JPH0952726A - Inscribing line imparting device for thin sheet glass under movement - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an inscribing line imparting device for thin sheet glass under movement capable of automating the inscribing line imparting work onto the thin sheet glass under movement and continuously producing the thin sheet glass. SOLUTION: A cutter wheel 3 is pressed to the thin sheet glass 1 by a pressure contact mechanism 6 in the state of pressing and supporting the cutter wheel by a surface plate 4 and is made to travel in the transverse direction of the thin sheet glass 1 by a cross feed mechanism 5. The cutter wheel 3 and the surface plate 4 are moved at the same speed in the same direction as the flow direction of the thin sheet glass 1 by a longitudinal feed mechanism 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engraving device for moving thin glass used in a process of manufacturing thin glass having a thickness of up to several millimeters used for flat display devices such as liquid crystals. is there.

[0002]

2. Description of the Related Art A plate glass produced by continuous plate-making is cut by forming a score line on one surface of the plate glass in a direction perpendicular to the flow direction, and then breaking along the score line.

Conventionally, there has been a marking line applying device for making a marking line on the glass by a machine if the thickness of the plate glass to be continuously made is several millimeters or more. However, if the thickness of the plate glass is several millimeters or less, a cutter wheel is used. When pressed against, the plate glass bends and escapes and no pressing force is applied, so there was no suitable mechanized marking device for thin glass.

[0004]

Therefore, in the past, it was tried to manually give a score line, but the work efficiency was poor, and it hindered the continuous production of thin glass sheets.

It is an object of the present invention to provide an engraving device for a thin glass sheet during movement which automates the work of engraving a thin glass sheet on the move and enables continuous production of thin glass sheets.

[0006]

In order to achieve the above-mentioned object, the present invention is a marking line applying device for applying a cutting line to a thin glass plate continuously produced by a cutter wheel in a direction perpendicular to the flow direction. , A cutter wheel that engraves a line on one surface side of the thin glass, a surface plate that abuts and supports the thin glass over the entire width across the other surface side of the thin glass, and the cutter wheel is in contact with the thin glass. A transverse feed mechanism that supports the sheet glass so that it can travel in a direction perpendicular to the flow of the sheet glass, a contact pressure mechanism that applies a contact pressure to the cutter glass to the cutter wheel, and a contact pressure of the cutter wheel by bringing the platen into contact with the sheet glass. It is possible to move the contact pressure support mechanism that supports the above, the transverse feed mechanism and contact pressure mechanism of the cutter wheel, and the contact pressure support mechanism of the surface plate in the same direction as the flow of the thin sheet glass according to the moving speed of the thin sheet glass. Which is constituted by a longitudinal feeding mechanism for supporting.

As described above, the cutter wheel is pressed against the thin glass sheet by the contact pressure mechanism while being brought into contact with and supported by the surface plate, and the transverse feed mechanism causes the sheet glass to run in the lateral width direction of the thin glass sheet to flow to the thin glass sheet. You can engrave in a direction perpendicular to the direction. The cutter wheel and surface plate are
With the vertical feed mechanism, the sheet is moved in the same direction as the flow of thin glass at the same speed, so there can be no relative speed difference in the flow direction of the thin glass, and the marking work can be performed reliably and accurately. Can be made.

[0008]

1 (A) and 1 (B) are a plan view and a side view of a marking line applying apparatus according to the present invention, and FIG. 2 is a schematic perspective view of a marking line applying mechanism. In the figure, 1 is thin glass, 2 is a transport roller, 3 is a cutter wheel, 4
Is a surface plate, 5 is a cutter wheel lateral feed mechanism, 6 is a cutter wheel contact pressure mechanism, 7 is a surface plate contact pressure support mechanism, 8
Is a vertical feed mechanism for a cutter wheel and a surface plate, and 9 is a measuring roller.

The thin glass plate 1 is continuously made into a plate, and has a predetermined thickness (for example, 1.5 mm or less) and a width (for example, 50).
0 mm) and conveyed by the conveying roller 2 to the marking line applying device according to the present invention. The transport roller 2 has a cushioning material such as rubber coated on the contact surface with the thin glass plate 1.

The scoring device according to the present invention is for putting a scoring line on one surface side of a thin glass sheet 1 which is continuously produced in a direction perpendicular to the flow direction of the thin glass sheet 1. In order to make a score line without stopping the flow of No. 1, the means for putting the score line is configured to move at the same speed in the same direction as the flow direction of the thin glass sheet 1 while the score line is being made.

The means for forming the score line is a cutter wheel 3 arranged on one side of the thin glass plate 1 so as to be movable in a direction perpendicular to the flow direction of the thin glass plate 1, and a thin glass plate facing the cutter wheel 3. In order to ensure that the thin glass sheet 1 is placed in contact with and supported by the cutter wheel 3 from the side opposite to the position where the cutter wheel 3 inserts the engraving line, and the engraving work by the cutter wheel 3 is ensured. And the surface plate 4 of.

The cutter wheel 3 has a substantially abacus ball shape, and as best shown in FIG. 2, is supported by the transverse feed mechanism 5 via a contact pressure mechanism 6 for contacting the thin glass plate 1. The contact pressure mechanism 6 is composed of an air cylinder 6a, and a cutter wheel 3 is rotatably attached to a support tool 6c attached to the tip of a piston rod 6b of the air cylinder 6a via a shaft 6d.

The lateral feed mechanism 5 includes a slide block 5c slidably supported on the moving base 5a via guide rails 5b in a direction perpendicular to the flow direction of the thin glass sheet 1, and a ball screw screwed to the slide block 5c. 5d and a motor 5e that drives the ball screw 5d to rotate forward and backward, and the cutter wheel 3 is supported by the slide block 5c via the contact pressure mechanism 6, whereby the cutter wheel 3 is made of thin glass. It is possible to move in the direction perpendicular to the flow direction of 1.

The surface plate 4 has a length corresponding to the entire length in the direction perpendicular to the flow direction of the thin glass plate 1, that is, in the width direction, and the contact surface with the thin glass plate 1 has a cushioning material (not shown) such as a rubber plate. ) Is attached.

The contact pressure support mechanism 7 of the surface plate has a gate-shaped frame 7a attached to the moving table 5a so as to straddle the flow of the thin glass plate 1, and an air installed on the support plate 7b of the gate-shaped frame 7a. A cylinder 7c and a guide rod 7d are provided. A platen 4 is attached to the tip of a piston rod 7e of the air cylinder 7c, and a guide rod 7d is attached to the platen 4. Is slidably inserted into and supported by a supporting plate 7b, whereby the surface plate 4 is fixed to the thin glass plate 1 by the air cylinder 7c.
The surface plate 4 is guided so as to move in parallel during the approaching and separating operations.

The vertical feed mechanism 8 includes a movable table 5a and a fixed table 8a.
On the other hand, the guide rail 8b that is movably mounted along the flow direction of the thin glass sheet 1 and the thin glass sheet 1 on the fixing base 8a.
Of a ball screw 8c which is arranged along the flow direction of 3 and is screwed to the moving table 5a, and a motor 8d which drives the ball screw 8c to rotate in the forward and reverse directions. The cutter wheel 3 and the surface plate 4 are moved in the same direction as the thin glass plate 1 at the same speed.

The measuring roller 9 is a thin glass plate 1.
Of the vertical feed mechanism 8 is controlled to move the cutter wheel 3 and the surface plate 4 in the same direction as the thin glass plate 1 at the same speed. It is what makes me.

An embodiment of the present invention has the above-described configuration.
Next, the operation will be described. The thin glass plate 1 continuously produced is conveyed by the conveying roller 2 to the position of the cutter wheel 3. The measuring roller 9 converts the moving speed of the thin glass plate 1 into an electric pulse signal and detects it.
As a result, the motor 8d of the vertical feed mechanism 8 is rotationally driven in the positive direction at a predetermined speed, and the moving table 5 is moved through the ball screw 8c.
A is started to move in the same direction as the thin glass plate 1 at the same speed. Then, the air cylinders 6a and 7c are extended to apply the cutter wheel 3 and the surface plate 4 to the thin glass plate 1 from both sides. Then, the motor 5e is rotationally driven in the forward direction, and the slide block 5c is started to move in the direction perpendicular to the flow direction of the thin glass sheet 1 via the ball screw 5d. As a result, the cutter wheel 3 is attached to the slide block 5
The movement starts in a direction perpendicular to the flow direction of the thin sheet glass 1 integrally with c, and a marking line is formed on one surface side of the thin sheet glass 1 in a direction perpendicular to the flowing direction of the thin sheet glass 1. In this case, since the surface on the opposite side of the thin glass plate 1 to which the cutter wheel 3 gives the scribe line is brought into contact with and supported by the surface plate 4, the position of the thin glass plate 1 does not change and the thin glass plate 1 is cut by the cutter wheel 3. It is possible to accurately insert a scored line having a predetermined depth in 1. Further, since the cutter wheel 3 and the surface plate 4 are moved in the same direction as the thin glass plate 1 at the same speed, the thin glass plate 1
There is no relative speed difference with respect to the flow direction of, and since it is as if the thin glass sheet 1 stops the flow and is marked, the marking is surely and easily performed.

When the cutter wheel 3 is moved from one end to the other end in the width direction of the thin glass plate 1 in this manner, the marking line finishes and immediately the air cylinders 6a and 7c are contracted to cause the cutter wheel 3 to move. And the surface plate 4 is separated from the thin glass plate 1 to both sides, and subsequently, the motor 5e and the motor 8d are rotated in the opposite directions to return the movable table 5a and the slide block 5c to their original positions via the ball screws 5d and 8d. , Wait for the next engraving command. When the next marking line assignment command is issued, the above operation is repeated. Motor 5e
The speed of the motor 8d is set so as not to interfere with the repetition of the above operation cycle.

The thin glass sheet 1 in which the marking lines have been marked by the marking device is folded and cut from the position of the marking lines in a subsequent process, and is carried out.

The above embodiment shows a case where the flow of the thin glass 1 is horizontal, the cutter wheel 3 is installed on the lower surface side of the thin glass 1, and the surface plate 4 is installed on the upper surface side of the thin glass 1. The glass powder generated at the time of giving the score line is preferable because it does not fall and adhere to the thin glass plate 1. But,
The flow direction of the thin glass sheet 1 may be inclined other than horizontal, curved, or vertical, and the cutter wheel 3 and the surface plate 4 may be arranged in an upside-down relationship. Good.

[0022]

EFFECTS OF THE INVENTION According to the present invention, it is possible to stably engrave the thin glass sheets which are continuously produced and flow, and to impart the engraving lines which enable continuous production of thin glass sheets. A device can be provided.

[Brief description of drawings]

1A and 1B are a plan view and a side view showing an embodiment of an engraving device for a thin glass sheet during movement according to the present invention.

FIG. 2 is a schematic perspective view of a marking line applying device.

[Explanation of symbols] 1 thin glass 2 conveying roller 3 cutter wheel 4 surface plate 5 lateral feed mechanism 6 pressure contact mechanism 7 pressure contact support mechanism 8 vertical feed mechanism 9 majoring roller

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Seiichi Oyu, 2-7-1, Hararashi, Otsu, Shiga Prefecture, Nippon Electric Glass Co., Ltd.

Claims (1)

[Claims] 1. A scoring device for scoring thin glass to be continuously manufactured by a cutter wheel in a direction perpendicular to the flow direction, which is a cutter wheel for scoring one surface of thin glass. A surface plate that abuts and supports the thin glass on the other side of the thin glass over the entire width in the lateral direction, and a lateral feed that supports the cutter wheel to the thin glass and supports it so that it can travel in a direction perpendicular to the flow of the thin glass. A mechanism, a contact pressure mechanism for applying a contact pressure to the thin glass to the cutter wheel, a contact pressure support mechanism for supporting the contact pressure of the cutter wheel by bringing the platen into contact with the thin glass, and a lateral side of the cutter wheel. It is characterized by having a feed mechanism, a contact pressure mechanism, and a vertical feed mechanism that movably supports the contact pressure support mechanism of the surface plate in the same direction as the flow of the thin glass plate in accordance with the moving speed of the thin glass plate. An engraving device for thin glass on the move.