JP2016108203A - Substrate dividing method and scribing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a substrate dividing method capable of smoothly dividing a mother substrate at a position of a sealant in a small number of steps, and a scribing apparatus used for the same.SOLUTION: A method for dividing a mother substrate G comprises the steps of: moving a scribing wheel 301 along a sealant SL while pressing the scribing wheel 301 at a position facing the sealant SL on the surface of a glass substrate G1 to form a scribe line L1 on the surface of the glass substrate G1; forming a trigger crack TC at a position corresponding to a formation position of the scribe line L1 on the side surface of at least a glass substrate G2; and pressing the surface of the glass substrate G2 by a break bar BB to apply a stress in a direction of opening the scribe line L1 to the mother substrate G and divide the mother substrate G along the trigger crack TC.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a substrate cutting method for cutting a bonded substrate by forming a scribe line and a scribe device used therefor.

  Conventionally, a brittle material substrate such as a glass substrate is divided by a scribe process for forming a scribe line on the substrate surface and a break process for applying a predetermined force to the substrate surface along the formed scribe line. In the scribing step, the cutting edge of the scribing wheel is moved along a predetermined line while being pressed against the substrate surface. A scribe device equipped with a scribe head is used to form the scribe line.

  Patent Document 1 below describes a method for cutting out a liquid crystal panel from a mother substrate. In this method, a mother substrate is formed by bonding a substrate on which a thin film transistor (TFT) is formed and a substrate on which a color filter (CF) is formed through a sealing material. Individual liquid crystal panels are obtained by dividing the mother substrate. The sealing material is arranged so that a space serving as a liquid crystal injection region remains in a state where the two substrates are bonded to each other.

  When the mother substrate having the above configuration is divided, scribe lines are formed on both surfaces of the mother substrate (see, for example, Patent Document 2). In this case, a scribe line is formed on one surface of the mother substrate, and then the mother substrate is turned upside down to form a scribe line on the other surface of the mother substrate. After forming a scribe line on each surface of the mother substrate in this way, pressing one surface of the mother substrate, breaking the bonded one substrate along the scribe line, then turning the mother substrate upside down, By the same process, the other bonded substrate is broken along the scribe line.

JP 2006-137441 A JP 2003-131185 A

  As shown in the above-mentioned Patent Document 1, a conventional mother substrate has a region where no sealing material is interposed between adjacent liquid crystal injection regions. Therefore, when the scribe lines are formed on both sides of the mother substrate as described above, the scribe lines are formed in a region where no sealant is interposed. When the scribe line is formed in this way and the mother substrate is divided, a frame region having a predetermined width remains around the liquid crystal injection region in the liquid crystal panel.

  However, in recent years, particularly in mobile liquid crystal panels, it has become mainstream to narrow the frame area to the limit. In order to meet this requirement, it is necessary to omit the region where the sealing material is not interposed in the mother substrate, and to configure the adjacent liquid crystal injection regions to be separated only by the sealing material. In this case, the scribe line is formed along the sealing material.

  Thus, also when forming a scribe line along a sealing material, as described above, a method of forming a scribe line individually for each surface and then breaking each surface individually can be used. . However, when this method is used, the number of steps for dividing the mother substrate is increased, and it is difficult to shorten the time required for dividing the mother substrate.

  In view of such problems, an object of the present invention is to provide a substrate cutting method and a scribing device used therefor that can smoothly cut a mother substrate at the position of a sealing material with a small number of steps.

  A first aspect of the present invention relates to a substrate cutting method for cutting a mother substrate formed by bonding a first substrate and a second substrate with a sealing material. In the substrate cutting method according to this aspect, the blade is moved along the sealing material while pressing the blade to a position facing the sealing material on the surface of the first substrate to scribe the surface of the first substrate. A step of forming a line, a step of forming a crack at a position corresponding to a formation position of the scribe line at least on a side surface of the second substrate, and applying a stress in a direction to open the scribe line to the mother substrate. And cutting the mother substrate along the crack.

  According to the substrate cutting method according to the present aspect, the stress in the direction of opening the scribe line formed on the first substrate is applied to the mother substrate, so that the first is based on the crack formed on the side surface of the second substrate. The second substrate together with the substrate is broken along the scribe line. Therefore, when forming the scribe line, the step of inverting the mother substrate to form the scribe line on the surface of the second substrate can be omitted, and the mother substrate is inverted during the break to break the second substrate. The process can be omitted. Therefore, according to the board | substrate cutting method which concerns on this aspect, a mother board | substrate can be cut off smoothly with few processes.

  In the substrate cutting method according to this aspect, it is preferable to perform the step of forming the crack after performing the step of forming the scribe line. If a crack has already been formed on the side surface of the second substrate when the scribe line is formed, there is a concern that an undesired crack may occur in the second substrate starting from the crack due to the load at the time of forming the scribe line. On the other hand, if the crack is formed after the formation of the scribe line, such a problem is avoided. Therefore, it is desirable to perform the process of forming a crack after performing the process of forming a scribe line.

  In the step of dividing the mother substrate, the surface of the second substrate corresponding to the position where the scribe line is formed is pressed to apply stress in the direction of opening the scribe line to the mother substrate. Is desirable. In this way, the surface of the second substrate is pressed at a position corresponding to the scribe line, and the scribe line is not formed because stress is applied to the both sides of the mother substrate substantially uniformly around the scribe line to open the scribe line. The second substrate can be broken more smoothly.

  In the step of forming the crack, a crack may be formed at a position corresponding to the scribe line on the side surface of the first substrate. If it carries out like this, formation of the crack with respect to the side surface of a 1st board | substrate can be made into introduction operation | movement, and a crack can be smoothly formed in the side surface of a 2nd board | substrate.

  The cracks formed on the side surface of the second substrate are preferably formed on the side surface of the second substrate over the entire length in the thickness direction of the second substrate. Thus, by taking a long crack as a starting point when breaking the second substrate, it is possible to break the second substrate more appropriately.

  A second aspect of the present invention relates to a scribing apparatus that forms a scribe line on a mother substrate formed by bonding a first substrate and a second substrate with a sealing material. In the scribing apparatus according to this aspect, the blade is moved along the sealing material while pressing the blade to a position facing the sealing material on the surface of the first substrate, and a scribe line is formed on the surface of the first substrate. Scribe line forming means for forming a crack, and crack forming means for forming a crack at a position corresponding to a position where the scribe line is formed on at least the side surface of the second substrate.

  By using the scribing apparatus according to this aspect, the scribe lines and cracks in the substrate cutting method according to the first aspect can be formed in the mother substrate. Therefore, the effects described in the first aspect can be achieved.

  A third aspect of the present invention relates to a scribing apparatus that forms a scribe line on a mother substrate formed by bonding a first substrate and a second substrate with a sealing material. The scribing apparatus according to this aspect includes a first head for forming a scribe line on the surface of the first substrate, a second head for forming a crack on at least a side surface of the second substrate, and the first head as the sealing material. And a second driving unit that moves the second head in a direction perpendicular to the upper surface of the mother substrate. Here, the blade is moved along the sealing material while the first head is pressed against a position of the surface of the first substrate facing the sealing material, and the second head includes at least the second head. The blade is moved in a direction perpendicular to the upper surface of the mother substrate while the blade is pressed to a position corresponding to the formation position of the scribe line on the side surface of the second substrate.

  By using the scribing apparatus according to this aspect, the scribe lines and cracks in the substrate cutting method according to the first aspect can be formed in the mother substrate. Therefore, the effects described in the first aspect can be achieved.

  The scribing apparatus according to a third aspect includes a first conveyor on which the mother substrate is placed when the scribe line is formed on the surface of the first substrate and the mother substrate can be transferred to the downstream side, And a second conveyor provided on the downstream side of the first conveyor on which the mother substrate transferred by the first conveyor is placed. In this configuration, in the second conveyor, the width of the second conveyor is the first conveyor in the direction perpendicular to the transfer direction of the mother board so that at least one end of the mother board protrudes from the second conveyor. The width of the second head may be set to be smaller than the width of the conveyor, and the second head may be configured to move in a direction perpendicular to the mother board on the end side of the mother board that protrudes from the second conveyor. If it carries out like this, a crack can be smoothly formed by the 2nd head.

  As described above, according to the present invention, it is possible to provide a substrate cutting method and a scribing device used therefor that can cut a mother substrate smoothly at the position of the sealing material with a small number of steps.

  The effects and significance of the present invention will become more apparent from the following description of embodiments. However, the embodiment described below is merely an example when the present invention is implemented, and the present invention is not limited to what is described in the following embodiment.

It is a figure which shows typically the structure of the scribing apparatus which concerns on embodiment. It is a disassembled perspective view which shows the structure of the scribe head which concerns on embodiment. It is a perspective view which shows the structure of the scribe head which concerns on embodiment. It is the block diagram which shows the structure of the scribing apparatus which concerns on embodiment, and the flowchart which shows the division process of a mother board | substrate. It is a figure explaining the cutting process of the board | substrate cutting method which concerns on embodiment. It is a figure which shows the experimental result by the board | substrate cutting method which concerns on embodiment. It is a figure which shows typically the effect | action in the scribe process which concerns on embodiment. It is a figure which shows the formation method and break method of the trigger crack which concern on the example of a change.

  Embodiments of the present invention will be described below with reference to the drawings. In each figure, an X axis, a Y axis, and a Z axis that are orthogonal to each other are added for convenience. The XY plane is parallel to the horizontal plane, and the Z-axis direction is the vertical direction.

<Configuration of scribing device>
FIGS. 1A, 1 </ b> B, and 1 </ b> C are diagrams schematically illustrating a configuration of the scribe device 1. 1A is a view of the scribe device 1 viewed from the Y axis positive side, FIG. 1B is a view of a part of the scribe device 1 viewed from the X axis positive side, and FIG. It is the figure which looked at a part of scribing device 1 from the Z-axis positive side.

  1A and 1B, the scribing apparatus 1 includes a first conveyor 11a, a second conveyor 11b, struts 12a and 12b, a guide 13, a sliding unit 14, and a drive motor 15. A guide 16, a sliding unit 17, a drive motor 18, cameras 19a and 19b, and two scribe heads 2.

  As shown in FIG.1 (b), the mother board | substrate G is mounted on the 1st conveyor 11a. The mother substrate G has a substrate structure in which a pair of glass substrates are bonded to each other. Mother board | substrate G is sent to the Y-axis negative direction by the 1st conveyor 11a, and is delivered to the 2nd conveyor 11b. As shown in FIG. 1C, the width of the second conveyor 11b in the X-axis direction is smaller than the width of the first conveyor 11a in the X-axis direction. That is, as for the 2nd conveyor 11b, the edge part of the X-axis positive side has retracted | retreated in the X-axis negative direction with respect to the 1st conveyor 11a. For this reason, as for the mother board | substrate G delivered to the 2nd conveyor 11b, the edge part of the X-axis positive direction protrudes slightly from the 2nd conveyor 11b.

  Referring to FIG. 1A, support columns 12 a and 12 b are provided vertically on the base of the scribe device 1 with the first conveyor 11 a interposed therebetween. The guide 13 is installed between the columns 12a and 12b so as to be parallel to the X-axis direction. The sliding unit 14 is slidably provided on the guide 13. The guide 13 is provided with a drive motor 15, and the drive motor 15 drives the sliding unit 14 in the X-axis direction.

  The scribe head 2 is attached to the sliding unit 14. A scribing tool is attached to the scribe head 2 so as to face the upper surface of the mother substrate G. The scribing head 2 moves in the X-axis direction in a state where the scribing wheel held by the scribing tool is pressed against the surface of the mother substrate G. Thereby, a scribe line is formed on the surface of the mother substrate G.

  Referring to FIG. 1B, a guide 16 is provided on the X axis positive side of the second conveyor 11b. The guide 16 is fixed to a support frame (not shown) of the scribe device 1 so as to be parallel to the Z axis. The sliding unit 17 is slidably provided on the guide 16. The guide 16 is provided with a drive motor 18, and the drive motor 18 drives the sliding unit 17 in the X-axis direction.

  The scribe head 2 is attached to the sliding unit 17. A scribing tool is attached to the scribe head 2 so as to face the side surface of the mother substrate G on the X axis positive side when the scribe head 2 is at the same height as the mother substrate G. The scribing head 2 moves in the Z-axis direction while the scribing wheel held by the scribing tool is pressed against the side surface of the mother substrate G. Thereby, a trigger crack TC (see FIG. 5) described later is formed on the side surface of the mother substrate G. As described with reference to FIG. 1C, the side surface on the positive side of the X axis of the mother substrate G slightly protrudes from the second conveyor 11b as described above so that the trigger crack TC can be formed in this way. .

  The cameras 19a and 19b are arranged above the guide 13 and detect alignment marks written on the mother board G. Based on the captured images from the cameras 19a and 19b, the arrangement position of the mother board G with respect to the first conveyor 11a is detected. Similarly, two cameras (not shown) are also arranged above the second conveyor 11b. The arrangement position of the mother board | substrate G with respect to the 2nd conveyor 11b is detected by the captured image from these cameras. Based on these detection results, the formation position of the scribe line and the formation position of the trigger crack are determined.

<Scribe head>
FIG. 2 is a partially exploded perspective view showing the configuration of the scribe head 2, and FIG. 3 is a perspective view showing the configuration of the scribe head 2.

  Referring to FIG. 2, the scribe head 2 includes an elevating mechanism 21, a scribe line forming mechanism 22, a base plate 23, a top plate 24, a bottom plate 25, a rubber frame 26, a cover 27, and a servo motor 28. With.

  The elevating mechanism 21 includes a cylindrical cam 21a connected to the drive shaft of the servo motor 28, and a cam follower 21c formed on the upper surface of the elevating part 21b. The elevating part 21b is supported by the base plate 23 so as to be movable in the vertical direction via a slider (not shown), and is urged in the positive direction of the Z axis by a spring 21d. The cam follower 21c is pressed against the lower surface of the cylindrical cam 21a by the bias of the spring 21d. The elevating part 21 b is connected to the scribe line forming mechanism 22. When the cylindrical cam 21a is rotated by the servo motor 28, the elevating part 21b is raised and lowered by the cam action of the cylindrical cam 21a, and accordingly, the scribe line forming mechanism 22 is raised and lowered. The scribing tools 30 and 40 are attached to the lower end of the scribe line forming mechanism 22.

  The scribing tool 30 is for forming a scribe line on the upper surface of the mother substrate G, and the scribing tool 40 is for forming a trigger crack on the side surface of the mother substrate G. A scribing tool 30 is attached to the scribe head 2 attached to the sliding unit 14 in FIG. 1A, and a scribing tool 30 is attached to the scribe head 2 attached to the sliding unit 17. Each of the scribing tools 30 and 40 rotatably holds a scribing wheel for forming a scribe line and a trigger crack.

  The rubber frame 26 is an elastic member that does not allow air to pass therethrough. The rubber frame 26 has a shape that fits into the groove 23 a of the base plate 23, the groove 24 a of the top plate 24, and the groove 25 a of the bottom plate 25. In a state where the rubber frame 26 is mounted in the grooves 23 a, 24 a, and 25 a, the surface of the rubber frame 26 protrudes slightly outward from the side surfaces of the base plate 23, the top plate 24, and the bottom plate 25.

  The cover 27 has a shape in which three plate portions of the front surface portion 27a, the right side surface portion 27b, and the left side surface portion 27c are bent. Two holes 27f are formed in the upper and lower edges of the front surface portion 27a.

  In a state where the rubber frame 26 is fitted in the grooves 23 a, 24 a, 25 a, the right side surface portion 27 b and the left side surface portion 27 c of the cover 27 are deformed so as to bend outward, and the cover 27 is transformed into the base plate 23, the top plate 24 and the bottom plate 25. It is attached. In this state, screws are screwed to the top plate 24 and the bottom plate 25 through two holes 27f formed at the upper and lower end edges of the front surface portion 27a. Further, screws are screwed into screw holes formed slightly outside the grooves 23a, 24a, and 25a of the base plate 23, the top plate 24, and the bottom plate 25. Thus, the cover 27 is sandwiched between the base plate 23, the top plate 24, the bottom plate 25, and the screw heads, and the peripheral portions of the right side surface portion 27b and the left side surface portion 27c are pressed against the rubber frame 26. In this way, the scribe head 2 is assembled as shown in FIG.

<Block configuration>
FIG. 4A is a block diagram showing a configuration of the scribe device 1.

  The scribing apparatus 1 includes a control unit 101, a detection unit 102, a drive unit 103, an input unit 104, and a display unit 105.

  The control unit 101 includes a processor such as a CPU and a memory such as a ROM and a RAM, and controls each unit according to a control program stored in the memory. The memory is also used as a work area when controlling each unit. The detection unit 102 includes various sensors in addition to the cameras 19a and 19b shown in FIG. The drive unit 103 includes the mechanism unit of the scribe device 1 and the drive motors 15 and 18 shown in FIGS. The input unit 104 includes a mouse and a keyboard. The input unit 104 is used to input various parameter values in the scribe operation such as the scribe line formation position and the scribe line interval. The display unit 105 includes a monitor, and a predetermined input screen is displayed upon input by the input unit 104.

<Substrate cutting method>
FIG. 4B is a flowchart showing a flow of dividing the mother substrate G.

  The mother substrate G is divided by a scribe line forming step (S11), a trigger crack forming step (S12), and a mother substrate G breaking step (S13). In S11, a scribe line is formed on the surface of the mother substrate G along the sealing material. In S12, a trigger crack is formed at a position corresponding to the formation position of the scribe line on the side surface of the mother substrate G. In S13, the position corresponding to the scribe line on the back surface of the mother substrate G is pressed by the break bar, and the mother substrate G is broken.

  FIGS. 5A to 5E are diagrams for explaining the process of dividing the mother substrate G. FIG. 5A is a schematic diagram when the vicinity of the scribe position is viewed from the Y axis negative side, FIG. 5B is a schematic diagram when the vicinity of the scribe position is viewed from the X axis positive side, and FIG. FIG. 5D is a schematic view when the vicinity of the scribe position is seen from the Z-axis positive side, FIG. 5D is a schematic view when the vicinity of the formation position of the trigger crack TC is seen from the X-axis positive side, and FIG. FIG. 6 is a schematic diagram when the mother substrate G is viewed from the X axis positive side.

  5A to 5C show a scribe line forming process, FIG. 5D shows a trigger crack forming process, and FIG. 5E shows a mother substrate G breaking process. Yes. 5A to 5D are performed by the scribing apparatus 1, and FIG. 5E is performed by an apparatus that performs a breaking process. Since the break process in FIG. 5E is performed using an existing apparatus, a detailed description of the configuration of the apparatus that performs the break process is omitted here.

  5A to 5D, the scribing wheel 301 is held by the scribing tool 30 of the scribe head 2 driven by the sliding unit 14 of FIG. 1A, and the scribing wheel 401 is shown in FIG. ) Of the scribing head 2 driven by the sliding unit 17. The scribing wheel 301 is used for forming the scribe line L1 on the upper surface of the mother substrate G, and the scribing wheel 401 is used for forming the trigger crack TC on the side surface of the mother substrate G.

  As shown in FIG. 5A, in the scribe line formation step, the scribe line L1 is formed by moving the scribe wheel 301 in the positive X-axis direction while pressing the scribe wheel 301 against the surface of the mother substrate G.

  Referring to FIG. 5B, the mother substrate G is configured by bonding two glass substrates G1 and G2 through a sealing material SL. A color filter (CF) is formed on the glass substrate G1, and a thin film transistor (TFT) is formed on the glass substrate G2. A liquid crystal injection region R is formed by the sealing material SL and the two glass substrates G1 and G2, and liquid crystal is injected into the liquid crystal injection region R.

  The sealing material SL is an adhesive made of a resin material such as an epoxy resin. For example, when the sealing material SL is made of an ultraviolet curable resin, the glass substrate G1 is overlaid on the upper surface of the glass substrate G2 in a state where the sealing material SL is applied to the surface of the glass substrate G2, and then ultraviolet rays are irradiated. Thereby, sealing material SL hardens | cures and glass substrate G1, G2 is bonded together through sealing material SL. In addition, the sealing material SL may be made of a thermosetting resin. In this case, the sealing material SL is cured by heating, and the glass substrates G1 and G2 are bonded together via the sealing material SL. When the sealing material SL is cured, it has a high hardness.

  As shown in FIG. 5B, the scribing wheel 301 is pressed against the surface of the glass substrate G1 at a position immediately above the sealing material SL. As shown in FIG.5 (c), the sealing material SL is arrange | positioned at the grid | lattice form. The scribing wheel 301 is moved in the positive direction of the X axis along the sealing material SL in a state where the scribing wheel 301 is pressed to a position immediately above the sealing material SL. Thereby, as shown in FIGS. 5B and 5C, a scribe line L1 is formed on the surface of the glass substrate G1.

  As described above, the sealing material SL has high hardness when cured. For this reason, the load applied to the glass substrate G1 from the scribing wheel 301 during the scribing operation is also applied to the glass substrate G2 via the sealing material SL. Due to this load, stress concentration occurs along the sealing material SL on the upper surface (the surface on the Z-axis positive side) of the glass substrate G2. Due to this stress concentration, the upper surface (the surface on the Z-axis positive side) of the glass substrate G2 is compressed along the sealing material SL.

  After the scribe line L1 is thus formed, a trigger crack TC is formed on the side surface of the mother substrate G on the X axis positive side, as shown in FIG. The trigger crack TC is formed at a position corresponding to the scribe line L1 in parallel with the Z-axis direction. The trigger crack TC is obtained by moving the scribing wheel 401 in the Z-axis negative direction from the upper end of the side surface on the X-axis positive side of the glass substrate G1 to the lower end of the side surface on the X-axis positive side of the glass substrate G2. It is formed on the side surface of the mother substrate G over the entire length in the direction. At this time, the scribing wheel 401 is pressed against the side surfaces of the glass substrates G1 and G2 with a predetermined load.

  As described above, the position control of the scribing wheels 301 and 401 with respect to the mother board G is performed by aligning the alignment marks on the upper surface of the mother board G with the cameras 19a and 19b arranged above the first conveyor 11a and the first conveyor 11a. This is performed by taking an image with a camera (not shown) arranged above the. That is, the control unit 101 in FIG. 4A detects the position of the mother board G on the first conveyor 11a and the second conveyor 11b based on the captured image of the alignment mark. And based on this detection result, the control part 101 controls the 1st conveyor 11a and the 2nd conveyor 11b so that the scribing wheel 301,401 is located in the position corresponding to the sealing material SL of the mother board | substrate G. FIG.

  Thus, after the trigger cracks TC are formed at positions corresponding to all the scribe lines L1, the mother substrate G is removed from the scribe device 1. And the mother board | substrate G is set to the apparatus which performs a breaking process in the state reversed front and back.

  As shown in FIG. 5E, in the breaking step, the surface of the glass substrate G2 corresponding to the position where the scribe line L1 is formed is pressed by the break bar BB. Thereby, the stress of the direction which opens the scribe line L1 is provided to the mother board | substrate G, and the glass substrate G1 is broken along the scribe line L1. At this time, the stress in the opening direction applied by the break bar BB is also applied to the glass substrate G2. Thereby, the glass substrate G2 is broken together with the glass substrate G1, starting from the trigger crack TC formed on the side surface of the glass substrate G2. Thus, the mother substrate G is divided along the scribe line L1.

<Experiment>
The inventors of the present application conducted an experiment to cut the mother substrate G according to the substrate cutting method shown in FIGS. Hereinafter, the experiment and the experimental result will be described.

  In the experiment, a substrate (mother substrate) in which glass substrates G1 and G2 each having a thickness of 0.2 mm were bonded together with a sealing material SL was used. The size of the bonded substrate (mother substrate G) is 110 mm × 550 mm. A scribe line L1 was formed on the upper surface of the mother substrate G in parallel with the short side direction, and a trigger crack TC was formed on one side surface to perform a breaking process. For the scribing wheels 301 and 401, a micro penet (registered trademark of Samsung Diamond Industrial Co., Ltd.) manufactured by Samsung Diamond Industrial Co., Ltd. was used. Each of the scribing wheels 301 and 401 has a structure in which a V-shaped cutting edge is formed on the outer periphery of the disk and grooves are formed at predetermined intervals on the ridge line of the cutting edge. The diameters of the scribing wheels 301 and 401 were both 3 mm.

  As shown in FIGS. 5A to 5C, the scribing wheel 301 having this configuration was moved while being pressed against the glass substrate G1 to perform a scribing operation. The load applied to the scribing wheel 301 during the scribing operation was controlled to 30N. Further, the trigger crack TC was formed from the upper end to the lower end of the side surface of the mother substrate G by the scribing wheel 401.

  In the experiment, the breaking process was performed by applying stress by hand in the direction of opening the scribe line L1. That is, the mother substrate G was broken by applying stress with both hands in the direction of opening the scribe line L1 while pressing a finger at a position corresponding to the scribe line L1 on the surface opposite to the surface on which the scribe line L1 was formed. . Further, the scribe line L1 does not reach the edge portion on the upper surface of the glass substrate G1, and the scribe line L1 is set such that a position away from the edge portion on the upper surface of the glass substrate G1 by a predetermined distance becomes the start point and the end point of the scribe line L1. Formed.

  An experimental result is shown to Fig.6 (a)-(c). 6A to 6C are cross-sectional photographs of the mother substrate G on the scribe line L1. 6A is a cross-sectional photograph of the vicinity of the right end (X-axis negative side) of the mother substrate G, FIG. 6B is a cross-sectional photograph of the center of the mother substrate G, and FIG. 6C is a mother. 6 is a cross-sectional photograph of the vicinity of the left end (X-axis positive side) of the substrate G.

  In FIG. 6B, D1 and D2 are the thicknesses of the glass substrates G1 and G2, respectively, D3 is the rib mark amount, and D4 is the crack penetration amount in the scribe line L1. In FIG. 6C, D5 is the penetration amount of the trigger crack TC, and D6 is the distance between the trigger crack TC and the end point of the scribe line L1. 6A to 6C, the white area is an area that coincides with the vertical plane including the center line of the scribe line L1, and the black area is an area that is deviated from the vertical plane.

  Referring to FIGS. 6A to 6C, it can be seen that the glass substrate G2 on which the scribe line L1 is not formed is generally cut along a vertical plane including the center line of the scribe line L1. In addition, in the glass substrate G2, the deviation | shift amount from the vertical surface in the black area | region of a cross-sectional photograph was settled in the range to 0-30 micrometers, and a big soge and shift | offset | difference did not arise in the cut surface. Therefore, a liquid crystal panel that can sufficiently withstand practical use can be cut out even by the substrate cutting method shown in FIGS. In addition, it is thought that the deviation | shift amount with respect to a vertical surface can further be suppressed by adjusting the formation method of the trigger crack TC and the application | coating method of the stress in a breaking process.

  6A to 6C, the progress of cracks stops in the middle of the upper glass substrate G1, and the crack does not progress to the lower glass substrate G2. However, referring to the cross-sectional photographs in FIGS. 6 (a) to 6 (c) in detail, it was found that a stepped ridge of about several microns occurred near the top of the cross section of the lower glass substrate G2. This sag is considered to be caused by the load applied by the scribing wheel 301 being applied to the upper surface of the glass substrate G2 through the sealing material SL during the scribing operation on the glass substrate G1.

  FIG. 7 is a diagram schematically showing an action in a scribe process that can be considered by the above-described experiment.

  In the scribe line forming step, when the scribing wheel 301 is moved while pressing the scribing wheel 301 against the upper surface of the glass substrate G1, the scribe line L1 is formed on the upper surface of the glass substrate G1 as described above. At this time, the scribing wheel 301 moves to a position immediately above the sealing material SL while being pressed against the upper surface of the glass substrate G1 with a predetermined load F0. Here, since the sealing material SL has high hardness, the load F0 of the scribing wheel 301 is applied to the upper surface of the glass substrate G2 through the sealing material SL. When this load is Fa, the load Fa is continuously applied to the upper surface of the glass substrate G2 along the seal material SL as the scribing wheel 301 moves. Thus, a stress concentration line LS due to the load Fa is set on the upper surface of the glass substrate G2. In the vicinity of the upper surface of the glass substrate G2, it is considered that the inner surface is bent as described above due to the pressure of the load Fa at the position of the line LS. Therefore, further, the trigger crack TC is formed at a position corresponding to the scribe line L1 on the side surface of the glass substrate G2, and the glass substrate G1 is applied to the scribe line L1 by applying stress in the direction of opening the scribe line L1 in the breaking process. The glass substrate G2 is broken with the line LS as a starting point together with the trigger crack TC. Thereby, it is considered that the glass substrate G2 was smoothly broken as in the above experiment.

  Although the load F0 of the scribing wheel 301 was 30N in the above experiment, the inventors of the present application conducted further experiments on the scribe line (crack on the surface of the upper glass substrate G1 whether the load F0 was 20N or 10N. It is confirmed that the mother substrate G can be divided along the scribe line L1 by the above dividing method. From this, by applying a load to the scribing wheel 301 to such an extent that a scribe line (crack) can be formed on the surface of the upper glass substrate G1, crease occurs near the upper surface of the glass substrate G2 via the sealing material SL. The mother substrate G can be smoothly divided by the above dividing method.

<Effect of embodiment>
According to the present embodiment, the following effects are exhibited.

  By applying stress in the direction of opening the scribe line L1 formed on the glass substrate G1 to the mother substrate G, the glass substrate G2 breaks together with the glass substrate G1, starting from the trigger crack TC formed on the side surface of the glass substrate G2. Is done. Accordingly, the step of forming the scribe line on the surface of the glass substrate G2 by inverting the mother substrate G in the scribe line forming step can be omitted, and the glass substrate G2 can be broken by inverting the mother substrate G in the breaking step. The process to perform can be omitted. Therefore, according to the present embodiment, the mother substrate G can be divided along the sealing material SL smoothly with fewer steps.

  In the present embodiment, the trigger crack TC is formed after the scribe line L1 is formed on the upper surface of the glass substrate G1. On the other hand, the trigger crack TC can be formed first, and then the scribe line L1 can be formed. However, if the trigger crack TC is already formed on the side surface of the glass substrate G2 when the scribe line L1 is formed, an undesired crack occurs in the glass substrate G2 starting from the trigger crack TC due to the load at the time of forming the scribe line. I am concerned that it will occur. On the other hand, if the trigger crack TC is formed after the scribe line L1 is formed as in the present embodiment, such a problem does not occur. Therefore, according to this Embodiment, it can avoid reliably that an undesired crack arises in the glass substrate G2 in the formation process of the scribe line L1 with respect to the glass substrate G1.

  In the present embodiment, in the step of dividing the mother substrate G, as shown in FIG. 5E, the surface of the glass substrate G2 corresponding to the position where the scribe line L1 is formed is pressed with the break bar BB. A stress in the direction of opening the scribe line L1 is applied to the mother substrate G. For this reason, since the surface of the glass substrate G2 is pressed at a position corresponding to the scribe line L1, the scribe line L1 is opened by applying a substantially equal stress to both sides of the mother substrate G around the scribe line L1. The glass substrate G2 in which no line is formed can be smoothly broken.

  In the present embodiment, in the step of forming the trigger crack TC, the trigger crack TC is formed not only on the side surface of the glass substrate G2 but also at a position corresponding to the scribe line L1 on the side surface of the glass substrate G1. For this reason, the trigger crack TC can be smoothly formed on the side surface of the glass substrate G2 using the formation of the trigger crack TC on the side surface of the glass substrate G1 as an introduction operation.

  In the present embodiment, as shown in FIG. 5D, the trigger crack TC is formed on the side surface of the glass substrate G2 over the entire length in the thickness direction of the glass substrate G2. Thus, the glass substrate G2 can be broken more appropriately by taking a long trigger crack TC when starting the glass substrate G2.

<Example of change>
Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made to the embodiments of the present invention other than the above.

  For example, in the above embodiment, the trigger crack TC is formed from the upper surface of the glass substrate G1 to the lower surface of the glass substrate G2. However, as shown in FIG. 8A, the trigger crack TC is formed only on the side surface of the glass substrate G2. It may be formed. Since the trigger crack TC is a starting point when the glass substrate G2 is broken, it is considered that the trigger crack TC may be formed at least on the side surface of the glass substrate G2.

  Further, the trigger crack TC does not necessarily have to be formed over the entire length in the thickness direction of the glass substrate G2. For example, as shown in FIG. 8B, the trigger crack TC is only a predetermined length from the upper surface of the glass substrate G2. May be formed. Since the trigger crack TC is a starting point when a break with respect to the glass substrate G1 progresses to the upper surface of the glass substrate G2, it is desirable that the trigger crack TC is connected to at least the upper surface of the glass substrate G2.

  Moreover, in the said embodiment, although the scribe line L1 was formed in the surface (upper surface) of the glass substrate G1, as shown in FIG.8 (c), the scribe line L2 was formed in the surface (lower surface) of the glass substrate G2. May be. In this case, the trigger crack TC is formed at least on the side surface of the glass substrate G1, and the breaking step is performed by applying a stress in a direction in which the surface of the glass substrate G1 is pressed to open the scribe line L2.

  Moreover, in the said embodiment, the stress of the direction which opens the scribe line L1 was provided to the mother board | substrate G by pressing the position corresponding to the scribe line L1 of the glass substrate G2 with the break bar BB. As shown in FIG. 8D, by pressing the upper surface of the glass substrate G1 downward with the upper surface and lower surface of the mother substrate G1 sandwiched between the holders B1 and B2, the stress in the direction of opening the scribe line L1 is mothered. It is also possible to apply to the substrate G. However, in this case, since it is difficult for stress to be evenly applied to both sides of the mother substrate G around the scribe line L1, there is a concern that the break accuracy of the glass substrate G2 is reduced as compared with the above embodiment.

  In the above embodiment, the trigger crack TC is formed by the scribing wheel 401. However, the trigger crack TC does not necessarily have to be formed by the scribing wheel 401. May be formed. The scribing wheel 301 that forms the scribe line L1 can also use other cutting edges such as a scribing wheel in which no groove is formed on the ridge line.

  In the above embodiment, the scribe head 2 for forming the trigger crack TC is provided separately from the scribe head 2 for forming the scribe line L1, but the scribe head 2 for forming the scribe line L1 is further provided with the trigger crack TC. It is also possible to configure the scribing apparatus 1 so as to form the above. In this case, the scribing head 2 is configured such that, for example, the scribing wheel 301 moves on the upper surface of the mother substrate G to the edge portion in the X-axis positive direction in FIG. The trigger crack TC is controlled to be formed on the side surface of the mother substrate G on the X axis positive side. In this configuration, the width in the X-axis direction of the first conveyor 11a is set so that the end on the positive side of the X-axis of the mother board G protrudes from the first conveyor 11a.

  In addition, the configuration, thickness, material, and the like of the mother substrate G are not limited to those shown in the above embodiment, and the substrate cutting method and the scribe device are used for cutting the mother substrate G of other configurations. Can be used.

  The embodiments of the present invention can be appropriately modified in various ways within the scope of the technical idea shown in the claims.

DESCRIPTION OF SYMBOLS 1 ... Scribe device 2 ... Scribe head (1st head, 2nd head)
11a ... 1st conveyor 11b ... 2nd conveyor 13 ... Guide (1st drive part)
14 ... Sliding unit (first drive part)
15 ... Drive motor (first drive unit)
16: Guide (second drive unit)
17 ... Sliding unit (second drive part)
18 ... Drive motor (second drive unit)
301, 401 ... scribing wheel (blade)
G ... Mother board G1 ... Glass board (first board)
G2 ... Glass substrate (second substrate)
SL ... Sealing material L1, L2 ... Scribe line TC ... Trigger crack (crack)

Claims (8)

A substrate cutting method for dividing a mother substrate formed by bonding a first substrate and a second substrate with a sealing material,
Forming a scribe line on the surface of the first substrate by moving the blade along the sealing material while pressing the blade against the sealing material on the surface of the first substrate;
Forming a crack at a position corresponding to a formation position of the scribe line on at least a side surface of the second substrate;
Dividing the mother substrate along the crack by applying stress in the direction of opening the scribe line to the mother substrate.
A substrate cutting method characterized by the above. The substrate cutting method according to claim 1,
A substrate cutting method, comprising performing the step of forming the crack after performing the step of forming the scribe line. In the substrate cutting method according to claim 1 or 2,
In the step of dividing the mother substrate, a stress in a direction to open the scribe line is applied to the mother substrate by pressing the surface of the second substrate corresponding to the position where the scribe line is formed. A substrate cutting method characterized by the above. In the substrate cutting method according to any one of claims 1 to 3,
In the step of forming the crack, the substrate cutting method is characterized in that a crack is also formed at a position corresponding to the scribe line on the side surface of the first substrate. In the substrate cutting method according to any one of claims 1 to 4,
The method for cutting a substrate, wherein the crack is formed on a side surface of the second substrate over the entire length of the second substrate in the thickness direction. A scribing device for forming a scribe line on a mother substrate formed by bonding a first substrate and a second substrate with a sealing material,
Scribe line forming means for forming a scribe line on the surface of the first substrate by moving the blade along the seal material while pressing the blade to a position facing the seal material on the surface of the first substrate; ,
A crack forming means for forming a crack at a position corresponding to a position where the scribe line is formed on at least a side surface of the second substrate;
A scribing device characterized by that. A scribing device for forming a scribe line on a mother substrate formed by bonding a first substrate and a second substrate with a sealing material,
A first head for forming a scribe line on the surface of the first substrate;
A second head forming a crack on at least a side surface of the second substrate;
A first drive unit that moves the first head along the sealing material;
A second drive unit that moves the second head in a direction perpendicular to the upper surface of the mother substrate,
The blade is moved along the sealing material while the first head is pressed against the sealing material on the surface of the first substrate.
The blade is moved in a direction perpendicular to the upper surface of the mother substrate while the blade is pressed at a position corresponding to the formation position of the scribe line on at least the side surface of the second substrate.
A scribing device characterized by that. The scribing device according to claim 7,
A first conveyor on which the mother substrate is placed when the scribe line is formed on the surface of the first substrate and the mother substrate can be transferred downstream;
A second conveyor provided on the downstream side of the first conveyor on which the mother substrate transferred by the first conveyor is placed;
In the second conveyor, the width of the second conveyor is larger than the width of the first conveyor in a direction perpendicular to the transfer direction of the mother board so that at least one end of the mother board protrudes from the second conveyor. Is set too small,
The second head is moved in a direction perpendicular to the mother substrate on the end side of the mother substrate protruding from the second conveyor.
A scribing device characterized by that.