KR101267711B1 - Jig for aligning tension sample and tension test apparatus having the same - Google Patents

Abstract

The present invention provides a jig for tensile specimen alignment. The jig is disposed to face each other, the both ends of the tensile test piece is fixed, a pair of fixing parts forming an alignment axis and disposed in each of the pair of fixing parts so as to be movable along a direction orthogonal to the alignment axis. And a measurement unit for measuring the width of the tension specimen to the side and the alignment axis. The present invention also provides a tensile test apparatus having the jig.

Description

Jig for tensile specimen alignment and tensile test apparatus having same {JIG FOR ALIGNING TENSION SAMPLE AND TENSION TEST APPARATUS HAVING THE SAME}

The present invention relates to a tensile test apparatus, and more particularly, to a tensile test piece alignment jig for aligning a tensile test piece in the tensile test and a tensile test device having the same.

In general, the tensile test is a test that continues until the specimen breaks by gradually applying a tensile load on both ends of the specimen.

Conventional tensile test apparatus is composed of a tension drive unit, a specimen fixture, a load measurement unit and a displacement measurement unit. The driving and measuring sections of the tensile tester can be precisely controlled and measured.

When testing plate-like tensile specimens, it is necessary to ensure that the specimen axes of the tensile specimens are aligned with the tensile test axis, and to conduct tests in alignment to obtain reliable tensile test results.

An object of the present invention is to measure the width of the set alignment axis formed in a thin plate and the parallel portion of the tensile specimen at a plurality of positions on the side of the parallel portion tensile tension jig for aligning the tensile specimen and a tensile test having the same In providing a device.

It is another object of the present invention to provide a tensile specimen alignment jig and a tensile test apparatus having the same that can align tensile specimens having parallel portions of various lengths.

The present invention is arranged to face each other, the both ends of the tensile test piece is fixed, a pair of fixing parts forming an alignment axis, and disposed in each of the pair of fixing parts to be movable along a direction orthogonal to the alignment axis It provides a tension specimen alignment jig including a measuring unit for measuring the width of the tension specimen to the side and the alignment axis.

Here, it is preferable that the said measuring part is arrange | positioned in any one position of a position facing each other, or a mutually staggered position.

And, the width is preferably the distance between the side of the parallel portion formed between the alignment axis and both ends of the tensile test piece.

The measuring unit may include a pair of reference members provided at each of the pair of fixing parts such that one end thereof is aligned with the alignment axis, and a reference scale having a zero point on the alignment axis is formed, and the pair of reference members. It is preferred to have a pair of contact members arranged in such a manner as to be movable along a direction perpendicular to the alignment axis, and one end of which is in contact with the side of the parallel portion.

In addition, the tension specimen may be formed of the parallel portion having both sides parallel to each other, a pair of fixed ends formed at both ends of the parallel portion and fixed to the pair of fixed portions, and the parallel portion and the pair of fixed ends. It is formed between a pair of exposed ends exposed to the outside of the pair of fixed ends.

Here, the vertical length of the pair of reference members is preferably formed to correspond to the vertical length of the pair of exposed ends.

In addition, it is preferable that the pair of reference members form a constant gap from the outer circumference of the tensile test piece.

In addition, the contact member preferably forms contact with either the rolling side or rolling contact or point contact.

In addition, the measurement unit may be movable along the alignment axis.

The present invention is arranged to face each other, the both ends of the tensile test piece is fixed, a pair of fixing parts forming an alignment axis, and disposed in each of the pair of fixing parts to be movable along a direction orthogonal to the alignment axis A tensile test including a measuring unit for measuring a width of the tensile test piece to the side and the alignment axis, and a tension driving unit for driving the pair of fixing parts up and down to apply a tensile force along the alignment axis to the tensile test piece. It also provides a device.

The present invention has the effect of aligning the tensile test piece by measuring the width of the set alignment axis formed in a thin plate shape and the parallel part of the tensile test piece at multiple positions on the side of the parallel part.

The present invention also has the effect of aligning tensile specimens having parallel portions of various lengths.

1 is a front view showing a jig for tension specimen alignment of the present invention.
FIG. 2 is an enlarged view of a symbol A of FIG. 1.
3 is a side view showing a jig for alignment of the tensile specimen of FIG.
4 is a front view showing another arrangement of the measuring unit according to the present invention.
5 is a front view showing another arrangement of the measuring unit according to the present invention.
6 is an exploded perspective view showing an example of a measuring unit according to the present invention.
7 is a partially cutaway perspective view showing another example of the measuring unit according to the present invention.
8 to 11 are views showing examples in which the contact member of the measuring unit according to the present invention is in contact with the tensile specimen in various forms.
12 is a cross-sectional view showing an example in which the measuring unit according to the present invention is installed to be movable along the alignment axis direction in the fixing unit.
13 is a view showing a tensile test apparatus of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described a jig for tension specimen alignment of the present invention.

Figure 1 shows the front of the tensile specimen alignment jig of the present invention, Figure 3 shows the side of the jig.

Referring to Figure 1, the tension specimen alignment jig of the present invention is preferably used for the alignment of the tensile specimen 10 of the flake shape.

The tensile test piece 10 has a pair of fixed ends 11 are formed at both ends, and the pair of fixed ends 11 are connected to the parallel portion 12.

A pair of exposed ends 13 are formed at both ends of the pair of fixed ends 11 and the parallel portion 12.

1 and 3, the jig according to the present invention largely grips (or fixes) both ends of the tensile test piece 10, and has a pair of fixing parts 100 forming an alignment axis C0, and the alignment. Measurement units disposed on each of the pair of fixing parts 100 to be movable along a direction orthogonal to the axis C0, and measure a width of the side surface of the tensile test piece 10 and the alignment axis C0. It consists of 200.

The pair of fixing parts 100 includes an upper fixing part 110 and a lower fixing part 120.

The upper fixing part 110 and the lower fixing part 120 are disposed to face each other along the top and bottom.

The upper fixing part 110 fixes the upper fixing end 11 of the tensile test piece 10, and the lower fixing part 120 fixes the lower fixing end 11 of the tensile test piece 10.

As shown in FIG. 3, the upper fixing part 110 includes a pair of upper fixing body bodies 111 and 112 to which the upper fixing end 11 of the tensile test piece 10 is fitted.

The lower fixing part 120 is composed of a pair of lower fixing parts bodies 121 and 122 to which the lower fixing end 11 of the tensile test piece 10 is fitted.

The measuring unit 200 includes a first measuring unit 210 positioned on an upper surface of the lower fixing unit 120 and a second measuring unit 220 positioned on a lower surface of the upper fixing unit 110.

Each of the first and second measurement units 210 and 220 is installed on the pair of reference members 211 and 221 and the pair of reference members 211 and 221 so as to be movable so that the side surfaces of the parallel portion 12 of the tensile test piece 10 are provided. And a pair of contact members 212 and 222 in contact therewith.

The first and second measurement units 210 and 220 may be disposed at positions facing each other with respect to the front of the jig. In detail, the first and second measurement parts 210 and 220 may be arranged side by side on one side of the tensile test piece 10 as shown in FIG. 1, and the front and rear positions may be staggered as shown in FIG. 3. have.

The configuration of the first and second measurement units 210 and 220 is as follows. Here, since the configuration of the first and second measurement units 210 and 220 may be substantially the same, the configuration of the first measurement unit 210 will be representatively described.

The first measuring unit 210 is a first reference member 211 is installed on the upper surface of the lower fixing part 120 through a fastening means (not shown) such as bolts, and at the upper end of the first reference member 211 The first contact member 212 is slidably moved along the direction orthogonal to the alignment axis C0.

Here, one end of the first reference member 211 is disposed to coincide with the alignment axis C0. The first contact member 212 is located at the side of the parallel portion 12 of the tensile test piece 10 at the top of the first reference member 211.

As shown in FIG. 2, the first reference member 211 is formed with a reference scale. The zero point of the reference scale coincides with the alignment axis C0.

In addition, the second measuring unit 220 is installed on the lower surface of the upper fixing unit 110 at a position facing the first measuring unit 210.

In addition, as shown in FIG. 3, the first reference member 211 forms a predetermined gap G with the outer circumference of the tensile test piece 10. The first reference member 211 may not be in contact with the tensile test piece 10 by the gap G.

The second measuring unit 220 includes a second reference member 221 having the same configuration as the first reference member 211 and a second contact member 222 having the same configuration as the first contact member 212. It is composed.

In addition, the vertical lengths H of the first and second reference members 211 and 221 may correspond to the vertical lengths h of the exposed ends 13 at the upper and lower ends of the tensile test piece 10, respectively.

Accordingly, the first and second contact members 212 and 222 of each of the first and second reference members 211 and 221 may flow along the direction to contact the side of the parallel portion 12 of the tensile test piece 10.

In addition, an example illustrated in FIG. 4 or 5 may be adopted as the sliding movement method of the first contact member 212.

Referring to FIG. 4, a rail groove 211a having a predetermined sliding width along a direction perpendicular to the alignment axis C0 is formed at an upper end of the first reference member 211, and a lower end of the first contact member 212. The rail protrusion 212a which is inserted into the rail groove 211a and slidably moves is formed.

Accordingly, the first contact member 212 may be slidably moved to both sides along the rail groove 211a by an external force.

In addition, referring to FIG. 5, a rail groove 211a ′ having a predetermined sliding width and opening at one side thereof is formed at an upper end of the first reference member 211 in a direction orthogonal to the alignment axis C0.

A rail protrusion 212a 'is formed at the lower end of the first contact member 212 and is positioned in the rail groove 211a' and is screwed with the ball screw 230 and further includes a screw hole 212c.

Here, one end of the ball screw 230 may be rotatably supported at one end of the rail groove 211a ', and the other end may be rotatably supported to protrude to the opening side of the rail groove 211a'.

In addition, the other end of the ball screw 230 may be provided with a dial 231.

Accordingly, the first contact member 212 may be slidably moved to both sides according to the rotational operation of the ball screw 230 in a state of being fitted into the rail groove 211a ′.

In the above, examples of the movement method of the first contact member 212 have been described, and all of the slidable configurations other than the above examples may be adopted.

In addition, the first contact member 212 is further provided with a screw hole 212b penetrating up and down. Bolts B are screwed into the screw holes 212b.

When the bolt is fastened to the screw hole 212b, when the lower end of the bolt B presses the upper surface of the first reference member 212, the first contact member 212 has a sliding position on the first reference member 211. Can be fixed.

Referring to the above configuration, each of the upper end fixing end 11 and the lower end fixing end 11 of the tensile test piece 10 is to be fixed to the upper fixing part 110 and the lower fixing part 120 primarily. Can be. The primary fixing may mean a state in which the upper end and the lower end of the tensile test piece 10 can be forcibly flowed to both sides.

The upper and lower fixed ends 110 and 120 are provided with an alignment axis C0 crossing the upper and lower ends. Here, the alignment axis C0 may be used as a reference axis for aligning the specimen axis C of the specimen 10 during the tensile test of the tensile specimen 10.

In addition, one end of the first reference member 211 of the first measurement unit 210 and one end of the second reference member 221 of the second measurement unit 220 form a state coinciding with the alignment axis C0. .

Referring to the above configuration, the specimen axis (C) of the tensile specimen 10 may be misaligned based on the alignment axis (C0).

In this state, the first and second contact members 212 and 222 are provided with an external force to the top and bottom sides of the parallel portion 12 in a direction orthogonal to the alignment axis C0 through the sliding method mentioned above. Can be contacted.

Here, the first measurement unit 210 may measure the first width δ1 between the side surface of the lower parallel side portion 12 of the tensile test piece 10 and the alignment axis C0. The second measurement unit 220 may measure the second width δ2 between the side surface of the lower parallel side 12 of the tensile test piece 10 and the alignment axis C0.

The first width δ1 is a distance from the zero point of the first reference member 211 to the end of the first contact member 212 in contact with the side surface of the lower parallel portion 12. The second width δ2 is a distance from the zero point of the second reference member 221 to the end of the second contact member 222 that is in contact with the side of the upper parallel side portion 12.

When the measured first width δ1 and the second width δ2 are coincident with each other, it means that the specimen axis C of the tensile specimen 10 is aligned with the alignment axis C0.

On the other hand, when the measured first width δ1 and the second width δ2 have different values, it means that the specimen axis C of the tensile specimen 10 is misaligned from the alignment axis C0.

Therefore, the present invention can achieve the misalignment state of the tensile test piece 10 while measuring the first width δ1 and the second width δ2.

When the alignment state is achieved, the fixing ends 11 of the tensile test piece 10 are fixed again to prevent the flow of the tensile test piece 10 by using the fixing part 100.

In a preferred embodiment of the present invention, as shown in Figure 1 with respect to the front surface of the jig to provide a pressing force on the upper side and the lower side of one side of the parallel portion 12 of the tension specimen 10, respectively 10) was described.

6 illustrates an example in which the first and second measurement units 210 and 220 according to the present invention are arranged to be staggered with respect to the front of the jig.

Referring to FIG. 6, the first and second measurement units 210 and 220 according to the present invention are arranged to be staggered with respect to the front of the jig.

Of course, the staggered direction of the first and second measurement units 210 and 220 may be changed to be symmetrical with the direction shown in FIG.

Accordingly, the first measuring unit 210 measures the width between one side of the lower parallel part 12 and the alignment axis C0, and the second measuring unit 220 is connected to the other side of the upper parallel part 12. Measure the width between the alignment axes C0.

7 shows an example in which the measuring unit according to the present invention is configured in two pairs.

Referring to FIG. 7, the pair of first measuring units 210 are disposed to face each other at the upper surface of the lower fixing part 120 at the boundary of the alignment axis C0.

The pair of second measurement units 220 are disposed to face each other at the bottom of the upper fixing part 110 at the boundary of the alignment axis C0.

Accordingly, the pair of first measuring units 210 measures the widths between both side surfaces of the lower parallel part 12 and the alignment axis C0, and the pair of second measuring units 220 measures the upper parallel part ( 12) Measure the widths between both sides and the alignment axis C0.

As mentioned above, the jig of the present invention can measure the widths measured at the side or both sides of the parallel portion 12 of the tensile specimen 10 at different positions.

Therefore, the present invention has an advantage that the specimen axis C of the tensile specimen 10 can be precisely adjusted and corrected to coincide with the alignment axis C0.

On the other hand, when the tensile test is carried out, one end of the sliding members (212, 222) may be carried out in contact with the side of the parallel portion 12 of the tensile test piece (10).

Therefore, during the tensile test, it is desirable to minimize the frictional force at one end of the contact members (212, 222) in contact with each other and the side of the parallel portion.

The contact members 212 and 222 may form any one of a rolling contact or a point contact with the parallel part 12.

The first measuring unit 210 will be described as an example.

As shown in FIG. 8, a roller 240 having a rotation shaft H may be further provided at one end of the first contact member 212.

Here, the roller 240 is preferably made of an elastic material.

Thus, the roller 240 of the first contact member 212 is in rolling contact with the side of the parallel portion 12. The frictional force at the surface in contact with the rolling can be minimized.

In addition, in the present invention, as shown in FIGS. 9 to 11, point contact may be achieved.

As for the point contact method, as shown in FIG. 9, one end of the first contact member 212 may be formed in the shape of a sharp protrusion 241, or may be formed in the shape of a round protrusion 242 as shown in FIG. 10. As shown in FIG. 11, one of the methods of forming the plurality of round protrusions 243 may be adopted. Of course, although not shown in the drawing, a plurality of pointed protrusions may be formed at one end of the first contact member 212.

According to the present invention, by adopting the above point contact method, the frictional force can be minimized by minimizing the contact area between one end of the contact members 212 and 222 and the side of the parallel part 12.

In addition, the present invention may variably adjust the measurement position 200 (distance between the side of the parallel portion 12 and the alignment axis C0) of the measurement unit 200 mentioned above along the alignment axis C0.

12 illustrates an example in which the lifting position of the first measuring unit may be variably adjusted.

Referring to FIG. 12, the present invention may further include a mobile unit 300. The moving unit 300 may be composed of one or more guide rods 310 and screw bolts 320.

The one or more guide rods 310 are installed in the state of being upright along the alignment axis C0 at the lower fixing part 120, and the first reference member 211 has the guide rods 310 penetrated thereinto to be elevated. You are guided.

The screw bolt 320 has a threaded portion 321 and an extension portion 322 extending from the threaded portion 321. At the end of the extension portion 322 is a disk-shaped head portion 323 is formed.

The thread 321 is screwed to the lower fixing part 120 along the alignment axis C0. The lower end of the screw portion 321 protrudes below the lower fixing portion 120.

The extension part 322 has a cylindrical shape and is fitted to rotate on the first reference member 211. The head 323 is inserted to be rotatably supported by the first reference member 211.

Therefore, when the lower end of the screw portion 321 is rotated in a predetermined rotational direction, the screw portion 321 is elevated in the state of being screwed to the lower fixing portion 120.

In addition, the extension part 322 which extends on the upper end of the thread part 321 and supports the first reference member 211 to rotate is also raised.

According to the operation thereof, the lifting position of the first reference member 211 that is rotationally supported by the extension 322 and the head 323 can be adjusted.

Here, the lifting method of the first measuring unit 210 may be substantially the same as the second measuring unit 220.

Thus, the present invention can selectively variably adjust the position for measuring the width between the parallel portion 12 side of the tensile specimen 10 and the alignment axis.

In this case, the present invention is not limited to the vertical length h of the exposed end 13 of the tensile test piece 10 and can easily measure the width from the side of the parallel portion 12 to the alignment axis C0. Has the advantage.

Referring to FIG. 13, the jig mentioned above is connected to the tension driving unit 400 to constitute a tensile test apparatus.

The tension driver 400 includes an upper driver 410 and a lower driver 420.

The upper driving part 410 is connected to the upper fixing part 110, and the lower driving part 420 is connected to the lower fixing part 120.

The upper driving unit 410 and the lower driving unit 420 is a device that receives power from the outside, and is forced to flow in a direction apart from each other along the alignment axis (C0).

When the specimen axis C of the tensile test piece 10 is precisely aligned with the alignment axis C0 by the jig of the present invention, the tensile driving part 400 receives external power and receives a predetermined tensile force on the tensile test piece 10. Can be added.

In addition, the tensile test piece 10 may be tensioned in a state where the specimen axis C coincides with the alignment axis C0.

Therefore, the tensile test apparatus of the present invention has the advantage of obtaining reliable tensile test results.

10: tensile test specimen 11: fixed end
12: parallel part 13: exposed end
100: fixing part 110: upper fixing part
111: upper fixing part body 120: lower fixing part
121: lower fixing part body 200: measuring part
210: first measurement unit 211: first reference member
211a, 211a ': rail groove 212: first contact member
212a, 212a ': Rail protrusion 220: Second measuring part
221: second reference member 222: second contact member
230: ball screw 300: moving unit
310: guide rod 320: screw bolt
400: tensile drive 410: upper drive
420: lower drive unit

Claims (9)

A pair of fixing parts disposed to face each other, both ends of the tensile test piece being fixed and forming an alignment axis; And
It is disposed in each of the pair of fixing parts to be movable along the direction orthogonal to the alignment axis, and includes a measuring unit for measuring the width of the side of the tensile test piece and the alignment axis,
Wherein the width is a distance between the side of the parallel portion formed between the alignment axis and both ends of the tensile test piece.
The method of claim 1,
Wherein the measuring unit comprises:
Jig for tensile specimen alignment, characterized in that arranged in any one of the positions facing each other or staggered position.
delete The method of claim 1,
Wherein the measuring unit comprises:
A pair of reference members provided at each of the pair of fixing portions so that one end thereof coincides with the alignment axis, and a reference scale having zero alignment points as the alignment axis is formed;
And a pair of contact members disposed in the pair of reference members so as to be flowable along a direction orthogonal to the alignment axis and having a pair of contact members whose one end contacts the side of the parallel part.
5. The method of claim 4,
The tensile specimen is,
The parallel portion with both sides parallel to each other,
A pair of fixed ends formed at both ends of the parallel part and fixed to the pair of fixed parts;
A pair of exposed ends formed between the parallel portion and the pair of fixed ends and exposed to the outside of the pair of fixed ends,
The vertical length of the pair of reference members is
Jig for tensile specimen alignment, characterized in that formed to correspond to the vertical length of the pair of exposed ends.
5. The method of claim 4,
The pair of reference members,
Jig for tensile specimen alignment, characterized in that for forming a predetermined gap from the outer periphery of the tensile specimen.
5. The method of claim 4,
The contact member
A jig for tension specimen alignment, characterized in that it forms either a rolling contact or a point contact with the parallel side.
The method of claim 1,
Wherein the measuring unit comprises:
A jig for tensile specimen alignment, which is movable along the alignment axis.
delete

Images