KR20210143165A - Glass plate end surface processing apparatus and glass plate manufacturing method - Google Patents

Abstract

The end surface processing apparatus 1 includes a rocking arm member 4 supporting the grindstone 2, and a servo motor 5 for generating a driving force for the grinding stone 2 to press the end surface E of the glass plate G. ) and a link mechanism (6) for transmitting the driving force of the servo motor (5) to the arm member (4). The link mechanism 6 includes a first link member 6a pivotable by a servo motor 5, and a second link member 6b pivotably connected to each of the arm member 4 and the first link member 6a. ) is provided. The end surface processing apparatus 1 is a state in which the grinding stone 2 is in contact with the end surface E of the glass plate G, the orthogonal direction Ar of the longitudinal direction A of the first link member 6a and the second link The angle θ1 formed by the longitudinal direction B of the member 6b is formed by the orthogonal direction Cr of the longitudinal direction C of the female member 4 and the longitudinal direction B of the second link member 6b. It is configured to be larger than the angle θ2.

Description

Glass plate end surface processing apparatus and glass plate manufacturing method

This invention relates to the manufacturing method of the end surface processing apparatus of a glass plate, and a glass plate.

In recent years, in order to meet the improvement request with respect to the production efficiency of a liquid crystal display etc., the improvement request|requirement with respect to the manufacturing efficiency of the glass substrate used for the said display etc. is increasing. Here, in manufacture of a glass substrate, cutting out a glass substrate of 1 sheet or multiple sheets from a large sized glass original plate (molding original plate) is performed. Thereby, the glass substrate of a desired dimension can be acquired.

On the other hand, since the end surface of the glass substrate cut out from the glass original plate becomes a cut surface or a breaking surface normally, a micro flaw (defect) exists in many cases. Since a crack etc. will generate|occur|produce from the wound when there is a wound on the end surface of a glass substrate, in order to prevent this, grinding processing (rough processing) and polishing processing (finishing processing) are performed with respect to the end surface of a glass substrate.

As an end surface processing apparatus for a glass plate used for this type of end surface processing, for example, Patent Document 1 discloses a swingable arm member for supporting a processing tool, and a pressing force applied from the processing tool to the end surface of the glass plate through the arm member. Disclosed is an end face machining apparatus, so-called static pressure type, provided with an actuator (pressing force generating element) that generates it.

International Publication No. 2013/187400

In the static pressure type end surface processing device, depending on the processing conditions such as the type of whetstone or the type of glass, the pressing force of the processing tool to the end surface of the glass plate may become insufficient, and in this case, the processing quality of the end surface of the glass plate is reduced. . For example, since it is necessary to strongly press a processing tool with respect to a glass plate when using the grindstone for grinding|polishing, a pressing force becomes insufficient and processing quality falls easily.

This invention makes it a subject to maintain the processing quality of the end surface of a glass plate favorably by ensuring the pressing force of the processing tool with respect to the end surface of a glass plate.

The present invention, devised to solve the above problems, is a device for processing the end surface of a glass plate for processing the end surface of the glass plate into a processing tool. and a link mechanism for transmitting the driving force of the actuator to the arm member, the link mechanism comprising: a first link member oscillating by the actuator; and a second link oscillatingly connected to each of the arm member and the first link member In a state in which a member is provided and the processing tool is in contact with the end surface of the glass plate, an angle formed between the longitudinal direction of the first link member and the longitudinal direction of the second link member is equal to the orthogonal direction to the longitudinal direction of the female member. It is characterized in that it is configured to be larger than the angle formed by the longitudinal direction of the two link members.

According to the above configuration, when the actuator moves the processing tool in a direction for pressing the processing tool against the end surface of the glass plate, the first link member oscillated by the actuator presses the second link member by the second link member, rather than the magnitude of the force. Among the forces acting on the pressed arm member, the magnitude of the component of the force acting in the swinging direction of the arm member increases. That is, since the pressing force of the processing tool with respect to the end surface of a glass plate can be enlarged by amplifying the driving force of an actuator with a link mechanism, the processing quality of the end surface of a glass plate can be maintained favorably.

In the said structure, it is preferable that a processing tool is a grindstone for grinding|polishing.

In general, it is necessary to increase the pressing force applied to the end face of the glass plate compared to the grinding wheel for grinding. If it sets it as the structure which can enlarge the pressing force with which a processing tool presses the end surface of a glass plate like this invention, even if it is a grindstone for grinding|polishing, it will become easy to ensure a required pressing force.

The present invention, devised to solve the above problems, is a method for manufacturing a glass plate having an end surface processing step of processing the end surface of the glass plate into a processing tool by an end surface processing device, the end surface processing device comprising: a swingable arm member supporting the processing tool; , an actuator for generating a driving force for pressing the end surface of the glass plate by the processing tool, and a link mechanism for transmitting the driving force of the actuator to the arm member, the link mechanism comprising a first link member capable of swinging by the actuator, the arm member and A second link member oscillatingly connected to each of the first link members is provided, and in the end face processing step, in a state in which the machining tool is in contact with the end face of the glass plate, the longitudinal direction of the first link member and the second link member are orthogonal to the longitudinal direction of the first link member. An angle formed by the longitudinal direction of is larger than an angle formed between the orthogonal direction of the longitudinal direction of the female member and the longitudinal direction of the second link member.

In this way, even when the driving force of the actuator is small for the same reason as the above-described configuration, in the end surface processing step, the pressing force with which the processing tool presses the end surface of the glass plate is increased, and the processing quality of the end surface of the glass plate is maintained well. can

ADVANTAGE OF THE INVENTION According to this invention, the processing quality of the end surface of a glass plate can be maintained favorably by ensuring the pressing force of the processing tool with respect to the end surface of a glass plate.

BRIEF DESCRIPTION OF THE DRAWINGS It is a top view which shows the end surface processing apparatus which concerns on embodiment of this invention.
FIG. 2 is a plan view showing an enlarged part of the end surface processing apparatus of FIG. 1 .
3 is a plan view showing an enlarged part of an end surface processing apparatus according to another embodiment of the present invention.
It is a top view which enlarges and shows a part of the end surface processing apparatus which concerns on another embodiment of this invention.
It is a top view which enlarges and shows a part of the end surface processing apparatus which concerns on another embodiment of this invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described, referring drawings.

As shown in Fig. 1, the end surface processing device 1 includes a motor 3 for rotationally driving a grinding stone 2 as a processing tool, a female member 4 for rotatably supporting the grinding stone 2, and a grinding stone 2 ) a servo motor 5 as an actuator that generates a driving force for pressing the end surface E of the glass plate G, and a link mechanism 6 that transmits the driving force of the servo motor 5 to the arm member 4 be prepared Such an end surface processing apparatus 1 is called a so-called static pressure type.

Although a synchronous motor, an induction motor, a servo motor, etc. can be used for the motor 3 which rotationally drives the grindstone 2, it is not limited to this.

The arm member 4 is rotatably supported by the support shaft member 7 , and can swing around the support shaft member 7 . The support shaft member 7 supports the middle portion of the arm member 4 . One end of the female member 4 supports the motor 3 , and the grindstone 2 is supported via the motor 3 . The other end of the female member 4 is connected to the link mechanism 6 . Moreover, although not shown in figure, on the rocking|fluctuation trajectory of the arm member 4, the stopper which regulates the range of the rocking|fluctuation of the arm member 4 is provided. The stopper is retractable from the arm member 4 while the grindstone 2 is in contact with the end surface E of the glass plate G.

The servo motor 5 for pressing the grindstone 2 to the end surface E of the glass plate G is provided with the motor shaft 5a rotatable in a forward and reverse direction, and the control part 5b, and feedback control is performed, have.

The link mechanism (6) includes a first link member (6a) and a second link member (6b) so as to be able to swing, respectively. One end of the first link member 6a is fixed to the motor shaft 5a of the servo motor 5, and the other end thereof swings at one end of the second link member 6b through the first joint 6c. possibly connected. That is, the 1st link member 6a swings centering on the motor shaft 5a by rotation of the motor shaft 5a. The other end of the second link member 6b is pivotably connected to the other end of the female member 4 through a second joint 6d. Moreover, in this embodiment, the center of the 2nd joint 6d, the center of the support shaft member 7, and the center of the rotating shaft 2a of the grindstone 2 are arranged on the same straight line.

As shown in FIG. 2 , when the motor shaft 5a of the servo motor 5 rotates counterclockwise, the arm member 4 also rotates counterclockwise with the support shaft member 7 by the link mechanism 6 . rotate to Thereby, the grindstone 2 moves to the direction pressed with respect to the end face E of the glass plate G, and the force which the grindstone 2 presses the end face E of the glass plate G increases. On the other hand, when the motor shaft 5a of the servo motor 5 rotates clockwise as opposed to FIG. 2 , the arm member 4 also rotates clockwise around the support shaft member 7 by the link mechanism 6 . do. Thereby, the grindstone 2 moves in the direction to avoid with respect to the end surface E of glass plate G, and the force with which the grindstone 2 presses the end surface E of glass plate G decreases.

The control unit 5b monitors the speed, torque, and position of the motor shaft 5a of the servo motor 5 by feedback control. The position and pressing force of the grindstone 2 are controlled by rotating the motor shaft 5a of the servomotor 5 in the forward and reverse directions according to this speed, torque, and position.

The whetstone 2 may be, for example, a grinding wheel whose main purpose is chamfering of the end surface E, or may be a grinding stone whose main purpose is to even out minute irregularities of the end surface E. The grain size of the abrasive grains in the grinding stone is equal to or larger than the grain size of the abrasive grains in the grinding stone. The grain size of the abrasive grains in the grinding stone can be, for example, #100 to #1000, and the grain size of the abrasive grains in the grinding stone can be, for example, #200 to #1000. The diameter of the grindstone 2 is 100-200 mm, for example.

As shown in FIG. 1, in this embodiment, the two end surface processing apparatuses 1 are arrange|positioned at the position which opposes across the glass plate G. That is, the end surface E of two opposite sides of the glass plate G is each simultaneously processed by the end surface. Moreover, you may arrange|position the some end surface processing apparatus 1 in one side of the glass plate G. In this case, the kind of the grindstone 2 of each end surface processing apparatus 1 may be the same, and may differ. For example, the grindstone 2 of the upstream end surface processing apparatus 1 which processes the end surface E first is used as a grindstone for grinding, and the downstream end surface which follows this and processes the end surface E from the back. It is good also considering the grindstone 2 of the processing apparatus 1 as a grindstone for grinding|polishing.

The glass plate G used as the process object of the end surface processing apparatus 1 has a rectangular plate shape, for example. It is preferable that they are 0.05 mm - 10 mm, for example, and, as for the thickness dimension of glass plate G, it is more preferable that they are 0.2 mm - 0.7 mm. Of course, the glass plate G to which this invention is applicable is not limited to the said form. For example, this invention is applicable also to the glass plate which has a shape (for example, polygon) other than a rectangle, and the glass plate of the size out of thickness dimension 0.05 mm - 10 mm.

The glass plate (G) can move relatively along a predetermined transfer direction (X) with respect to the grindstone (2). Moreover, in FIG. 1, the glass plate G moves to the conveyance direction X, and the case where the grindstone 2 is fixed is shown. Of course, the glass plate G is fixed, and the grindstone 2 may move in the direction opposite to the conveyance direction X, and both of the glass plate G and the grindstone 2 may move.

Next, the manufacturing method of the glass plate using the edge processing apparatus 1 of the said structure is demonstrated.

The manufacturing method which concerns on this embodiment is equipped with the preparatory process of preparing glass plate G, and the end surface processing process of processing the end surface E of the prepared glass plate G. Moreover, you may perform processes, such as washing|cleaning of glass plate G, a test|inspection, packing, after an end surface processing process. The end surface processing process can be performed independently.

In a preparatory process, first, a shaping|molding original board is obtained by a well-known shaping|molding method. Then, the glass plate G used as the process object of the end surface processing apparatus 1 is obtained by cutting out the shaping|molding original board to a predetermined dimension. As a shaping|molding method, down-draw methods, such as an overflow down-draw method, a slot down-draw method, a re-draw method, and a float method can be used, for example. Among them, the overflow down-draw method is preferable because the surfaces of both sides are forged and high surface quality can be realized. Glass plate G is used for glass substrates for flat panel displays, such as a liquid crystal display, for example.

In the end surface processing step, first, the rotated grindstone 2 is disposed at a predetermined position by rotation of the servomotor 5 . In this state, the glass plate G is conveyed along the conveyance direction X, and the grindstone 2 is made to contact the end surface E of the glass plate G. At the time of this processing start (at the time of processing of the part shown by the code|symbol Ea of FIG. 1), by the impact accompanying the contact of the edge surface E of the grindstone 2 and the glass plate G, the grindstone 2 is a glass plate ( G) tries to get away from it. In order to respond to this, the control part 5b performs feedback control of the speed and torque of the motor shaft 5a of the servomotor 5 (for example, PID control). Specifically, the control unit 5b detects the movement of the arm member 4 moving together with the grindstone 2 based on the speed of the motor shaft 5a of the servo motor 5 . In accordance with the detection result, the control unit 5b controls the speed and torque of the motor shaft 5a of the servo motor 5 so as to suppress the movement of the arm member 4 . The pressing force of the grindstone 2 is adjusted so that the grindstone 2 may not fall from the end surface E of the glass plate G by this. Therefore, the bounding of the grindstone 2 at the time of a process start can be prevented.

Moreover, also in the process of the intermediate part (the part between the part shown by the part and the part shown by the code|symbol Eb) of the conveyance direction among the end surfaces E of the glass plate G, the motor shaft 5a of the servomotor 5 ) and feedback control of speed and torque. At that time, the ratio of the speed control and the torque control is changed to increase the ratio of the torque control. This ratio can be changed by changing the gain setting. Thereby, the amount of processing of the end surface E of glass plate G can be kept constant in a conveyance direction.

When the said end surface processing is complete|finished, since the contact of the end surface E of the grindstone 2 and the glass plate G is cancelled|released, the torque of the motor shaft 5a of the servo motor 5 decreases rapidly. Therefore, the control unit 5b controls the feedback control of the speed and torque of the motor shaft 5a of the servomotor 5 so that the position of the grindstone 2 becomes constant at the end of the machining (at the time of machining the portion indicated by the symbol Eb). do In addition, the said control method by the control part 5b is an example, and is not limited to this.

As shown in Fig. 2, in the end surface processing step, the motor shaft 5a of the servo motor 5 rotates counterclockwise, and the grindstone 2 is moved in the direction to be pressed against the end surface E of the glass plate G. Although not shown, the motor shaft 5a of the servo motor 5 rotates in a clockwise direction and moves the grindstone 2 in a direction to be separated with respect to the end surface E of the glass plate G. there is

The angle between the orthogonal direction Ar of the longitudinal direction A of the first link member 6a in the first joint 6c and the longitudinal direction B of the second link member 6b is θ1, the second If the angle formed by the orthogonal direction Cr of the longitudinal direction C of the female member 4 in the joint 6d and the longitudinal direction B of the second link member 6b is θ2, θ1 > θ2 relationship is to be established. The angular relationship of this (theta)1 and (theta)2 is always satisfied during from the time of the process start of the end surface E of glass plate G to the time of a process completion|finish.

Here, (theta)1 and (theta)2 mean the angle in the state which the grindstone 2 contacted the end surface E of the processing object of glass plate G. In addition, the longitudinal direction A of the first link member 6a is the center of the motor shaft 5a of the servo motor 5 (the swinging center of the first link member 6a) and the center of the first joint 6c. means the direction of a straight line connecting, the longitudinal direction (B) of the second link member (6b) means the direction of a straight line connecting the center of the first joint (6c) and the center of the second joint (6d), The longitudinal direction C of the arm member 4 refers to the direction of a straight line connecting the center of the second joint 6d and the center of the support shaft member 7 (the swinging center of the arm member 4).

As shown in Fig. 2, when the grindstone 2 is moved in the pressing direction, the force of the first link member 6a pressing the second link member 6b (strictly, the pressing force of the first joint 6c). ) (F1) is a direction parallel to the orthogonal direction (Ar) of the longitudinal direction (A) of the first link member (6a). On the other hand, among the forces acting on the arm member 4 pressed by the second link member 6b (strictly, the force acting on the second joint 6d), the arm member 4 is oscillated in the counterclockwise direction. The force F2 is in a direction parallel to the orthogonal direction Cr of the longitudinal direction C of the arm member 4 . Therefore, the relationship F2=F1cosθ2/cosθ1 is established, and since θ1 is greater than θ2, F2 becomes greater than F1. That is, by amplifying the driving force of the servomotor 5 by the link mechanism 6, the pressing force with which the grindstone 2 presses the end surface E of the glass plate G can be enlarged. Therefore, for example, even when the driving force (output range) of the servomotor 5 is small, or when a grinding wheel which requires a large pressing force is used, a necessary pressing force can be ensured.

θ1 may be an angle exceeding 0°, and θ2 may be, for example, 0° or more. If ?1-?2 is increased, the pressing force can be made larger, but it becomes difficult to finely adjust the pressing force. From a viewpoint of making these compatible, it is preferable that θ1-θ2 is, for example, 5-85°, more preferably 7.5-70°, and most preferably 10-45°. It is preferable that it is 1.02-20, for example, as for cos(theta)2/cos(theta)1, it is more preferable that it is 1.04-10, It is most preferable that it is 1.06-5.

The magnitudes of θ1 and θ2 are, for example, the lengthwise dimensions of the arm member 4, the first link member 6a, and the second link member 6b, and the motor shaft 5a of the servo motor 5. and by changing the attachment position of the support shaft member 7 .

As mentioned above, although embodiment of this invention was described, of course, the end surface processing apparatus and manufacturing method of the glass plate which concern on this invention are not limited to this form, It is possible to take various forms within the scope of the present invention.

In the above embodiment, in the arm member 4, the case has been described in which the second joint 6d, the support shaft member 7, and the rotation shaft 2a of the grindstone 2 are arranged on the same straight line, but the arm member ( 4) is a straight line connecting the center of the second joint 6d and the center of the support shaft member 7, and a straight line connecting the center of the support shaft member 7 and the center of the rotation shaft 2a of the grindstone 2 It may be a shape that is not arranged on the same straight line and has an angle of less than 180°. Also in this case, the longitudinal direction C of the arm member 4 is defined as the direction of a straight line connecting the center of the second joint 6d and the center of the support shaft member 7 .

In the said embodiment, although the grindstone 2 was illustrated as a processing tool, as long as a processing tool can process the end surface E of glass plate G, other than a grindstone may be sufficient.

Although the servomotor which has the motor shaft 5a was illustrated as an actuator in the said embodiment, the actuator may be a well-known actuator other than a servomotor, such as a pneumatic actuator, a hydraulic actuator, and an electromechanical actuator.

In the above embodiment, in Fig. 2, the orthogonal direction Ar of the longitudinal direction A of the first link member 6a is an angle of θ1 counterclockwise from the longitudinal direction B of the second link member 6b. In addition to having , the case in which the orthogonal direction Cr of the longitudinal direction C of the arm member 4 has an angle of θ2 in the clockwise direction from the longitudinal direction B of the second link member 6b was exemplified, The directions of θ1 and θ2 with respect to the longitudinal direction B of the second link member 6b are not particularly limited.

That is, as shown in FIG. 3, even if the orthogonal direction Cr of the longitudinal direction C of the female member 4 has an angle of θ2 in the counterclockwise direction from the longitudinal direction B of the second link member 6b. OK (the direction of θ2 is opposite).

Further, as shown in Fig. 4, even if the orthogonal direction Ar of the longitudinal direction A of the first link member 6a has an angle of θ1 in the clockwise direction from the longitudinal direction B of the second link member 6b. OK (the direction of θ1 is opposite).

5, the orthogonal direction Ar of the longitudinal direction A of the first link member 6a has an angle of θ1 in the clockwise direction from the longitudinal direction B of the second link member 6b; In addition, the orthogonal direction Cr of the longitudinal direction C of the female member 4 may have an angle of θ2 counterclockwise from the longitudinal direction B of the second link member 6b (the angle of θ1 and θ2). opposite direction).

1: End face processing device
2: Whetstone (tool)
3: Motor
4: female member
5: Servo motor (actuator)
5a: motor shaft
5b: control
6: Link mechanism
6a: first link member
6b: second link member
6c: first joint
6d: second joint
7: Support shaft member
G: glass plate
E: end face

Claims (3)

As an end surface processing device for processing the end surface of the glass plate into a processing tool,
A swingable arm member for supporting the processing tool, an actuator for generating a driving force for the processing tool to press the end surface of the glass plate, and a link mechanism for transmitting the driving force of the actuator to the arm member;
The link mechanism includes a first link member pivotable by the actuator, and a second link member pivotably connected to each of the arm member and the first link member;
In a state in which the processing tool is in contact with the end surface of the glass plate, an angle formed between a longitudinal direction of the first link member and a longitudinal direction of the second link member is perpendicular to the longitudinal direction of the arm member and The end surface processing apparatus of the glass plate characterized in that it is comprised so that it may become larger than the angle which the longitudinal direction of the said 2nd link member makes. The method of claim 1,
The processing tool is an end surface processing apparatus for a glass plate, characterized in that the grinding stone. As a manufacturing method of a glass plate provided with the end surface processing process of processing the end surface of a glass plate into a processing tool by an end surface processing apparatus,
The end surface processing device includes a swingable arm member for supporting the processing tool, an actuator for generating a driving force for the processing tool to press the end surface of the glass plate, and a link mechanism for transmitting the driving force of the actuator to the arm member to provide
The link mechanism includes a first link member pivotable by the actuator, and a second link member pivotably connected to each of the arm member and the first link member;
In the end surface processing step, in a state in which the processing tool is in contact with the end surface of the glass plate, an angle formed by an orthogonal direction to the longitudinal direction of the first link member and the longitudinal direction of the second link member is the length of the arm member It becomes larger than the angle which the orthogonal direction of a direction and the longitudinal direction of the said 2nd link member make, The manufacturing method of the glass plate characterized by the above-mentioned.

Images