JP2019171823A - Holder unit, and scribing wheel and pin thereof - Google Patents

Abstract

To provide a holder unit capable of easily forming a scribe line along a scan direction of the holder unit, as well as to provide a scribing wheel and a pin thereof.SOLUTION: A pin 70 is a pin for supporting a scribing wheel 60, and comprises a restriction part 80 for preventing the scribing wheel 60 from moving with respect to the pin 70 in an axial direction of the pin 70.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a holder unit and its scribing wheel and pin.

  A scribe device is used to form a scribe line for a brittle material substrate such as a glass substrate. The scribing device is provided with a holder unit and a scanning device for scanning the holder unit. The holder unit includes a holder body, pins, and a scribing wheel. The holder body is attached to the scanning device. The pin is supported by the holder body. The scribing wheel is supported by the pin. Patent Document 1 discloses a scribe unit (20) which is an example of a holder unit. The scribe unit (20) includes a scribing wheel (60), a pin (32) that rotatably supports the scribing wheel (60), and a support frame (33) that supports the pin (32). A scribing line is formed on the brittle material substrate by the scribing unit 20 being scanned in a predetermined scanning direction with respect to the brittle material substrate.

JP 2012-106479 A

  In the conventional scribing apparatus, for example, when the holder unit is scanned in a linear direction, a non-linear scribe line may be formed on the brittle material substrate. In one example, the non-linear scribe line includes a straight portion along the scanning direction of the scribing wheel and a non-linear portion that has traveled in a direction different from the scanning direction. When the non-linear portion is partially formed at one or several places on the scribe line, the straight portion and the non-linear portion may be alternately formed on almost the entire scribe line. Line shapes vary. From the viewpoint of improving the quality of the broken brittle material substrate, it is preferable to form a scribe line along the scanning direction. This is the same not only when a linear scribe line is formed but also when a scribe line having a shape different from a straight line is formed.

(1) The pin of the scribing wheel according to the present invention is a pin that supports the scribing wheel, and includes a restricting portion that prevents movement of the scribing wheel relative to the pin in the axial direction of the pin.
When a reaction force acting in the axial direction of the pin during scanning of the scribing wheel is generated in the scribing wheel, this reaction force is received by the pin restricting portion. For this reason, the movement of the scribing wheel with respect to the pin in the axial direction of the pin is suppressed. Thereby, the scribe line along the scanning direction of the holder unit can be easily formed.

(2) In a preferred example, in the pin of the scribing wheel described in (1), the restricting portion includes a recess formed on the outer periphery of the pin.
For this reason, the structure of a control part is simple.

(3) In a preferred example, in the pin of the scribing wheel described in (2), the surface of the concave portion is a curved surface.
For this reason, stress concentration hardly occurs in the recess.

(4) A scribing wheel according to the present invention is a scribing wheel supported by the pin according to any one of (1) to (3), and includes a regulated portion that contacts the regulating portion.
According to the scribing wheel, the same effect as described in (1) can be obtained.

(5) In a preferred example, the scribing wheel described in (4) is a scribing wheel supported by the pin described in (2), and the regulated portion includes a convex portion inserted into the concave portion.
For this reason, the configuration of the restricted portion is simple.

(6) In a preferred example, the scribing wheel described in (5) is a scribing wheel supported by the pin described in (3), and the surface of the convex portion is a curved surface.
For this reason, stress concentration is unlikely to occur in the convex portion.

(7) A holder unit according to the present invention includes the pin according to any one of (1) to (3) and the scribing wheel according to any one of (4) to (6).
According to the holder unit, the same effect as described in (1) can be obtained.

(8) In a preferred example, the holder unit described in (7) includes the pin described in (3) and the scribing wheel described in (6), and the curvature radius of the concave portion is larger than the curvature radius of the restricted portion. Is also big.
Since the concave portion and the convex portion are in line contact, the frictional resistance during scribing is reduced.

  According to the holder unit related to the present invention, and its scribing wheel and pin, a scribe line along the scanning direction of the holder unit can be easily formed.

A perspective view of a scribing device of an embodiment. Sectional drawing of the holder unit of FIG. Sectional drawing of the holder unit of a 1st modification. Sectional drawing of the holder unit of a 2nd modification.

(Embodiment)
A scribe device 1 shown in FIG. 1 forms a scribe line on the surface of a brittle material substrate GB in order to sever a substrate made of a brittle material such as a glass substrate or a ceramic substrate (hereinafter, “brittle material substrate GB”). Used to do. An example of the brittle material substrate GB is a glass substrate. An example of the glass substrate is alkali-free glass. Alkali-free glass is used for flat panel displays and the like.

  The main elements constituting the scribe device 1 are a moving device 10, a table device 20, a holding mechanism 30, and a holder unit 40. The moving device 10 scans the brittle material substrate GB in the scanning direction. The moving device 10 includes a moving table 11 on which the table device 20 is mounted. The movable table 11 is placed on a pair of rails 12. The linear rotation conversion device 13 moves the movable table 11 along the rail 12. An example of the linear rotation conversion device 13 is a feed screw device, which includes a motor 13A serving as a drive source and a feed screw portion 13B connected to the output shaft of the motor 13A.

  The table device 20 includes a table 21 that can rotate around a rotation center axis J, and a motor 22 that rotates the table 21. The brittle material substrate GB is placed on the table 21 and is held on the table 21 by being attracted to the table 21 by vacuum suction means (not shown). The motor 22 is accommodated in the table 21. The motor 22 determines the position of the brittle material substrate GB in the rotation direction of the table 21 by rotating the table 21.

  The holding mechanism 30 holds the holder unit 40. The holding mechanism 30 includes a bridge 31 installed so as to straddle the table 21 from above, and a pair of support columns 32 that support the bridge 31. The bridge 31 is provided with a guide 31A. A scribe head 34 is movably attached to the guide 31 </ b> A via a connecting portion 33. The connecting portion 33 and the scribe head 34 move along the guide 31A. The connecting portion 33 and the scribe head 34 are connected via an elevating mechanism (not shown). When the lifting mechanism is driven, the scribe head 34 moves in the vertical direction with respect to the connecting portion 33. A holder unit 40 is detachably attached to the scribe head 34 via a holder joint 35.

  The main elements constituting the holder unit 40 shown in FIG. 2 are a holder 50, a scribing wheel 60, and a pin 70 of the scribing wheel 60 (hereinafter “pin 70”). Since the scribing wheel 60 is a consumable item, it is periodically replaced. In one example, the scribing wheel 60 is exchanged by exchanging only the scribing wheel 60 or the holder unit 40.

  An example of the material constituting the holder 50 is a magnetic metal. The holder 50 is substantially cylindrical or prismatic. The holder 50 includes a groove 51 for accommodating a part of the scribing wheel 60, and a support hole 52 that penetrates the holder 50 so as to communicate with the groove 51. The groove 51 opens toward the brittle material substrate GB in a state where the holder 50 is attached to the scribe head 34 (see FIG. 1).

  The pin 70 supports the scribing wheel 60. The pin 70 is inserted into the support hole 52. One end portion 70A of the pin 70 has a tapered shape. The relationship between the support hole 52 and the pin 70 can be arbitrarily selected. In the first example, the pin 70 is fixed to the support hole 52 so as not to rotate with respect to the support hole 52. The fixing method is press-fitting or adhesion. In the case of the first example, it is preferable that the maximum inner diameter of the support hole 52 and the maximum outer diameter of the pin 70 are substantially equal. In the second example, the pin 70 is inserted into the support hole 52 so as to be rotatable with respect to the support hole 52. In the case of the second example, the maximum inner diameter of the support hole 52 is slightly larger than the maximum outer diameter of the pin 70. Hereinafter, the direction in which the central axis of the pin 70 extends is referred to as the pin axis direction.

  Examples of the material constituting the scribing wheel 60 are sintered diamond (Poly Crystalline Diamond), cemented carbide, single crystal diamond, and polycrystalline diamond. In another example, the scribing wheel 60 may be coated with a hard material. The hard material is, for example, diamond.

  The scribing wheel 60 is mainly divided into a main body portion 61 and a blade edge portion 62. The main body 61 has a disk shape and is a portion on the inner side in the radial direction of the cutting edge portion 62 in the scribing wheel 60. The blade edge portion 62 has a V-shaped cross section and is formed over the entire outer periphery of the scribing wheel 60. The V-shaped cross section is a tapered shape toward the outer peripheral edge of the scribing wheel 60 in a cross section obtained by cutting the scribing wheel 60 along a plane along the thickness direction of the scribing wheel 60 (hereinafter referred to as “thickness direction DT”). . In the following description, a cross section orthogonal to a plane parallel to the radial direction of the scribing wheel 60 is referred to as an orthogonal cross section. In a preferred example, an example of the outer diameter of the scribing wheel 60 is included in the range of φ1 mm to φ7 mm. In one example, the outer diameter of the scribing wheel 60 is φ2 mm. An example of the thickness of the scribing wheel 60 is 0.64 mm. An example of the length of the groove 51 in the thickness direction DT, that is, the distance between the two surfaces 51A and 51B facing the thickness direction DT of the inner surface of the groove 51 is 0.66 mm. .

  An insertion hole 63 that penetrates the main body 61 in the thickness direction DT is formed at the center of the main body 61. A pin 70 is inserted into the insertion hole 63. The main body 61 includes a first side surface 61A in which one end of the insertion hole 63 is formed, and a second side surface 61B in which the other end of the insertion hole 63 is formed. A portion of the first side surface 61A accommodated in the groove 51 is opposed to the surface 51A of the groove 51 through a predetermined gap SA. A portion of the second side surface 61B accommodated in the groove 51 is opposed to the surface 51B of the groove 51 via a predetermined gap SB. The relationship between the size of the gap SA and the size of the gap SB in the thickness direction DT can be arbitrarily selected according to the position and size of a regulating portion 80 described later. In the first example shown in FIG. 2, the size of the gap SA and the size of the gap SB in the thickness direction DT are equal. In the second example, the size of the gap SA and the size of the gap SB in the thickness direction DT are different.

  The sizes of the gaps SA and SB in the thickness direction DT can be set arbitrarily. In a preferred example, the size of the gaps SA and SB in the thickness direction DT is such that the inclination of the scribing wheel 60 in the groove 51 of the holder 50 in the thickness direction DT is easily suppressed, and the gaps SA and SB It is determined based on the relationship with the difficulty of clogging foreign matter. An example of the foreign material is scraping of the brittle material substrate GB generated by forming a scribe line. An example of the maximum value of the size of the gaps SA and SB in the thickness direction DT is 10 μm. When the sizes of the gaps SA and SB are 10 μm or less, it is easy to suppress the inclination of the scribing wheel 60 in the groove 51 of the holder 50 in the thickness direction DT. An example of the minimum value of the gaps SA and SB in the thickness direction DT is 2 μm. When the size of the gaps SA and SB is 2 μm or more, the gaps SA and SB are not easily clogged with foreign matter. Furthermore, the scribing wheel 60 and the holder 50 are unlikely to interfere with each other. An example of a possible range of the total size of the gaps SA and SB in the thickness direction DT is 4 μm to 20 μm.

  In the step of forming a scribe line on the brittle material substrate GB, the holder unit 40 is scanned in a predetermined scanning direction with the scribing wheel 60 pressed against the surface of the brittle material substrate GB. Examples of the scanning method include a method of moving the holder unit 40 relative to the brittle material substrate GB, a method of moving the brittle material substrate GB relative to the holder unit 40, and a method combining these. When the brittle material substrate GB is scribed, not only the first reaction force including the component acting in the direction opposite to the scanning direction but also the second reaction force including the component in the pin axis direction acts on the scribing wheel 60. This is mainly caused by non-uniformity of the surface property of the brittle material substrate GB. The non-uniformity of the surface properties is caused by, for example, a large number of minute irregularities unevenly distributed on the surface and surface deflection. The second reaction force includes a reaction force acting in the first pin axis direction that is one of the pin axis directions and a reaction force acting in the second pin axis direction that is the other of the pin axis directions. Since the shape of the unevenness on the surface of the brittle material substrate GB is different for each part, the direction and strength of the second reaction force acting on the scribing wheel 60 change as the scribing wheel 60 advances. Since the scribing wheel 60 is not fixed to the pin 70, the scribing wheel 60 is displaced relative to the pin 70 in the pin axial direction as the second reaction force acts on the scribing wheel 60. In the following description, the movement of the scribing wheel 60 in the pin axis direction with respect to the pin 70 is referred to as “wheel axis direction displacement”.

  The direction and amount of displacement in the wheel axis direction mainly depend on the relationship between the strength of the second reaction force acting in the first pin axis direction and the strength of the second reaction force acting in the second pin axis direction. A non-linear scribe line is formed by the wheel axial displacement. By suppressing this displacement, it becomes difficult to form a non-linear scribe line. The holder unit 40 includes a displacement suppressing structure that suppresses wheel axial displacement. The displacement suppression structure includes a restriction portion 80 provided on the pin 70 and a restricted portion 90 provided on the scribing wheel 60.

  The configuration of the restriction unit 80 can be arbitrarily selected. In the example shown in FIG. 2, the restricting portion 80 includes a concave portion 81 formed on the outer periphery of the pin 70. For this reason, the structure of the control part 80 is simple. The concave portion 81 is a portion formed by polishing the outer peripheral portion of the pin 70 so as to be in contact with the regulated portion 90, and does not include minute irregularities formed at the time of manufacturing the pin 70. The recess 81 makes one round of the outer periphery of the pin 70. The position of the recess 81 in the axial direction of the pin 70 can be arbitrarily selected. In one example, the recess 81 is provided in the center of the pin 70 in the axial direction. The surface 81 </ b> A of the recess 81 is a curved surface that is recessed toward the central axis side of the pin 70 with respect to the outer peripheral surface 71 of the pin 70. For this reason, stress concentration hardly occurs in the recess 81. The surface 81A has a predetermined radius of curvature RA on the orthogonal cross section.

  The diameter of the pin 70 is included in the range of 0.4 mm to 1.1 mm. The depth XA of the recess 81 is included in the range of 0.5 μm to 3.0 μm. The depth XA of the recess 81 is indicated by, for example, the distance between the straight line LA passing through the outer peripheral surface 71 of the pin 70 and the vertex 81B of the recess 81 on the orthogonal cross section.

  The width XB of the recess 81 in the pin axis direction is equal to the thickness of the scribing wheel 60. The width XB of the recess 81 is indicated by the distance between one edge and the other edge of the recess 81 on the straight line LA passing through the outer peripheral surface 71 on the orthogonal cross section. The width of the recess 81 is equal to the thickness of the scribing wheel 60 or larger than the thickness of the scribing wheel 60. The width of the recess 81 is included in the range of 0.4 mm to 1.2 mm.

  The regulated portion 90 includes a convex portion 91 that is inserted into the concave portion 81. For this reason, the configuration of the regulated portion 90 is simple. The surface 91A of the convex portion 91 is a curved surface formed between the first side surface 61A and the second side surface 61B in the thickness direction DT and defined by a predetermined radius of curvature RB. For this reason, stress concentration is unlikely to occur in the convex portion 91. The relationship between the curvature radius RA of the concave portion 81 and the curvature radius RB of the convex portion 91 can be arbitrarily selected. In the first example shown in FIG. 2, the radius of curvature RA of the concave portion 81 is larger than the radius of curvature RB of the convex portion 91. In the case of the first example, since the surface 81A of the concave portion 81 and the surface 91A of the convex portion 91 are in line contact, the frictional resistance during scribing is reduced. In the second example, the curvature radius RA of the concave portion 81 is equal to or smaller than the curvature radius RB of the convex portion 91. The height HA of the convex portion 91 is included in the range of 0.1 μm to 1.0 μm. The height HA of the convex portion 91 is preferably included in the range of 0.1 μm to 0.5 μm. The height HA of the convex portion 91 is indicated by the distance between the straight line LB passing through the boundary between the side surfaces 61A and 61B of the main body portion 61 and the surface 91A and the vertex 91B of the convex portion 91. The minimum inner diameter of the convex portion 91 of the insertion hole 63 of the scribing wheel 60 is slightly larger than the maximum outer diameter of the pin 70.

  The operation and effect of the holder unit 40 will be described. In a state where the scribing wheel 60 is pressed against the brittle material substrate GB and is not scanned, the vertex 91B of the regulated portion 90 of the scribing wheel 60 contacts the regulating portion 80 of the pin 70 on the orthogonal cross section. Actually, a certain range of the regulated portion 90 is in line contact with the regulating portion 80. The regulated portion 90 receives a reaction force acting in the pressing direction from the regulating portion 80. When the second reaction force is applied to the scribing wheel 60 as the scribing wheel 60 is scanned, the second reaction force for moving the regulated portion 90 in the pin axis direction is received by the regulating portion 80 of the pin 70. For this reason, the wheel axis direction displacement of the scribing wheel 60 is prevented, the scribing wheel 60 advances along the scanning direction, and a linear scribe line is formed on the brittle material substrate GB. For this reason, a scribe line along the scanning direction of the holder unit 40 can be easily formed.

(Modification)
The said embodiment is an illustration of the form which the holder unit regarding this invention, its scribing wheel, and a pin can take, and is not intending restrict | limiting the form. The holder unit according to the present invention, and its scribing wheel and pin may take a form different from that illustrated in the embodiment. For example, a part of the configuration of the embodiment is replaced, changed, or omitted, or a new configuration is added to the embodiment. Below, an example of the modification of embodiment is shown.

  -The structure of the control part 80 and the to-be-controlled part 90 can be changed arbitrarily. FIG. 3 shows a configuration of the holder unit 40 including the restricting portion 180 and the restricted portion 190 of the first modification. The restricting portion 180 includes a convex portion 181 formed on the outer periphery of the pin 70. The convex portion 181 is a portion that protrudes from the outer peripheral surface 71 of the pin 70 so that it can come into contact with the regulated portion 190. The convex portion 181 is provided over the entire position of the outer peripheral surface 71 of the pin 70 facing the insertion hole 63 of the scribing wheel 60. The position where the convex portion 181 in the axial direction of the pin 70 can be arbitrarily selected. In one example, the convex portion 181 is provided at the center of the groove portion 51 in the axial direction. A surface 181A of the convex portion 181 is a curved surface defined by a predetermined radius of curvature RA. The regulated portion 190 includes a concave portion 191 into which the convex portion 181 is inserted. The concave portion 191 is a portion formed by polishing the insertion hole 63, for example, and does not include minute irregularities formed when the scribing wheel 60 is manufactured. The surface 191A of the recess 191 is a curved surface that is formed between the first side surface 61A and the second side surface 61B in the thickness direction DT and is defined by a predetermined radius of curvature RB. In the first modified example, the holder 50 is not formed by an integral member, but the holder unit 40 can be easily formed by dividing the groove 51 into a portion including the surface 51A and a portion including the surface 51B. Can be assembled into.

  The relationship between the curvature radius RA of the surface 181A and the curvature radius RB of the surface 191A can be arbitrarily selected. In the first example shown in FIG. 3, the curvature radius RA of the surface 181A is smaller than the curvature radius RB of the surface 191A. In the case of the first example, since the surface 181A and the surface 191A are in line contact, the frictional resistance during scribing is reduced. In the second example, the radius of curvature RA of the surface 181A is equal to or larger than the radius of curvature RB of the surface 191A.

  FIG. 4 shows a configuration of the holder unit 40 including the restricting portion 280 and the restricted portion 290 of the second modification. The restricting portion 280 includes a recess 281 formed on the outer peripheral surface 71 of the pin 70. The concave portion 281 is a portion formed by, for example, polishing the outer peripheral surface 71 of the pin 70 so as to be in contact with the regulated portion 290, and does not include minute concave and convex portions formed at the time of manufacturing the pin 70. The recess 281 is provided over the entire position of the outer peripheral surface 71 of the pin 70 facing the insertion hole 63 of the scribing wheel 60. The position where the concave portion 281 in the axial direction of the pin 70 can be arbitrarily selected. In one example, the recess 281 is provided at the center of the pin 70 in the axial direction. The recess 281 is a groove including a corner. In the example shown in FIG. 4, the recess 281 is a V-shaped groove. The regulated portion 290 includes a convex portion 291 that is inserted into the concave portion 281. The convex portion 291 is formed between the first side surface 61A and the second side surface 61B in the thickness direction DT. The convex portion 291 is a projection including a corner. In the example shown in FIG. 4, the convex portion 291 is a V-shaped projection. The minimum inner diameter of the convex portion 291 of the insertion hole 63 of the scribing wheel 60 is slightly larger than the maximum outer diameter of the pin 70.

  -The structure of the holder unit 40 can be changed arbitrarily. In one example, the restricted portion 90 is omitted from the holder unit 40. In this case, the width of the restriction portion 80 is preferably larger than the width of the scribing wheel 60 and narrower than the width of the groove portion 51. Further, the shapes of the restricting portion 80 and the restricted portion 90 are not limited to the configurations disclosed in the above embodiment, and may be, for example, a shape having a flat portion in part. Moreover, the shape of the convex part 91 and the shape of the concave part 81 do not need to correspond. In this case, it is preferable that the width of the concave portion 81 is larger than the width of the convex portion 91.

1: Scribing device 40: Holder unit 60: Scribing wheel 70: Pin 80: Restricting part 81: Concave part 90: Restricted part 91: Convex part

Claims (8)

A pin that supports the scribing wheel,
A pin for a scribing wheel, comprising a restricting portion that prevents movement of the scribing wheel relative to the pin in the axial direction of the pin. The scribing wheel pin according to claim 1, wherein the restricting portion includes a recess formed on an outer periphery of the pin. The pin of the scribing wheel according to claim 2, wherein the surface of the recess is a curved surface. A scribing wheel supported by the pin according to any one of claims 1 to 3,
A scribing wheel comprising a regulated portion that contacts the regulating portion. A scribing wheel supported by the pin according to claim 2,
The scribing wheel according to claim 4, wherein the regulated portion includes a convex portion that is inserted into the concave portion. A scribing wheel supported by the pin according to claim 3,
The scribing wheel according to claim 5, wherein a surface of the convex portion is a curved surface. The pin according to any one of claims 1 to 3,
A holder unit comprising the scribing wheel according to any one of claims 4 to 6. A pin according to claim 3;
A scribing wheel according to claim 6,
The holder unit according to claim 7, wherein a curvature radius of the concave portion is larger than a curvature radius of the restricted portion.