KR102088613B1 - Multi folding tester - Google Patents

Abstract

Disclosed is a multi-folding tester. According to one embodiment of the present invention, a multi-folding tester comprises: a base; at least two support portions installed vertically on the base; a fixed shaft portion fixed to both sides of at least two support portions; a rotating body portion having both ends rotatably connected to the fixed shaft portion, and rotating about the fixed shaft portion; a rotating shaft portion having one side connected to the rotating body portion and the other side fixed to an object to be irradiated, and being rotated by the rotational force of the rotating body portion to fold the object to be irradiated; and a rotating control part having the rotating shaft portion passing through between the rotating body portion and the object to be irradiated to be coupled, and controlling the position change of the central axis of the rotating shaft portion.

Description

Multi-folding tester {MULTI FOLDING TESTER}

The present invention relates to a multi-folding tester, and more particularly, to a multi-folding tester capable of folding tests on flexible substrates, panels, materials, etc. having various physical, mechanical, and mechanical characteristics.

2. Description of the Related Art Recently, with the development of information communication technology (ICT), the use of electronic devices is continuously increasing. In this situation, in order to develop a differentiated electronic device than the prior art, new devices, components, materials, etc. of the electronic device are actively being developed.

Among them, research and development on flexible electronic components, devices, materials, and the like has also been actively conducted. In the case of manufacturing a flexible substrate, a folding test is performed on the flexible substrate. For example, an in-folding test in which the surfaces of the flexible substrate face each other, an out-folding test in which the surfaces and the bottom surface of the substrate face each other, or a combination thereof. A hybrid folding test or the like is performed.

Conventionally, in-folding test and out-folding test have various difficulties in testing in one folding test equipment. In addition, it was technically difficult to test various types of flexible substrates (or materials) in one folding test apparatus due to differences in the thickness of the substrate or the physical structure (hinge structure).

Specifically, referring to FIG. 1 (a), the position of the central axis of folding is eliminated when the object P having a certain thickness d1 is in-folded or out-folded. It can be seen that the first central axis C1 and the second central axis C2 change with each other. Or, referring to Figure 1 (b), the first subject P1 and the second subject P2 having different thicknesses (first thickness d1, second thickness d2) are in-folded ( In the case of In-Folding test, it can be seen that the position of the folding central axis is different from the first central axis C1 and the second central axis C2 due to the thickness difference. Or, referring to Figure 1 (c), when folding the subject P having one hinge (hinge) structure, the folding central axis is the first central axis C1, but the subject having the two hinge structures ( When folding P), it can be seen that the central axis of the folding may be different from the first central axis C1 and the second central axis C2 '.

As described above, in order to perform folding tests on various types of objects under the circumstances in which the folding central axis is variable due to the physical, mechanical, and structural characteristics of the flexible object, the need for the development of a new type of folding test device is required.

Patent Literature 1: Korean Registered Patent No. 10-1901390 (Publication date: September 17, 2018) Patent Document 2: Korean Registered Patent No. 10-1843874 (Publication date: March 26, 2018) Patent Literature 3: Korean Registered Patent No. 10-1489667 (Publication date: January 29, 2015)

The present invention, devised by the above-mentioned necessity, can be used in various creations without a user's separate manipulation or setting when the folding central axis is changed during folding of the inspected object due to the physical, mechanical or mechanical characteristics of the inspected object in the folding test. An object of the present invention is to provide a multi-folding tester capable of performing a stable and precise folding test by compensating for the folding central axis of the carcass.

Multi-folding tester according to an embodiment of the present invention to achieve the above object, the base portion; At least two support portions vertically installed on the base portion; A fixed shaft part fixed to both sides of the at least two support parts; A rotating body part rotatably connected to both end portions of the fixed shaft part and rotating the fixed shaft part as a rotating shaft; One side is connected to the rotating body portion, the other side is fixed to the object to be irradiated, the rotating shaft portion for folding the object by rotating by the rotational force of the rotating body portion; And a rotation adjusting part that is fastened through the rotating shaft part between the rotating body part and the irradiated body and controls a position change of a central axis of the rotating shaft part.

In this case, the fixed shaft portion is composed of a first fixed shaft portion and a second fixed shaft portion, and the subject is divided into a fixed region and a rotating region based on a central axis of the fixed shaft portion, and the first fixed shaft The portion includes first fixing means for fixing one side end of the fixing region, and the second fixing shaft portion includes second fixing means for fixing the other end of the fixing region.

In this case, the rotating shaft portion is composed of a first rotating shaft portion and a second rotating shaft portion, and the first rotating shaft portion includes third fixing means for fixing one side end of the rotating region, and the second The rotating shaft portion includes fourth fixing means for fixing one end of the rotating region.

Meanwhile, the rotating body portion rotates in a clockwise or counterclockwise direction based on the central axis of the fixed shaft portion.

On the other hand, when the position of the rotational axis of the rotating area occurs during the folding process of the subject, the rotation adjusting unit adjusts the position of the rotating shaft of the rotating shaft part to compensate for the position of the rotating shaft of the rotating shaft part according to the positional movement. .

In this case, the rotation adjusting part adjusts the position of the rotation shaft of the rotation shaft part in the front-rear direction, the up-down direction, or a combination thereof, in accordance with the position of the rotation axis of the rotation region.

In this case, the rotation adjustment unit is composed of a first rotation adjustment unit and a second rotation adjustment unit, the first rotation adjustment unit is located between one side end of the rotation region and the rotation unit, the second rotation adjustment The part is located between the other side end of the rotating area and the rotating body part.

In this case, the first rotation adjustment unit and the second rotation adjustment unit are composed of a vertical adjustment member having a first hole and a second hole, and a front and rear adjustment member positioned below the vertical adjustment member.

In this case, the first rotation shaft part is inserted into the first hole of the first rotation adjustment part, and the first rotation adjustment part penetrates the second hole of the first rotation adjustment part to fix the third. And a first connecting shaft fastened to the means.

Meanwhile, the second rotating shaft part is inserted into the first hole of the second rotation control part, and the second rotation control part penetrates through the second hole of the second rotation control part and is fastened to the fourth fixing means. It includes a second connecting shaft.

Meanwhile, the rotating body portion includes a first adjusting groove and a second adjusting groove in an area connected to the first rotating shaft portion and the second rotating shaft portion, and the first rotating shaft portion includes the first adjusting groove By, it can be moved in the front-rear direction, the second rotary shaft portion, it can be moved in the front-rear direction by the second adjustment groove.

On the other hand, a motor unit for providing a rotational force to the rotating body; And a double bearing part provided between the motor part and the fixed shaft part, and further comprising, the rotating force is not transmitted to the fixed shaft part by the double bearing part, and the rotating force is transmitted to the rotating body part.

According to various embodiments of the present invention, when the folding central axis is changed when folding of the subject due to the physical, mechanical, and mechanical characteristics of the subject of the folding test, the user can perform various subjects without additional manipulation or setting. By compensating for the folding central axis of, it exhibits the effect of performing a stable and precise folding test.

1 is a view for explaining an example of a variable folding central axis expected in various folding tests,
2 is an exemplary diagram for explaining a multi-folding tester according to an embodiment of the present invention,
Figure 3 is a view showing a top view of the multi-folding tester shown in Figure 2,
4 is an enlarged view of area A shown in FIG. 3,
5 is an enlarged view of region B shown in FIG. 4,
6 is an exemplary view for explaining the structure of the rotation control unit according to an embodiment of the present invention,
7 is an exemplary view of the first rotation control unit in the M direction in FIG. 6,
8 is a view showing an example in which the rotating body of the multi-folding tester according to an embodiment of the present invention rotates counterclockwise;
FIG. 9 is a view showing an example of a state in which the rotating body part rotating in the counterclockwise direction shown in FIG. 8 has finished rotating;
10 is a perspective view illustratively illustrating the multi-folding tester shown in FIG. 9,
11 is a view showing an example in which the rotating body of the multi-folding tester according to an embodiment of the present invention rotates clockwise, and
12 is a view showing an example of a state in which the rotating body part rotating in the clockwise direction shown in FIG. 11 has finished rotating.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited or limited by the embodiments. In addition, in various embodiments of the present invention, the accumulation or proportions of the drawings are merely exemplary, and the components of the present invention illustrated in the drawings may be designed in different shapes, shapes, dimensions, or sizes according to embodiments.

1 is a view for explaining a problem that occurs in the folding area when executing the conventional folding test. Referring to FIG. 1 (b), when a folding test is performed on an object (eg, a display panel) having a certain thickness, it can be seen that the rotation axis C1 of the folded portion of the object is variable (FIG. 1 ( b) see the marked part of C1). When there is no compensation for the variability of the rotational axis of the folding region, when P1 is folded with respect to P2, a problem that mutual impact or excessive external force is applied in the folding region as shown in FIG.

Hereinafter, a multi-folding tester that performs a folding test by compensating for a change in a rotation axis in a folding area in a folding test according to an embodiment of the present invention. Here, the meaning of 'multi' means that the folding test can be performed in various cases in which the type, material, position of the rotating shaft, and the variability of the rotating shaft are different.

2 is an exemplary diagram for explaining a multi-folding tester according to an embodiment of the present invention. Referring to FIG. 2, the multi-folding tester 100 includes a base portion 110, two support portions 120-1 and 120-2, a fixed shaft portion 130, a rotating body portion 140, and a rotating shaft portion 150 ), Two rotation control units 160-1 and 160-2 and a motor unit 170. In addition, although not shown in FIG. 2, it includes various components for achieving the above-described object.

As shown in FIG. 2, the base portion 110 is in contact with the installation surface, and the support portions 120-1 and 120-2 are vertically installed on the upper portion of the base portion 110. Two support portions 120-1 and 120-1 may be designed in two or more, but if at least two are installed, it is not difficult to achieve the object of the present invention.

The fixed shaft part 130 is located between the two support parts 120-1 and 120-2. The fixed shaft part 130 may include a first fixed shaft part 130-1 and a second fixed shaft part 130-2. The first fixing shaft part 130-1 is connected to the first fixing means 180-1 on which one side fixes the fixed object P2, and the other side penetrates through a region of the rotating body 140 to remove the first fixing shaft part 130-1. It is connected to 1 support part 120-1. The second fixed shaft portion 130-2 is connected to the second fixing means 180-2 on which one side fixes the fixed object P2, and the other side penetrates through a region of the rotating body portion 140 to remove the second fixed shaft portion 130-2. 2 It is connected to the support (120-2).

The rotating body portion 140 is rotatably connected to both ends of the ends at the first fixed shaft portion 130-1 and the second fixed shaft portion 130-2. The rotating body portion 140 is connected to the first rotating shaft 150-1 and the second rotating shaft 150-2 to one region on both sides. The rotating body part 140 rotates the fixed shaft part 130 counterclockwise or clockwise about the central axis.

The rotating shaft part 150 is located in a space between both sides of the rotating body part 140. The rotating shaft part 150 may be composed of a first rotating shaft part 150-1 and a second rotating shaft part 150-2. The first rotating shaft part 150-1 is connected to a third fixing means for fixing one side end of the rotating object P1 to one side, and the other side is fastened to the first adjustment hole provided in the rotating body part 140. do. The second rotating shaft part 150-2 is connected to a fourth fixing means on which one side secures the other end of the rotating object P1, and the other side is fastened to the second adjustment groove provided on the rotating body part 140. do.

The rotation adjusting unit 160 is located between the rotating object P1 and the rotating body 150. The rotation adjusting unit 160 may include a first rotation adjusting unit 160-1 and a second rotation adjusting unit 160-2. The first rotation adjusting part 160-1 is fastened through the first rotation shaft part 150-1, and penetrated by the first connection shaft part 161-1 to fix the rotation subject P1. It is connected to the third fixing means. The second rotation adjusting part 160-2 is fastened through the second rotation shaft part 150-2 and penetrated by the second connection shaft part 161-2 to fix the rotation subject P1. It is connected to the fourth fixing means.

The motor unit 170 provides rotational force to the rotating body 140 by a force transmission means (not shown). The force transmission means is a double bearing part installed inside the first support part 120-1 provided between the motor part 170 and the first fixed shaft part 130-1. The double bearing part does not provide the rotational force provided by the motor part 170 to the first fixed shaft part 130-1, and transmits it to the rotating body part 140.

A plurality of fixing means (180-1 to 180-4) is configured to secure the object P to the fixed shaft portion 130 and the rotating shaft portion 150. The plurality of fixing means (180-1 to 180-4) is not essential to understand the present invention, so a detailed description thereof will be omitted.

The plurality of size adjusting means 190-1 to 190-3 adjusts the horizontal or vertical size of the subject P in accordance with the allowable size of the rotating body 140 according to the plane size of the subject P.

FIG. 3 is a plan view of the multi-folding tester shown in FIG. 2. Referring to FIG. 3, it can be confirmed that two objects are connected by a hinge. The subject P is divided into a rotating subject P1 and a stationary subject P2. The rotating object P1 connected to the rotating shaft portion 150 is in contact with or until the fixed object P2 connected to the fixed shaft portion 130 connected to the fixed shaft portion 130 by rotational movement of the rotating body portion 140. Until folded. In the case of connection by hinge, the fixed area and the rotating area are made of rigid material. In addition, the hinge is designed to be folded until the fixed area and the rotating area of the subject are overlapped. At this time, depending on the structure of the hinge, the hinge of the fixed region and the rotating region can be designed in dual, and the central axis of the hinge of the rotating region can be varied according to the rotation angle. When the rotation axis of the rotation area is changed in this way, the rotation axis of the rotation shaft part 150 connected to the rotation area must be compensated accordingly.

That is, the rotation adjusting unit 160 provides a degree of freedom to move the rotating shaft unit 150 in a vertical or forward or backward direction or a combination of these directions, so that the central axis of the hinge of the rotating region changes The rotating shaft of the rotating shaft unit 150 may also be changed according to the operation.

As described above, since the rotation adjusting unit 160 has a structure that compensates for the position of the rotating shaft of the rotating shaft unit 150, even if the rotating shaft of the rotating region P1 of the subject P is variable, it adapts to the rotating region P1. By rotating the mechanical stress due to an external force concentrated in the folded region of the subject P can be relieved, and the rotating region and the fixed region of the subject P can be folded in close contact.

In order to examine the structure of the rotation control unit 160 in more detail, it will be described below with reference to a separate drawing.

FIG. 4 is an enlarged view of region A shown in FIG. 3. Referring to FIG. 4, the rotation adjusting part 160 of the present invention is located at least two places between the rotating shaft part 150 and the rotating area P1 of the subject P. Referring to the enlarged view of the first rotation control unit 160 located in the region B in FIG. 4, a detailed structure of the rotation control unit 160 will be described as follows.

FIG. 5 is an enlarged view of region B shown in FIG. 4. Referring to FIG. 5, it can be seen that one side of the first rotary shaft part 150-1 is connected to the rotating body part 140, and the other side penetrates the first rotation control part 160-1. . However, according to an embodiment of the present invention, the first rotating shaft portion 150-1 is directly connected to the rotating body 140, but the third fixing means (180-) for fixing one side of the rotating object P1 3) is characterized by being indirectly connected via the first rotation control unit 160-1. The structure in which the first rotation shaft part 150-1 is indirectly connected to the third fixing means 180-3 via the first rotation adjustment part 160-1 will be described below with reference to a separate drawing. .

6 is an exemplary view for explaining the structure of the rotation control unit according to an embodiment of the present invention. Referring to FIG. 6 (a), one side of the first rotation shaft part 150-1 penetrates the upper hole among the two holes provided in the first rotation adjustment part 160-1. Referring to FIG. 6 (b), the first rotation shaft part 150-1 is fastened to the adjustment groove 141 having a long length in the front-rear direction provided at the other side of the rotation body part 140. One side of the first rotation shaft portion 150-1 is fastened to the adjustment groove 141, and the other side is fastened to the upper hole of the first rotation control portion 150-1, thereby allowing the first rotation shaft portion 150- The degree of freedom in the front-rear direction of 1) affects the degrees of freedom of the front-rear adjustment member 163-1 constituting the first rotation adjusting unit 150-1.

In addition, the first rotation shaft portion 150-1 only penetrates the upper hole of the first rotation adjustment portion 160-1, and is not directly connected to the third fixing means 180-1. A lower hole is provided below the upper hole through which the first rotary shaft part 150-1 passes through the first rotation adjusting part 160-1.

In the lower hole, the first connecting shaft part 161-1 is fastened through, and the first connecting shaft part 161-1 is connected to the third fixing means 180-1. A detailed structure for this will be described below with reference to separate drawings.

7 is an exemplary view of the first rotation adjusting unit in the M direction in FIG. 6. Referring to FIG. 7, one side of the first rotation shaft part 150-1 is connected to one end region of the rotating body part 140, and the other side penetrates the first rotation control part 160-1, but is fixed to the third part. It is not connected to the means 180-1. The first rotation adjusting unit 160-1 includes a first connecting shaft unit 161-1, an up and down adjustment member 162-1 having two holes, and a front and rear adjustment member 163-1 for adjusting in the front-rear direction. ). The first connecting shaft part 161-1 penetrates the lower hole provided in the up and down adjustment member 162-1 of the first rotation adjustment part 160-1, and is connected to the front-rear adjustment member 163-1. , The front-rear adjustment member 163-1 is connected to the third fixing means 180-3 by a connection member.

As described above, the rotation control unit 160 of the present invention can give the degree of freedom in the vertical direction by indirectly connecting the rotating shaft unit 150 to the fixing means 180 of the subject by the connecting shaft unit 161. have. Further, the degree of freedom can be given in the front-rear direction by the front-rear adjustment member 163.

8 is a view showing an example in which the rotating body portion of the multi-folding tester according to an embodiment of the present invention rotates counterclockwise. Referring to FIG. 8, the rotating body 140 may rotate counterclockwise when the X-Z plane is used as a reference plane. When the rotating body 140 rotates counterclockwise, the center of rotation becomes a rotation axis of the fixed shaft 130. However, in the rotating shaft part 150 that receives and rotates the rotational force by the rotating body part 140, the rotation center becomes the folding center of the object P.

In the process of rotating the rotating body portion 140 while rotating while drawing a semicircle orbit (R_1) having a constant radius, the rotating shaft portion 150 draws a compensated rotational trajectory according to a change in the central axis of the rotating object P1. The rotating object P1 is folded. When the rotating object P1 is folded in this way, an excessive external force is not applied to the hinge (or folding area) provided in the element P1, and there is no fear of damage due to mechanical stress or impact. Remarkable effect.

FIG. 9 is a diagram illustrating an example of a state in which the rotating body part rotating in the counterclockwise direction shown in FIG. 8 has finished rotating. Referring to FIG. 9, the multi-folding tester 100 of the present invention may perform a folding test until the rotational region P1 and the fixed region P2 of the subject P are in contact with each other.

10 is a perspective view illustrating the multi-folding tester illustrated in FIG. 9 by way of example. Referring to FIG. 10, when the folding test in the counterclockwise direction is completed, the rotating body 140 is placed in a completely folded state in the direction of the fixed area P2 of the subject P. Depending on the type of the subject P, the rotation region P1 and the fixed region P2 may not be completely folded, and in some embodiments, they may be folded clockwise or counterclockwise to a size smaller than 180.

11 is a view showing an example in which the rotating body portion of the multi-folding tester according to an embodiment of the present invention rotates clockwise. Referring to FIG. 11, the rotating body 140 may rotate clockwise when the X-Z plane is used as a reference plane. When the rotating body 140 rotates clockwise, the rotation center becomes a rotation axis of the fixed shaft 130. However, in the rotating shaft unit 150 rotating by receiving the rotational force by the rotating body unit 140, the rotation center becomes the center of the folded region of the irradiated body P.

In the process of rotating the rotating body portion 140 while rotating while drawing a semi-circular orbit (R_2) having a constant radius, the rotating shaft portion 150 draws a compensated rotating trajectory according to the change in the central axis of the rotating object P1. The rotating object P1 is folded. When the rotating object P1 is folded in this way, an excessive external force is not applied to the hinge (or folding area) provided in the element P1, and there is no fear of damage due to mechanical stress or impact. Remarkable effect.

FIG. 12 is a diagram illustrating an example of a state in which the rotating body part rotating in the clockwise direction shown in FIG. 11 has finished rotating. Referring to FIG. 12, the multi-folding tester 100 of the present invention rotates the rotating body 140 180 degrees clockwise relative to the XZ plane to rotate the rotating area P1 and the fixed area P2 of the inspected object P ) Can be folded until it actually touches.

Although exemplary embodiments and application examples of the present invention are illustrated and described, many changes and modifications are possible without departing from the scope of the technical spirit of the present invention, and such modifications can be made to those skilled in the art to which the present invention pertains. It can be clearly understood. Accordingly, the described embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited by the following detailed description, but may be modified within the technical scope of the claims.

100: multi-folding tester 110: base
120: support 130: fixed shaft portion
140: rotating body portion 150: rotating shaft portion
160: rotation control unit 161: connecting shaft unit
162: up and down adjustment member 163: front and rear adjustment member
170: motor unit
180: fixing means

Claims (12)

A base portion;
At least two support portions vertically installed on the base portion;
A fixed shaft part fixed to both sides of the at least two support parts;
A rotating body part rotatably connected to both end portions of the fixed shaft part and rotating the fixed shaft part as a rotating shaft;
One side is connected to the rotating body portion, the other side is fixed to the object to be irradiated, the rotating shaft portion for folding the object by rotating by the rotational force of the rotating body portion; And
A multi-folding tester comprising; a rotation adjusting part for fastening through the rotating shaft part between the rotating body part and the irradiated body and adjusting a position change of a central axis of the rotating shaft part.
According to claim 1,
The fixed shaft portion is composed of a first fixed shaft portion and a second fixed shaft portion,
The subject is divided into a fixed region and a rotating region based on the central axis of the fixed shaft portion,
The first fixing shaft part includes first fixing means for fixing one side end of the fixing region,
The second fixing shaft part, the multi-folding tester, characterized in that it comprises a second fixing means for fixing the other end of the fixing area.
The method of claim 2,
The rotating shaft portion is composed of a first rotating shaft portion and a second rotating shaft portion,
The first rotating shaft portion includes third fixing means for fixing one side end of the rotating region,
The second rotating shaft portion, the multi-folding tester, characterized in that it comprises a fourth fixing means for fixing one end of the rotating region.
According to claim 1,
The rotating body portion, multi-folding tester, characterized in that rotating in a clockwise or counterclockwise direction with respect to the central axis of the fixed shaft.
According to claim 3,
The rotation adjusting unit, when the position of the rotational axis of the rotational region occurs during the folding process of the subject, adjusts the position of the rotational shaft of the rotational shaft to compensate for the position of the rotational shaft according to the positional movement. Multi-folding tester.
The method of claim 5,
The rotation control unit, the multi-folding tester, characterized in that in accordance with the position of the rotation axis of the rotation region to adjust the position of the rotation shaft of the rotation shaft in the front-rear direction or up-down direction or a combination thereof.
The method of claim 6,
The rotation control unit is composed of a first rotation control unit and a second rotation control unit,
The first rotation adjusting part is located between one side end of the rotation area and the rotation body part,
The second rotation control unit, the multi-folding tester, characterized in that located between the other end of the rotation area and the rotating body.
The method of claim 7,
The first rotation control unit and the second rotation control unit, the multi-folding characterized in that it consists of a vertical adjustment member having a first hole and a second hole, respectively, and front and rear adjustment members located below the vertical adjustment member. Testing machine.
The method of claim 8,
The first rotation shaft portion is inserted into the first hole of the first rotation control portion,
The first rotation control unit, the multi-folding tester, characterized in that it comprises a first connection shaft that is fastened to the third fixing means through the second hole of the first rotation control unit.
The method of claim 8,
The second rotary shaft portion is inserted into the first hole of the second rotation control portion,
The second rotation control unit, the multi-folding tester, characterized in that it comprises a second connection shaft that is fastened to the fourth fixing means through the second hole of the second rotation control unit.
The method of claim 8,
The rotating body portion includes a first adjusting groove and a second adjusting groove in an area connected to the first rotating shaft portion and the second rotating shaft portion,
The first rotating shaft portion, it can be moved in the front-rear direction by the first adjustment groove,
The second rotating shaft unit, multi-folding tester, characterized in that can be moved in the front-rear direction by the second adjustment groove.
According to claim 1,
A motor unit providing rotational force to the rotating body; And
Further comprising; a double bearing portion provided between the motor portion and the fixed shaft portion,
Multi-folding tester, characterized in that the rotational force is not transmitted to the fixed shaft portion by the double bearing portion, and the rotational force is transmitted to the rotating body portion.

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