KR101690931B1 - Jig for adhesive strength test - Google Patents

Abstract

A jig for adhesion testing is disclosed. An adhesive force test paper according to an embodiment of the present invention includes: a first movable part that is linearly moved by receiving a driving force from a first driving part; A first base portion supporting the first movable portion so as to be linearly movable; A first holder slidably coupled to one side of the first base portion in a direction perpendicular to the linear motion direction of the first movable portion and holding the first specimen; A first link for converting a linear movement of the first movable part into a sliding movement of the first holder; A second movable part that is linearly moved by receiving a driving force from the second driving part; A second base portion supporting the second movable portion so as to be linearly movable; A second holder that is slidably coupled to one side of the second base portion in a direction perpendicular to the linear motion direction of the second movable portion and holds a second specimen adhered to the first specimen by an adhesive; And a second link for converting the linear movement of the second movable part into a sliding movement of the second holder.

Description

Jig for adhesive strength test [

The present invention relates to a jig used for testing the adhesive strength of an adhesive.

1 is a view showing a conventional superposition shear test process. Referring to Figure 1, a lap shear test is typically performed to test the adhesive strength of the adhesive.

For such an adhesion test, a uniaxial tensile tester as shown in Fig. 1 is used. The holders H1 and H2 of the uniaxial tensile test machine hold the jig members J1 and J2 respectively adhered with the adhesive A, respectively.

The uniaxial tensile test machine applies a tensile force to the holders H1 and H2 to measure the tensile force at the moment when the holders H1 and H2 are separated to estimate the adhesive force of the adhesive A.

Since the tensile force of the uniaxial tensile testing machine is located on the same axis line, the jig members J1 and J2 are thinner than the portion where the adhesive agent A is held by the holder.

When such jig members J1 and J2 are used, there is no problem if the strength of the jig members J1 and J2 is overwhelmingly higher than that of the adhesive agent A. However, (J1, J2), the jig members (J1, J2) are first bent or fractured during the process of testing the adhesive strength of the adhesive (A), resulting in an erroneous result lower than the actual adhesive force do.

An embodiment of the present invention seeks to provide whether or not the adhesive force of the adhesive can be effectively tested.

According to an aspect of the present invention, there is provided a portable terminal comprising: a first movable unit that is linearly moved by receiving a driving force from a first driving unit; A first base portion supporting the first movable portion so as to be linearly movable; A first holder coupled to one side of the first base part so as to be slidable in a direction perpendicular to the linear motion direction of the first movable part and holding the first specimen; A first link for converting a linear movement of the first movable part into a sliding movement of the first holder; A second movable part that is linearly moved by receiving a driving force from the second driving part; A second base portion supporting the second movable portion so as to be linearly movable; A second holder slidably coupled to one side of the second base portion in a direction perpendicular to a linear motion direction of the second movable portion and holding a second specimen bonded to the first specimen by an adhesive; And a second link for converting a linear movement of the second movable part into a sliding movement of the second holder.

A guide portion for guiding the sliding movement of the first holder may be formed at one side of the first base portion and a guide portion for guiding the sliding movement of the second holder may be formed at one side of the second base portion.

The first link includes: a 1-1 link member having one end hinged to one side of the first movable portion; And a 1-2 link member having one end hinged to the other end of the 1-1 link member and the other end connected to one side of the first holder, A second-1 link member hinged to one side; And a second-2 link member having one end hinged to the other end of the second-1 link member and the other end coupled to one side of the second holder.

The first movable part and the second movable part can move on the same straight line.

The combination of the first movable portion, the first base portion, the first holder, and the first link has a symmetrical structure with the combination of the second movable portion, the second base portion, the second holder, and the second link Lt; / RTI >

According to an embodiment of the present invention, a first holder and a second holder, which hold the first specimen and the second specimen, respectively, by converting a linear driving force provided by the first driving unit and the second driving unit into a force in a direction perpendicular thereto, The adhesive force of the adhesive provided between the first specimen and the second specimen can be effectively tested in a new way of moving in the opposite direction.

Furthermore, since the first movable part and the second movable part respectively held by the holder of the first driving part and the holder of the second driving part move on the same straight line, the adhesive force test jig according to this embodiment is applied to the uniaxial tensile testing machine of the conventional type .

Furthermore, since the combination of the first movable portion, the first base portion, the first holder, and the first link has a symmetrical structure with the combination of the second movable portion, the second base portion, the second holder, and the second link, Errors that occur can be minimized.

1 is a view showing a conventional superposition shear test process.
2 is a view showing an adhesive strength testing jig according to an embodiment of the present invention.
3 and 4 are views for explaining the operation of the adhesive force testing jig according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, do.

2 is a view showing an adhesive strength testing jig according to an embodiment of the present invention. 2, the adhesive testing jig 100 according to the present embodiment includes a first movable part 110, a first base part 120, a first holder 130, a first link 140, A second movable part 160, a second base part 170, a second holder 180, and a second link 190.

The first moving part 110 receives a driving force from the first driving part 10 and linearly moves. The first drive 10 may include, but is not limited to, a hydraulic or pneumatic cylinder that provides a linear drive force. One end of the first movable part 110 is held by the holder 11 of the first driving part 10. At this time, the first movable part 110 may be clamped or bolted to the holder 11 of the first driving part 10, but the present invention is not limited thereto.

The first base part 120 supports the first movable part 110 so as to linearly move. The first base part 120 is formed with a groove 121 for linear movement of the first movable part 110. The first base portion 120, which is supplied with driving force from the first driving portion 10, moves linearly along the groove 121.

The first holder 130 is slidably coupled to one side of the first base 120. The first holder 130 holds the first specimen T1. The first holder 130 slides in a direction perpendicular to the linear motion direction of the first movable unit 110.

A guide part 123 for guiding the sliding movement of the first holder 130 is formed on one side of the first base part 120. The guide portion 123 is formed to extend in a direction perpendicular to the linear motion direction of the first movable portion 110.

The first link 140 is interposed between the first movable part 110 and the first holder 130. The first link 140 converts the linear movement of the first movable part 110 into the sliding movement of the first holder 130.

In one example, the first link 140 may include a 1-1 link member 141 and a 1-2 link member 142. One end of the 1-1 link member 141 is hinged to one side of the first movable part 110 and the other end of the 1-1 link member 141 can be hinged to one end of the 1-2 link member 142. The other end of the 1-2 link member 142 is coupled to one side of the first holder 130.

The first link (140) member converts the linear movement of the first movable part (110) into the sliding movement of the first holder (130).

The second moving part 160 receives a driving force from the second driving part 20 and moves linearly. The second drive 20 may include, but is not limited to, a hydraulic or pneumatic cylinder that provides a linear drive force. One end of the second movable part 160 may be held in the holder 21 of the second driving part 20. [ At this time, the second movable part 160 may be clamped or bolted to the holder 21 of the second driving part 20, but is not limited thereto.

The second base portion 170 supports the second movable portion 160 so as to be linearly movable. The second base portion 170 is formed with a groove 171 for linear movement of the second movable portion 160. The second base portion 170 receiving the driving force from the second driving portion 20 linearly moves along the groove 171.

The second holder 180 is slidably coupled to one side of the second base portion 170. The second holder 180 holds the second specimen T2. The second holder 180 slides in a direction perpendicular to the linear motion direction of the second movable unit 160.

A guide portion 173 for guiding the sliding movement of the second holder 180 is formed on one side of the second base portion 170. The guide portion 173 is formed to extend in a direction perpendicular to the linear motion direction of the second movable portion 160.

And the second link 190 is interposed between the second movable part 160 and the second holder 180. The second link 190 converts the linear movement of the second movable part 160 into the sliding movement of the second holder 180. [

In one example, the second link 190 may include a second-1 link member 191 and a second-2 link member 192. One end of the second-1 link member 191 is hinged to one side of the second movable part 160, and the other end thereof is hinged to one end of the second-second link member 192. The other end of the second -2 link member 192 is coupled to one side of the second holder 180.

The second link (190) member converts the linear movement of the second movable part (160) into the sliding movement of the first holder (130).

According to the present embodiment, the sliding directions of the first holder 130 and the second holder 180 are opposite to each other. In this case, the first specimen T1 and the second specimen T2 held by the first holder 130 and the second holder 180 respectively move in opposite directions to move the first specimen T1 and the second specimen T2, The adhesive force of the adhesive (A) interposed between the test pieces (T2) can be tested. The mechanism in which the first holder 130 and the second holder 180 slide in opposite directions will be described later.

The jig 100 according to the present embodiment converts the linear driving force provided by the first driving unit 10 and the second driving unit 20 into a force in a direction perpendicular thereto and transmits the first and second test pieces T1, (A) provided between the first specimen (T1) and the second specimen (T2) in a new way of moving the first holder (11) and the second holder (21) Can be effectively tested.

On the other hand, the first driving part 10 and the second driving part 20 provide a linear driving force acting on the same straight line X. The first movable part 110 and the second movable part 160 which are respectively held by the holder 11 of the first driving part 10 and the holder 21 of the second driving part 20 also move on the same straight line X, do.

At this time, the first driving part 10 and the second driving part 20 can constitute a part of a conventional type of pull-up tensile testing machine. Therefore, the adhesive force testing jig 100 according to the present embodiment is applicable to a uniaxial tensile test machine of a conventional type.

According to the present embodiment, the combined body of the first movable part 110, the first base part 120, the first holder 130 and the first link 140 is composed of the second movable part 160, The holder 170, the second holder 180, and the second link 190, as shown in FIG.

At this time, if the linear driving force provided by the first driving unit 10 and the second driving unit 20 acts on the same straight line X and the sizes thereof are the same, errors occurring in the asymmetry of the members can be minimized.

3 and 4 are views for explaining the operation of the adhesive force testing jig according to an embodiment of the present invention. 3 and 4 illustrate the operation of the jig 100 assuming that the first specimen T1 and the second specimen T2 are not held in the first holder 130 and the second holder 180 do.

3, the first moving part 110 and the second moving part 160 are held by the holder 11 of the first driving part 10 and the holder 21 of the second driving part 20, respectively. At this time, the first holder 130 and the second holder 180 are arranged to face each other.

The first and second driving units 10 and 20 provide driving forces acting on the same straight line X to the first and second movable units 110 and 160. [ At this time, the driving force provided by the first driving unit 10 and the second driving unit 20 acts as a compressive force.

4, when a driving force is applied to the first movable part 110 and the second movable part 160, the first movable part 110 and the second movable part 160 are rotated by the first base part 120 and the second movable part 160, respectively, And moves linearly while being supported by the base portion 170.

The first link 140 and the second link 190 move the first holder 130 and the second holder 180 in the direction of linear motion of the first movable part 110 and the second movable part 160, Move in a vertical direction. At this time, the directions of motion of the first holder 140 and the second holder 180 are reversed.

The first movable part 110 and the second movable part 160 are connected to the first base part (not shown), and the first movable part 110 and the second movable part 160, respectively, 120 and the grooves 171 of the second base portion 170. In this case, For example, an end portion of each of the first movable portion 110 and the second movable portion 160 is formed with an engagement portion that engages with an opening of each of the grooves 121 and 171.

When the first driving part 10 and the second driving part 20 continuously provide a tensile force, the first movable part 110, the first base part 120, the first holder 130, and the first link 140 The connection between the coupling and the second movable part 160, the second base part 170, the second holder 180, and the combination of the second link 190 is distant. At this time, the first specimen T1 and the second specimen T2, which are wired between the first holder 130 and the second holder 180 and adhered to each other with an adhesive, may be disposed therebetween.

When the first and second driving units 10 and 20 provide a compressive force, the first and second specimens T1 and T2 are held by the first holder 130 and the second holder 180, .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, many modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

10:
20:
110: first movable part
120: first base portion
130: first holder
140: first link
160: second moving part
170: second base portion
180: second holder

Claims (5)

A first movable part that is linearly moved by receiving a driving force from the first driving part;
A first base portion supporting the first movable portion so as to be linearly movable;
A first holder coupled to one side of the first base part so as to be slidable in a direction perpendicular to the linear motion direction of the first movable part and holding the first specimen;
A first link for converting a linear movement of the first movable part into a sliding movement of the first holder;
A second movable part that is linearly moved by receiving a driving force from the second driving part;
A second base portion supporting the second movable portion so as to be linearly movable;
A second holder slidably coupled to one side of the second base portion in a direction perpendicular to a linear motion direction of the second movable portion and holding a second specimen bonded to the first specimen by an adhesive; And
And a second link for converting a linear movement of the second movable part into a sliding movement of the second holder,
Wherein the first holder and the second holder are slidable in mutually opposite directions perpendicular to a driving force provided by the first driving unit and a driving force provided by the second driving unit, respectively. The method according to claim 1,
A guide portion for guiding a sliding movement of the first holder is formed on one side of the first base portion,
And a guide portion for guiding a sliding movement of the second holder is formed on one side of the second base portion. The method according to claim 1,
Wherein the first link comprises:
A 1-1 link member having one end hinged to one side of the first movable part; And
And a 1-2 link member having one end hinged to the other end of the 1-1 link member and the other end connected to one side of the first holder,
Wherein the second link comprises:
A second-1 link member having one end hinged to one side of the second movable portion; And
And a second-2 link member having one end hinged to the other end of the second-1 link member and the other end coupled to one side of the second holder. 4. The method according to any one of claims 1 to 3,
Wherein the first movable part and the second movable part move on the same straight line. 5. The method of claim 4,
The combination of the first movable portion, the first base portion, the first holder, and the first link,
Wherein the jig has a symmetrical structure with an assembly of the second movable portion, the second base portion, the second holder, and the second link.

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