KR102359092B1 - Ultra-thin Glass Folding Device - Google Patents

Abstract

The present invention relates to an ultrathin glass folding device capable of repeating a flexible material folding test under the same condition. To achieve the purpose of the present invention, according to the present invention, the ultrathin glass folding device includes: a board-shaped base plate having a predetermined size; a driving unit installed on one side of the base plate to generate rotatory power; a rail unit of a predetermined length installed on one side of the driving unit; a sliding unit installed on the rail unit to slide back and forth in a predetermined distance along the rail unit by the rotation of the driving unit; a pressure plate of a predetermined size installed on the sliding unit at a right angle; and a fixing plate of a predetermined size installed on the base plate at a right angle to be spaced at intervals while facing the pressure plate. In a state where both ends of UTG are fixed to the pressure plate and the fixing plate to form a reverse U-shape, the pressure plate slides back and forth in a horizontal direction by the rotation of the driving unit. Therefore, the distance between the pressure plate and the fixing plate repeatedly increases or decreases, and the UTG is folded or unfolded at a predetermined curvature.

Description

Ultra-thin Glass Folding Device

The present invention relates to an ultra-thin glass folding device, and more particularly, to an ultra-thin glass folding device used for a folding fatigue test of a flexible material such as ultra-thin glass (hereinafter referred to as 'UTG').

In recent years, portable electronic devices such as smartphones that can be bent or folded by applying a flexible display have been developed. In order to test the durability of the flexible display, various types of folding devices that repeatedly perform a folding test are being developed.

As a prior art for this purpose, there is disclosed an apparatus for testing durability of a flexible display (hereinafter referred to as a 'patent document') of Korean Patent Application Laid-Open No. 2021-0084893.

The durability test apparatus disclosed in the patent document has a folding area of the flexible display interposed therebetween, vacuum-sucks and fixes a part of the non-folding side area, and holds the vacuum-adsorbed flexible display part at a certain distance as needed during the folding test. Fixed plate to elevate as much as; A rotation plate that vacuum-sucks and fixes a part of the other side area of the flexible display positioned opposite to the fixed plate with the folding area of the flexible display interposed therebetween, and rotates the vacuum-sucked flexible display part to be folded during a folding test ; And it is provided on both sides of the fixed plate side of the rotation plate consists of including a rotation driving unit for adding a rotation force so that the rotation plate is folded or unfolded.

However, the conventional folding device as described above is configured in such a way that the plates on both sides are folded around a hinge, and for this reason, slip occurs toward both ends of the flexible material during folding, and when the flexible material slips, the flexible material has a preset radius of curvature. Therefore, there is a problem in that it is difficult to accurately and repeatedly perform a folding test of a flexible material under the same conditions.

Therefore, it is required to develop a folding device with an improved structure so that the flexible material can be tested repeatedly under the same conditions when performing a folding test.

KR 10-2021-0084893 A (2021. 07. 08.) KR 10-2145682 B1 (2020. 08. 11.) KR 10-2101287 B1 (2020. 04. 09.) KR 10-2158041 B1 (2020. 09. 15.) KR 10-2053319 B1 (2019. 12. 02.)

The present invention has been devised to solve the problems of the conventional folding device as described above, and the problem to be solved by the present invention is an ultra-thin glass folding device that can be repeatedly tested under the same conditions when folding a flexible material. is to provide

Ultra-thin glass folding apparatus according to the present invention for solving the above problems, a plate-shaped base plate having a predetermined size; a driving unit installed on one side of the base plate to generate rotational power; a rail unit having a predetermined length installed on one side of the driving unit; a sliding unit installed on the rail unit and slid back and forth along the rail unit by a rotation operation of the driving unit; and a pressure plate of a predetermined size vertically installed on the sliding unit, and a fixing plate of a predetermined size vertically installed on the base plate to face the pressure plate and spaced apart by a predetermined distance, wherein both ends of the UTG are fixed to the pressure plate and the fixing plate In a state in which the pressure plate is reciprocally slid in the horizontal direction by the rotation operation of the driving unit in a state in which it is in an inverted "U" shape, the distance spaced from the fixed plate is repeatedly moved away from or approached, so that the UTG is not folded or unfolded with a set curvature. It is characterized in that it is configured so as to

The present invention is further characterized in that holders for fixing both ends of the UTG to the pressing plate and the fixing plate are installed.

In addition, the present invention is configured such that the holder is made of a flat plate of a predetermined length that horizontally crosses the lower portion of the pressing plate and the fixing plate, and is in close contact with the pressing plate and the fixing plate or spaced apart by a predetermined distance by loosening and tightening the fastening member Another feature.

In addition, the present invention is configured such that the holder is made of a flat plate of a predetermined length that horizontally crosses the lower part of the pressing plate and the fixing plate, and is configured to be maintained in elastically close contact with the pressing plate and the fixing plate through an elastic spring. characterized.

And another feature of the present invention is that by adjusting the distance between the driving unit and the sliding unit, the pressure plate is configured to be spaced apart from the fixed plate by adjusting the distance.

According to the present invention, both ends of the UTG are fixed through a holder installed on the pressure plate and the fixed plate, and in this state, the pressure plate slides by a preset distance to approach or move away from the fixed plate, through which both ends are fixed between the pressure plate and the fixed plate It has the advantage of being able to accurately test the performance of the UTG as the UTG is repeatedly folded with the same preset radius of curvature.

In addition, there is an advantage in that the UTG is structurally prevented from being scratched by sliding from the surfaces of the pressing plate and the fixing plate during the folding process.

1 is a perspective view showing an example of an ultra-thin glass folding device according to the present invention.
Fig. 2 is a plan view of Fig. 1;
Fig. 3 is a front view of Fig. 1;
4 is a view showing an example in which UTG is installed in the ultra-thin glass folding device according to the present invention.
5 is a view showing an example of folding the UTG through the ultra-thin glass folding device according to the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is to provide an ultra-thin glass folding device that can be repeatedly tested under the same conditions when performing a folding test of a flexible material, and the present invention for this purpose provides a base plate 10 as shown in FIGS. , a driving unit 20 , a rail unit 30 , a sliding unit 40 , a pressure plate 50 and a fixed plate 60 .

The base plate 10 is formed in a plate shape having a predetermined size and has a configuration in which a driving unit 20 , a rail unit 30 and a fixing plate 60 to be described later are installed, and the base plate 10 is a separate frame structure. (not shown) may be installed and used.

The driving unit 20 is installed on one side of the upper surface of the base plate 10 to generate rotational power.

As shown in FIGS. 1 to 3, the driving unit 20 includes a fixed bracket 21 of a predetermined size installed on the base plate 10, and a motor installed and fixed on one side of the fixing bracket 21 ( 22) and a disc-shaped rotating plate 23 installed on the rotating shaft 22A of the motor 22 and rotating with a predetermined diameter, and a sliding unit 40 having one end connected to the rotating plate 23 and the other end being described later. It includes a connection link 24 of a predetermined length connected to the hinge coupling portion 41 of the.

At this time, a hole 21A of a predetermined diameter is formed in the fixing bracket 21 , and the rotation shaft of the motor 22 is installed to pass through the other side of the fixing bracket 21 .

In addition, a plurality of coupling holes 23A having different distances from each other to the circumference from which the rotation shaft 22A is assembled may be formed in the rotary plate 23, and any one selected from among the plurality of coupling holes 23A may be coupled By connecting one end of the connecting link 24 to the ball 23A, the sliding unit 40 may be configured to adjust the sliding distance.

In addition to this, the connection link 24 is formed in a bar shape having a predetermined length, and a plurality of fastening holes 24A may be further formed along the length at a predetermined interval, and any one selected from the plurality of fastening holes 24A Connected by coupling to each other through a coupling pin (P) in a state such that the position of any one coupling hole (23A) selected from among the plurality of coupling holes (23A) of the one coupling hole (24A) and the rotating plate (23) is matched The sliding unit 40 through the link 24 may be configured to be able to adjust the sliding distance more variously.

On the other hand, in the above, the rotating plate 23 has been shown and described only as being formed in the shape of a disk having a predetermined diameter, but otherwise formed in an elliptical shape, and then the rotating shaft 22A is coupled to one end of the rotating plate 23. It may be changed to be formed with a plurality of coupling holes spaced apart from each other along the length of the rotary plate 23.

The rail unit 30 is installed on the upper surface of the base plate 10 and is configured to guide the sliding unit 40 to be described later by the rotational operation of the driving unit 20 to reciprocate sliding by a predetermined distance in the horizontal direction.

The rail unit 30 is composed of a guide rail 31 having a predetermined length as shown in FIGS. 1 to 3 and a transfer block 32 of a predetermined size transferred along the guide rail 31 .

At this time, the rail unit 30 is preferably composed of a linear guide having the advantage of less noise and vibration between sliding movements.

The sliding unit 40 is installed on the transfer block 32 of the rail unit 30 and slides a predetermined distance in the horizontal direction along the guide rail 31 of the rail unit 30 by the rotation operation of the driving unit 20 . It is a configuration that becomes

As shown in FIG. 3, the sliding unit 40 is formed in a cross-sectional shape of the letter "ㅗ", and a hinge coupling part 41 to which the other end of the connection link 24 is coupled is formed on one upper surface.

And the pressure plate 50 is installed and fixed to the upper surface of the other side through a fastening member such as a screw to be described later.

The pressure plate 50 is vertically installed on the sliding unit 40 and is configured to repeatedly press the UTG while being close to or spaced apart from the support plate 60 to be described later.

A groove of a predetermined size is formed in the lower portion of the pressing plate 50 to cross horizontally, and a holder H having a predetermined length is horizontally assembled in the groove through a fastening member such as a screw, and the pressing plate 50 After one end of the UTG 2 is inserted between the holder H and the holder H, the UTG 2 is firmly fixed by tightening the fastening member so that the holder H is in close contact with the pressure plate 50 .

In addition, it is possible to easily separate the UTG (2) fixed between the holder (H) and the pressing plate (50) by loosening the fastening member.

On the other hand, in the above, the holder (H) is shown and described only as being in close contact with the pressure plate 50 by being assembled through a fastening member, but unlike this, the holder (H) is attached to the pressure plate 50 through an elastic spring (not shown). It may be configured to remain in close contact.

Through this, one end of the UTG (2) is inserted in a state in which the holder (H) is moved elastically so that a spaced space of a predetermined size is formed between the holder (H) and the pressure plate (50), and then the holder (H) is subjected to the elastic force. By releasing the fixing of the holder (H) so that it is in close contact with the pressure plate 50 by the elastic force, the holder (H) is in close contact with the pressure plate 50, so that the UTG (2) is fixed.

Alternatively, the holder (H) is made of a ferromagnetic material and may be configured to be in close contact with the pressure plate 50 by magnetic force, through which one end of the UTG (2) is positioned between the pressure plates 50, and then the holder (H) By attaching to the pressure plate 50, the UTG (2) may be configured to be fixed.

The fixing plate 60 is vertically fixed to the base plate 10 while being spaced apart from the pressing plate 50 by a predetermined distance to face each other, and the other end of the UTG 2 is fixed.

The holding plate 60 has a holder (H) having the same structure as the holder (H) of the pressing plate 50 on one side facing the pressing plate 50, so that the other end of the UTG (2) is fixed.

Hereinafter, an example in which the ultra-thin glass folding device of the present invention is used will be described.

In a state in which the pressing plate 50 and the fixing plate 60 are maximally spaced apart from each other, as shown in FIG. 4, both ends of the UTG (2) are fixed through the holder (H) to form an inverted “U” shape, In this state, when power is applied to the motor 22 of the driving unit 20 to rotate the rotating plate 23 at a predetermined speed, the connection link 24 moves along the rotating plate 23 as shown in FIG. 5 . While the sliding unit 40 is slid, as a result, the pressing plate 50 is moved to be close to the fixed plate 60, and then reciprocally transferred to be spaced apart by a predetermined distance again, thereby rapidly folding and unfolding the UTG (2).

In this case, by accurately controlling the rotation speed of the motor 22 , the number of folding times and folding speed of the UTG 2 can be accurately controlled.

On the other hand, in the above, it has been described that the both ends of the UTG 2 are fixed to the pressing plate 50 and the fixing plate 60, respectively, and then the folding test is performed. ), and then slide the pressing plate 50 toward the fixing plate 60 so that the round bar is in close contact, and in this state, the coupling hole 24A of the connecting link 24 and the coupling hole 23A of the rotating plate 23) By tightening the coupling pin (P) at the position where the positions of After setting, the above test can proceed.

As described above, in the present invention, both ends of the UTG are fixed through a holder installed on the pressure plate and the fixed plate, and in this state, the pressure plate slides by a preset distance to approach or move away from the fixed plate, and through this, both ends between the pressure plate and the fixed plate As this fixed UTG is repeatedly folded with the same preset radius of curvature, it is possible to accurately test the performance of the UTG.

In addition, it is structurally prevented from being scratched unnecessarily due to slipping of the UTG during the folding test process.

In the above description, for convenience of description, reference numerals and names are given to the drawings showing preferred embodiments and configurations shown in the drawings, but this is an embodiment according to the present invention. It should not be construed as being limited, and that simple substitutions from the description of the invention into various predictable shapes and simple substitutions for the same function are within the scope of change for those skilled in the art to easily implement. It will be seen as extremely self-explanatory.

1: Folding device 2: UTG
10: base plate 20: drive unit
21: fixing bracket 21A: through hole
22: motor 22A: rotation shaft
23: rotary plate 23A: coupling hole
24: connection link 24A: fastener
30: rail unit 31: guide rail
32: transfer block 40: sliding unit
41: hinge coupling part 50: pressure plate
60: fixing plate H: holder
P: coupling pin

Claims (5)

In the folding device (1) for testing the folding performance of the UTG (2),
The folding device (1),
a plate-shaped base plate 10 having a predetermined size;
a driving unit 20 installed on one side of the base plate 10 to generate rotational power;
a rail unit 30 having a predetermined length installed on one side of the driving unit 20;
a sliding unit 40 installed on the rail unit 30 and reciprocally slid along the rail unit 30 by a rotational operation of the driving unit 20;
a pressure plate 50 of a predetermined size vertically installed on the sliding unit 40; and
a fixing plate 60 of a predetermined size vertically installed on the base plate 10 so as to face the pressing plate 50 and spaced apart by a predetermined distance;
including,
In a state where both ends of the UTG 2 are fixed to the pressure plate 50 and the fixing plate 60 to form an inverted "U" shape, the pressure plate 50 is rotated by the driving unit 20 by the rotation operation. It is configured to be reciprocally slid in the horizontal direction so that the distance spaced from the fixed plate 60 is repeatedly moved away or approached so that the UTG (2) is folded or unfolded with a set curvature,
The driving unit 20,
a fixing bracket 21 of a predetermined size installed on the base plate 10;
a motor 22 installed and fixed to one side of the fixing bracket 21;
a disc-shaped rotating plate 23 installed on the rotating shaft 22A of the motor 22 and having a predetermined diameter to be rotated; and
a connection link 24 having one end connected to the rotating plate 23 and the other end connected to a hinge coupling part 41 of a sliding unit 40 to be described later;
including,
In the rotating plate 23,
A plurality of coupling holes 23A having different distances to each other are formed around the rotation shaft 22A,
The connecting link 24 is,
While being formed in a bar shape having a predetermined length, a plurality of fastening holes 24A are formed along the length at predetermined intervals,
Any one of the coupling holes (24A) selected from the plurality of coupling holes (24A) and the position of any one coupling hole (23A) selected from the plurality of coupling holes (23A) of the rotary plate (23) to match The distance at which the sliding unit 40 slides through the connection link 24 is controlled by mutual coupling through the coupling pin P in the state, and the distance at which the pressing plate 50 is spaced apart from the fixing plate 60 Ultra-thin glass folding device, characterized in that configured to be adjusted.
The method according to claim 1,
In the pressure plate 50 and the fixing plate 60,
Ultra-thin glass folding device, characterized in that the holder (H) for fixing both ends of the UTG (2) is installed.
3. The method according to claim 2,
The holder (H),
It is made of a flat plate of a predetermined length that horizontally crosses the lower portion of the pressing plate 50 and the fixing plate 60, and is in close contact with the pressing plate 50 and the fixing plate 60 by loosening and tightening the fastening member or spaced apart by a predetermined distance. Ultra-thin glass folding device, characterized in that it is configured to be.
3. The method according to claim 2,
The holder (H),
It consists of a flat plate of a predetermined length that horizontally crosses the lower portion of the pressure plate 50 and the fixing plate 60, and is configured to be maintained in elastically close contact with the pressure plate 50 and the fixing plate 60 through an elastic spring. Ultra-thin glass folding device, characterized in that it becomes.
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