to external impact and collision which may occur in a high-speed running automobile, so it is a tendency to prefer a high-speed tensile test rather than a static tensile test.

A high-speed tensile test is carried out to determine tensile properties at high speeds for automotive materials. Prior to testing, work is done to align jaws with test specimens. This is a very important task because it greatly affects the accuracy of the test data.

Conventionally, in the work of matching the gap between the jaw and the test piece, the operator confirms with the naked eye every time the test piece is changed, and the tensile test is performed after the test using the interval measuring machine.

The interval between the jaws and the test piece is adjusted by the user, the intervals of the jaws can be irregularly set, and there is a problem that a lot of work time is required to adjust the interval of the jaw oil.

Korean Patent Publication No. 10-2005-0098416 (published on October 12, 2005) Korean Patent Publication No. 10-2002-0049080 (published on June 26, 2002)

The spacing adjusting device for adjusting the spacing of the jaws in the high-speed tensile tester according to the present invention has been developed in order to solve the above-mentioned problems of the prior art. Regulating device.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

The spacing adjusting device for adjusting the spacing of the jaws of the high-speed tensile testing machine according to the present invention has the following problems in order to solve the above-mentioned problems.

The apparatus for adjusting the spacing of the jaws of the high-speed tensile tester according to the present invention comprises: a body coupled to a high-speed tensile tester; And a rotation unit coupled to the upper end of the body so as to be rotatable to adjust the height of the wedge of the high-speed tensile tester. The height of the wedge may be adjusted to adjust the interval of the jaws of the high-speed tensile tester.

The rotation unit includes a fixed plate provided on the body and rotatable; And a moving plate which is located below the fixing plate and is provided so as to move away from or closer to the fixing plate, thereby controlling the height of the wedge by movement of the moving plate.

Wherein the rotary portion is a gear shaft provided so as to penetrate through the moving plate and rotatable about an axis passing through the moving plate and being restricted in movement in the moving direction of the moving plate and having a gear at an upper end; And a motor that includes a gear engaged with the gear of the gear shaft. As the motor operates, the gear of the motor meshes with the gear of the gear shaft to rotate the gear shaft so that the moving plate moves away from or closer to the fixed plate .

Preferably, the moving plate further includes a cylinder connected to a fixing pin passing through the moving plate, wherein one end of the fixing pin is connected to the cylinder, and the other end is engageable with the wedge.

The projection of the fixing pin is engaged with the projection in the projection groove formed in the wedge when the cylinder is advanced. When the cylinder is moved backward, the projection of the fixing pin is formed in the wedge And is preferably separated from the projection in the projection groove.

The rotation unit includes a guide pin for preventing the moving plate from being detached from the fixing plate. The guide pin is installed through the fixing plate. One end of the guide pin is fixed to the moving plate. It is preferable that a spring is provided to provide an elastic force such that the jaw is away from the fixing plate.

Preferably, the body further includes a meter for measuring the height of the wedge.

The gap adjusting device for adjusting the gap of the jaws of the high-speed tensile tester according to the present invention having the above-described structure has the following effects.

First, it offers the advantage of precisely adjusting the spacing of jaws in a high-speed tensile testing machine.

Second, since the distance between the specimen and the jaw can be precisely adjusted, it is possible to collect tensile test data with high reliability for the specimen.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a perspective view of a conventional high-speed tensile testing machine.
2 is a view for explaining a gap between a test piece and a jaw provided in a conventional high-speed tensile tester.
FIG. 3 is a view for explaining a method of adjusting the spacing of the jaws.
4 is a perspective view of a gap adjusting device according to an embodiment of the present invention.
5 is a view showing a state where a gap adjusting apparatus according to an embodiment of the present invention is installed in a high-speed tensile tester.
6 is a view showing a state in which the rotation part of the gap adjusting device is separated from the high-speed tensile tester according to the embodiment of the present invention.
7 is a view showing data obtained by operating the high-speed tensile tester.

The spacing adjusting device for controlling the spacing of the jaws of the high-speed tensile testing machine according to the present invention may be variously modified and may have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail below . It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Hereinafter, with reference to the drawings, a gap adjusting device for adjusting the gap of the jaws of the high-speed tensile tester according to an embodiment of the present invention will be described in detail.

1 is a perspective view of a conventional high-speed tensile testing machine. 2 is a view for explaining the interval between the test piece 1 and the jaw 150 installed in the conventional high-speed tensile tester.

As shown in FIG. 1, the high-speed tensile tester 100 includes an upper grip 120 for fixing the upper portion of the test piece 1 to the apparatus frame 110 and a lower grip 120 for fastening the lower portion of the test piece 1 And a U-shaped lower grip 130 is provided.

The upper grip 120 is made of two members, and the two members facing each other are tapered so that when one member of the two members is raised, the gap between the two members is narrowed. When the two members are lowered, As shown in Fig.

Therefore, in the state that the test piece 1 is positioned between the two opposing members of the upper grip 120, one member of the two members is raised to fix the upper portion of the test piece 1.

The lower grip 130 is U-shaped as described above, and the cylinder 131 is connected to the lower end of the lower grip 130, so that the lower grip 130 can move up and down.

Two jaws 150 are fixed at the center of the upper end of the lower grip 130 and an inclined member 190 is fixed to the outer side of the jaws 150, respectively.

A guide 170 to which the wedge 140 capable of abutting the inclined members 190 is fixed is fixed to both sides of the moving hole 180 through which the lower grip 130 moves, Is installed.

At the upper end of the lower grip 130, there is provided a tightening bolt 160 which can apply force thereto.

Therefore, when the upper part of the test piece 1 is fixed by the upper grip 120 and the tightening bolt 160 is tightened with the wedge 140 abutting the inclined member 190, The upper end of the lower grip 130 does not move because the reaction force against the force is generated because the wedge 140 is abutted against the inclined member 190 as shown in the figure.

The lower portion of the test piece 1 is positioned between the jaws 150 fixed to the upper end of the lower grip 130 and the test piece 1 and the jaws 150 are kept in close contact with each other at a constant interval t mm). For example, it is possible to use a method in which the test piece 1 is kept in close contact with one of the two jaws 150 and spaced apart from the other jaws 150.

Therefore, the upper part of the test piece 1 is fixed by the upper grip 120, and the lower part of the test piece 1 is positioned at a certain distance from the jaws 150 between the jaws 150.

Here, although the upper end of the lower grip 130 is tightened by the tightening bolt 160, it does not move inward due to the reaction force of the wedge 140, but the force still acts inward by the tightening bolt 160 .

In this state, when the lower grip 130 is lowered by the cylinder 131 connected to the lower end of the lower grip 130, the inclined member 190 fixed to the lower grip 130 descends along the wedge 140 Whereby the wedge 140 is not positioned between the inclined members 190. [

Therefore, the reaction force of the wedge 140 with respect to the force acting on the upper end portion of the lower grip 130 is lost by the tightening bolt 160, so that the upper end of the lower grip 130 is in contact with the force exerted by the tightening bolt 160 As shown in Fig.

As described above, since the lower portion of the test piece 1 is positioned at a predetermined interval between the jaws 150 fixed to the upper end of the lower grip 130, when the upper end of the lower grip 130 moves inward as described above , And the jaws (150) hold the lower portion of the test piece (1).

Therefore, the jaws 150 hold the lower portion of the test piece 1 at a constant speed and descend with the test piece 1, so that the high-speed tensile test of the test piece 1 is performed.

FIG. 3 is a view for explaining a method for adjusting the spacing of the jaws 150.

The reference line 191 is marked on the inclined member 190 and the wedge 140 is marked with the interval of the lines 141, 142, 143 and 144 corresponding to the interval of the jaws 150. [

The reference line 191 of the inclined member 190 and the inclination of the wedge 140 at the position of the inclined member 190 and the wedge 140 that have an appropriate interval (for example, 0.1 mm) when the thickness of the test piece 1 is 3.0 mm The line 143 to be matched is marked. In the same manner, the corresponding lines 141, 142 and 144 are marked when the thickness of the test piece 1 is 1.0 mm, 2.0 mm and 4.0 mm.

The operator can adjust the spacing of the jaws 150 according to the thickness of the test piece 1 by matching the baseline of the inclined member 190 with the lines of the wedge 140.

4 is a perspective view of a gap adjusting device according to an embodiment of the present invention.

The gap adjusting device according to an embodiment of the present invention can adjust the spacing of the jaws 150 of the high-speed tensile testing machine by adjusting the height of the wedge 140.

The gap adjusting device comprises a body part 210 and a rotation part 220.

The body 210 is coupled to the high-speed tensile testing machine 100.

The rotation unit 220 is coupled to the upper end of the body 210 so as to be rotatable, and the height of the wedge 140 of the high-speed tensile tester can be adjusted.

5 is a view showing a state where a gap adjusting apparatus according to an embodiment of the present invention is installed in a high-speed tensile tester.

6 is a view showing a state in which the rotation part 220 of the gap adjusting device is separated from the high-speed tensile tester according to an embodiment of the present invention.

The rotating portion 220 includes a fixed plate 221, a moving plate 226, a gear shaft 229, and a motor 223.

One side of the fixing plate 221 is coupled to the body 210 by a pin so as to be rotatable with respect to the body in one axial direction.

The moving plate 226 is located below the fixing plate 221. The moving plate 226 is installed so as to move away from or close to the holding plate 221.

The gear shaft 229 is installed to penetrate the moving plate 226 and is rotatable about the moving direction of the moving plate 226 so as to limit the movement of the moving plate 226 in the through direction . A gear 229a is formed at the upper end of the moving plate 226. [

The motor 223 includes a gear 223a that meshes with the gear 229a of the gear shaft 229. [ When the motor 223 is operated and rotated, the gear 223a of the motor 223 is engaged with the gear 229a of the gear shaft 229 to rotate the gear shaft 229 so that the moving plate 226 is rotated by the fixed plate 221 ).

The moving plate 226 is provided with a cylinder 228. A fixing pin 227 penetrating the moving plate 226 is connected to the cylinder 228.

One end of the fixing pin 227 is connected to the cylinder 228 and the other end of the fixing pin 227 is engageable with the wedge 140. The other end of the fixing pin 227 can be connected to or disconnected from the wedge 140.

At the other end of the fixing pin 227, a projection 227a is formed. The wedge 140 has a protrusion groove 141 into which the other end of the fixing pin 227 can be inserted.

A protrusion which can contact the protrusion 227a of the fixing pin 227 is formed inside the protrusion groove 141.

When the cylinder 228 advances, the projection 227a of the fixing pin 227 is engaged with the projection in the projection groove 141 formed in the wedge 140.

The rotation unit 220 may further include a guide pin 222 for preventing the moving plate 226 from being detached from the holding plate 221.

One end of the guide pin 222 is fixed to the moving plate 226 and the other end of the guide pin 222 passes through the fixing plate 221. A hook is formed at the other end of the guide pin 222, and a spring is provided between the hook and the fixing plate 221. The spring provides an elastic force such that the latching jaw moves away from the holding plate. When the moving plate 226 moves away from the holding plate 221, the spring is compressed.

The body portion 210 may further include a measuring device 212 for measuring the height of the wedge 140.

The body part 210 may include a cylinder 211 for controlling the rotating part to rotate.

Hereinafter, a process of adjusting the gap of the jaws 150 of the high-speed tensile tester according to an embodiment of the present invention will be described.

A case where the thickness of the test piece 1 is thicker than 1.0 mm will be described.

If the thickness of the test piece 1 is thicker than 1.0 mm, the gap of the jaws 150 should be wider than that of the reference thickness. When the motor 223 of the rotary part 220 is operated while the interval adjusting device of the jaws 150 is installed in the high-speed tensile tester, the gear shaft 229 rotates by the rotation of the gear 223a. The gear shaft 229 can be moved up and down in accordance with the direction in which the gear 223a of the motor 223 rotates.

When the gear shaft 229 also moves downward, the projection 229b formed at the lower end of the gear shaft 229 pushes the wedge 140. [ When the wedge 140 moves downward, the inclined members 190 are spaced apart due to the inclined shape, and the spacing of the jaws 150 also widens. The height of the wedge 140 can be measured through the measuring device 212 to measure the interval of the jaws 150 according to the height of the wedge 140.

When the interval of the jaws 150 is set to correspond to the thickness of (1), the rotating portion 220 is separated from the high-speed tensile tester. Thereafter, the high-speed tensile tester starts the tensile test of the test piece 1.

A case where the thickness of the test piece 1 is thinner than 1.0 mm will be described.

When the thickness of the test piece 1 is thinner than 1.0 mm, the interval of the jaws 150 should be narrower than that of the reference thickness. The rotation of the cylinder 228 of the rotation unit 220 causes the projection 227a of the fixing pin 227 to move to the projection groove 141 of the wedge 140 And is coupled to the formed projection. When the motor 223 is operated to raise the moving plate 226, the cylinder 228 is also raised. When the cylinder 228 is raised, the fixing pin 227 is also raised and the wedge 140 connected to the fixing pin 227 is also raised. As a result, the wedge 140 rises and the gap between the jaws 150 becomes narrow. When the wiper 140 senses the setting height of the wedge 140, the operation of the motor 223 is stopped and the interval of the jaws 150 is automatically set to a set interval.

When the adjustment of the spacing of the jaws 150 is completed, the rotation part 220 is separated from the high-speed tensile tester by the operation of the cylinder 211, and then the high-speed tensile tester starts the tensile test of the test piece 1.

7 is a view showing data obtained by operating the high-speed tensile tester.

Referring to FIG. 7, a graph is tensile test data obtained from a conventional high-speed tensile tester, and a graph b shows a case where the interval of the jaws 150 of the high-speed tensile tester is adjusted by a gap adjusting device according to an embodiment of the present invention And tensile test data obtained from a high-speed tensile tester.

A dynamic tensile load acts on the test piece 1.

When the high-speed tensile test of the test piece 1 is performed using the conventional high-speed tensile testing machine 100, it is required to precisely adjust the distance between the test piece 1 and the jaws 150 as described above.

If the gap between the test piece 1 and the jaw 150 is not suitable for the high-speed tensile test of the test piece 1, the jaw 150 installed on the lower grip 130 moves downward, There is a problem in that accurate high-speed tensile test data can not be obtained because the jaws 150 slip without holding the test piece 1 securely.

In the conventional case, there is a problem that the test data can not be accurately known until the jaws 150 are firmly held by the jaws 150 due to irregular intervals of the jaws 150.

On the other hand, in the case where the interval of the jaws 150 of the high-speed tensile tester is adjusted by the gap adjusting device according to the embodiment of the present invention, the test data in which the applied load is stable can be obtained.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be appreciated that other embodiments may be easily suggested by adding, modifying, deleting, adding, or the like.

The scope of the present invention is defined by the claims, the parentheses used in the claims are not used for optional limitation but are used for the definite components and the description in parentheses is also interpreted as an essential component .

1 Specimen 100 High-speed tensile testing machine
110 device frame 120 upper grip
130 Lower grip 131 Cylinder
140 Wedge 150 Jou
160 tightening bolt 170 guide
180 moving hole 190 inclined member
200 interval adjusting device 201 motor
210 Body portion 211 Cylinder
212 measuring instrument 220 rotating part
221 Fixing plate 222 Guide pin
223 motor 223a gear
226 moving plate 227 fixing pin
228 Cylinder 229 Gear Shaft
229a Gear 229b

Claims (7)

A body coupled to the high-speed tensile tester; And
And a rotation unit coupled to the upper end of the body so as to be rotatable to adjust the height of the wedge of the high-speed tensile tester,
The height of the wedge is adjusted to adjust the gap of the jaws of the high-speed tensile tester,
The rotation unit includes a fixed plate provided on the body and rotatable; And
And a moving plate disposed below the fixing plate and provided to move away from or closer to the fixing plate, wherein the height of the wedge is adjusted by movement of the moving plate.
delete The method according to claim 1,
Wherein the rotary portion is a gear shaft provided so as to penetrate through the moving plate and rotatable about an axis passing through the moving plate and being restricted in movement in the moving direction of the moving plate and having a gear at an upper end; And a motor including a gear engaged with the gear of the gear shaft,
And the gear of the motor engages with the gear of the gear shaft to rotate the gear shaft as the motor is operated, so that the moving plate is moved away from or closer to the holding plate.
The method according to claim 1,
Wherein the moving plate further comprises a cylinder connected to a fixing pin passing through the moving plate,
Wherein one end of the fixing pin is connected to the cylinder and the other end is engageable with the wedge.
5. The method of claim 4,
A projection is formed at the other end of the fixing pin,
When the cylinder advances, the projection of the fixing pin is engaged with the projection in the projection groove formed in the wedge,
Wherein when the cylinder is retracted, the projection of the fixing pin is separated from the projection in the projection groove formed in the wedge.
The method according to claim 1,
Wherein the rotating portion includes a guide pin for preventing the moving plate from being detached from the fixing plate,
Wherein the guide pin is installed to penetrate through the fixing plate and has one end fixed to the moving plate and the other end being provided with a spring for providing an elastic force so that a locking protrusion formed at the other end of the guide pin is away from the fixing plate. Regulating device.
The method according to claim 1,
Wherein the body further comprises a meter for measuring the height of the wedge.

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