WO2020110699A1 - Dispositif de mesure d'une plaque de verre - Google Patents

Dispositif de mesure d'une plaque de verre Download PDF

Info

Publication number
WO2020110699A1
WO2020110699A1 PCT/JP2019/044279 JP2019044279W WO2020110699A1 WO 2020110699 A1 WO2020110699 A1 WO 2020110699A1 JP 2019044279 W JP2019044279 W JP 2019044279W WO 2020110699 A1 WO2020110699 A1 WO 2020110699A1
Authority
WO
WIPO (PCT)
Prior art keywords
glass plate
dimension
pin
end surface
measuring instrument
Prior art date
Application number
PCT/JP2019/044279
Other languages
English (en)
Japanese (ja)
Inventor
隼人 奥
茂 山木
Original Assignee
日本電気硝子株式会社
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 日本電気硝子株式会社 filed Critical 日本電気硝子株式会社
Priority to JP2019563294A priority Critical patent/JP7328623B2/ja
Priority to CN201990001193.9U priority patent/CN216115736U/zh
Publication of WO2020110699A1 publication Critical patent/WO2020110699A1/fr

Links

Images

Classifications

    • GPHYSICS
    • G01MEASURING; TESTING
    • G01BMEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
    • G01B5/00Measuring arrangements characterised by the use of mechanical techniques
    • G01B5/02Measuring arrangements characterised by the use of mechanical techniques for measuring length, width or thickness

Definitions

  • the present invention relates to a glass plate measuring device for measuring the dimensions of a glass plate.
  • the glass plate manufacturing process includes a cutting process for cutting the glass plate into a predetermined size, and an end face processing process for finishing the cut end face of the glass plate such as chamfering.
  • the glass plate In the end face processing process, the glass plate is positioned with reference to the cut end face, and in various processes after the end face processing process, the glass plate is generally positioned with reference to the finished end face.
  • a shape measuring step of measuring shape data of a glass plate including dimensions of the glass plate may be performed after the cutting step or the end surface processing step (for example, , Patent Document 1).
  • two opposite sides of the glass plate are imaged from above with a camera, and the imaged image is analyzed, and the position between each side obtained from the position of each side is analyzed.
  • There is a method of measuring the distance for example, refer to Patent Document 2).
  • the object of the present invention is to measure the dimensions of a glass plate easily and reliably.
  • the present invention devised to solve the above problems is a glass plate measuring device for measuring the dimensions of a rectangular glass plate, the table having a mounting portion on which the glass plate is mounted, and the glass plate.
  • a first pin that comes into contact with any one of the four end faces of the first pin, a first dimension measuring instrument that measures the first dimension between the end face with which the first pin comes into contact and the end face opposite thereto, and the glass plate
  • a first position adjusting mechanism capable of adjusting the position of the first dimension measuring instrument according to the size.
  • the dimension between the end face with which the first pin contacts and the end face opposite to the first pin is measured by the first dimension measuring instrument.
  • the dimensions can be measured easily and reliably.
  • the position of the first dimension measuring instrument can be adjusted by the first position adjusting mechanism, so that it is possible to easily and reliably measure the glass plates having different dimensions.
  • the first pin and the first dimension measuring device face each other.
  • the first dimension (for example, the vertical dimension) between the end surface that the first pin contacts and the end surface that faces the end surface, and the end surface between the end surface that the second pin contacts and the end surface that faces the end surface
  • Both the second dimension (for example, the lateral dimension) can be efficiently measured without changing the orientation of the glass plate. Further, even when the size of the glass plate is changed, the positions of the first dimension measuring instrument and the second dimension measuring instrument can be adjusted by the first position adjusting mechanism and the second position adjusting mechanism, so that the dimensions are different. The glass plate can be measured easily and reliably.
  • the second pin and the second dimension measuring device face each other.
  • each of the first pin and the first dimension measuring instrument are provided, and a plurality of each of the second pin and the second dimension measuring instrument are provided, and each of the first dimension and the second dimension is It is preferable that the measurement is performed at a plurality of points.
  • a rod-shaped first calibration jig for calibrating the first dimension measuring instrument and a rod-shaped second calibration jig for calibrating the second dimension measuring instrument are provided.
  • one end of the first calibration jig contacts the first pin, and the other end of the first calibration jig contacts the first dimension measuring instrument. It is preferable that one end of the calibration jig is in contact with the second pin and the other end of the second calibration jig is in contact with the second dimension measuring instrument.
  • the first dimension measuring instrument can be calibrated using the first calibration jig, and the second dimension measuring instrument can be calibrated using the second calibration jig. Therefore, the measurement accuracy of the first dimension and the second dimension is improved.
  • each of the first calibration jig and the second calibration jig includes a small diameter portion and a large diameter portion having a diameter larger than the small diameter portion, and the table is larger than the first calibration jig.
  • a first support part that supports the diameter part and a second support part that supports the large diameter part of the second calibration jig, and the first support part and the second support part are lower than the placement part. Is preferred.
  • the large-diameter portions of the first calibration jig and the second calibration jig are simply supported by the first support portion and the second support portion provided on the table, and the positions of the respective calibration jigs are corrected. Adjustable (including height). Therefore, the calibration work of the first dimension measuring instrument and the second dimension measuring instrument becomes easy. Further, since the first support portion and the second support portion are lower than the placing portion, these supporting portions do not come into contact with the glass plate placed on the placing portion when the calibration work is not performed.
  • the dimensions of the glass plate can be measured easily and reliably.
  • FIG. 2 is a cross-sectional view taken along the line AA of FIG.
  • FIG. 1 is a cross-sectional view showing an example of a contact state between the straight edge ruler and the roller of the copying mechanism.
  • FIG. 2B is a sectional view taken along line BB of FIG. 1, showing a preparatory step of placing a glass plate on a table using a placing jig.
  • It is a top view of the glass plate measuring device which concerns on embodiment of this invention, Comprising: It is a figure which shows the straightness measuring process which measures the straightness of the end surface of a glass plate. It is a perspective view which shows the state which supported the weight by the support member through the glass plate in the straightness measurement process of FIG.
  • FIG. 13 is a cross-sectional view taken along the line DD in FIG. 12, showing the arrangement of calibration jigs in the calibration process.
  • FIG. 13 is a cross-sectional view taken along the line CC of FIG. 12, showing the positional relationship in the height direction between the support portion of the calibration jig and the glass plate.
  • XYZ in the figure is an orthogonal coordinate system.
  • the X and Y directions are horizontal, and the Z direction is vertical.
  • the glass plate measuring device 1 is a device for measuring the shape data of a rectangular glass plate G.
  • the glass plate measuring device 1 uses, as the shape data, the straightness of at least one of the end faces Ga to Gd of the glass plate G, the vertical and horizontal dimensions (X-direction dimension and Y-direction dimension) of the glass sheet G, and the glass.
  • the squareness of the end faces Ga to Gd intersecting at at least one of the corners G1 to G4 of the plate G is measured. That is, the glass plate measuring device 1 includes a straightness measuring device, a dimension measuring device, and a squareness measuring device.
  • the glass plate measuring device 1 basically includes a table 2 having a mounting portion 2x on which the glass plate G is mounted.
  • the glass plate G is mounted on the mounting portion 2x of the table 2 such that the end surfaces Ga and Gb are substantially parallel to the X direction and the end surfaces Gc and Gd are substantially parallel to the Y direction.
  • the thickness of the glass plate G is, for example, 0.2 to 10 mm, and the size of the glass plate G is, for example, 700 mm ⁇ 700 mm to 3000 mm ⁇ 3000 mm.
  • the glass plate G is manufactured by a known method such as a down draw method (for example, an overflow down draw method) or a float method.
  • the glass plate G is used, for example, as a substrate of a flat panel display such as a liquid crystal display or a cover glass such as a touch panel.
  • the mounting portion 2x may be formed of a single plane or a plurality of planes, but in the present embodiment, the first ridge portion 2a and the second ridge portion having a long contact portion that comes into contact with the glass plate G. It has a part 2b.
  • the contact portion of the first ridge portion 2a extends along the pair of opposed end surfaces Ga and Gb of the glass plate G, that is, along the X direction, and the contact portion of the second ridge portion 2b faces the glass plate G.
  • the contact portion of the first ridge portion 2a becomes elongated along the X direction, and therefore, when the glass plate G is moved along the X direction, the first ridge portion 2a does not contact the glass plate G. On the other hand, it does not become a great resistance. Therefore, it is possible to smoothly move (slide) the glass plate G in the X direction while the glass plate G is supported from below by the first ridge portion 2a.
  • the contact portion of the second ridge portion 2b is elongated along the Y direction, the second ridge portion 2b is larger than the glass plate G when the glass plate G is moved along the Y direction. I can't resist.
  • the glass plate G can be smoothly moved in two different X and Y directions for easy positioning.
  • the plurality of first ridge portions 2a are provided at a plurality of locations in the Y direction with a spacing in the X direction
  • the second ridge portions 2b are provided at a plurality of locations in the X direction with a spacing in the Y direction.
  • the first ridge portions 2a and the second ridge portions 2b are scattered on the table 2 at intervals so that the glass plate G can be supported in a stable posture.
  • the first ridge portion 2a and the second ridge portion 2b are detachably fixed to the table 2 by fasteners (not shown) such as screws. Therefore, any member of the plurality of ridges 2a and 2b can be individually replaced.
  • the arrangement of the first ridge portions 2a and the second ridge portions 2b is not particularly limited and may be, for example, a regular arrangement such as a grid pattern or a zigzag pattern. It may be a regular array.
  • the longitudinal direction of the contact portion of the first ridge portion 2a and the longitudinal direction of the contact portion of the second ridge portion 2b are not limited to the X direction and the Y direction, and may be directions different from each other.
  • another ridge portion having a long contact portion may be further provided along a direction different from the ridge portions 2a and 2b (for example, a direction having an angle of 45° with the X direction).
  • the cross-sectional shape of the first ridge portion 2a in the lateral direction is trapezoidal in consideration of the posture stability of the first ridge portion 2a on the table 2. That is, the first ridge portion 2a is wider on the bottom portion 2aa side than on the upper portion 2ab side, and is fixed to the table 2 in a state where the bottom portion 2aa is grounded to the table 2.
  • the upper portion 2ab (contact portion with the glass plate G) of the first ridge portion 2a may be a flat surface or a curved surface.
  • the upper portion 2ab of the ridge portion 2a may be formed in a linear shape by narrowing the width in the lateral direction.
  • the cross-sectional shape of the first ridge portion 2a in the lateral direction is, for example, a triangle. It can be shaped.
  • the cross-sectional shape of the first ridge portion 2a in the lateral direction is not particularly limited, and various changes can be made.
  • the first ridge portion 2a can adopt a sectional shape as shown in, for example, FIGS. 3A to 3D.
  • the first ridge portion 2a has a trapezoidal tip portion (on the side of the glass plate G) and a rectangular base portion (on the side of the table 2).
  • FIG. 3B the first ridge portion 2a has a semicircular shape whose tip portion forms a convex curved surface.
  • FIG. 3A the first ridge portion 2a has a trapezoidal tip portion (on the side of the glass plate G) and a rectangular base portion (on the side of the table 2).
  • the first ridge portion 2a has a semicircular shape whose tip portion forms a convex curved surface.
  • the first ridge portion 2a has a U shape having two ridges arranged in parallel.
  • the first ridge 2a may be brush-shaped, that is, the first ridge 2a may be a brush.
  • the cross-sectional shape of the second ridge portion 2b in the lateral direction (X direction) is not particularly limited, but may be the same as the cross-sectional shape of the first ridge portion 2a in the lateral direction (Y direction). Can be adopted.
  • the contact portion of the first ridge portion 2a and the contact portion of the second ridge portion 2b are preferably made of resin such as nylon. In this way, the glass plate G becomes slippery on the ridges 2a and 2b.
  • the entire first protrusion 2a and the second protrusion 2b are made of resin.
  • the longitudinal dimension (X-direction dimension) of the contact portion of the first ridge portion 2a and the longitudinal dimension (Y-direction dimension) of the contact portion of the second ridge portion 2b are, for example, 0.2 to 20 mm. Is preferred.
  • the short-side dimension (Y-direction dimension) of the contact portion of the first ridge portion 2a and the short-side dimension (X-direction dimension) of the contact portion of the second ridge portion 2b are, for example, 5 to 400 mm. Preferably.
  • the mounting portion 2x further includes a plurality of columnar protrusions 2c.
  • the projection 2c supports the glass plate G from below at its tip.
  • the tip of the protrusion 2c may be provided with a float mechanism for facilitating the positioning of the glass plate G, but in the present embodiment, it is composed of a spherical roller.
  • the protrusions 2c are scattered on the table 2 at intervals.
  • the arrangement mode of the protrusions 2c is not particularly limited, and may be, for example, a regular array such as a grid pattern or a zigzag pattern, or an irregular array.
  • the tip of the protrusion 2c may be a non-rolling body, and may have any shape such as a convex curved surface or a flat surface.
  • the glass plate measuring device 1 has a rangefinder 3, a holding mechanism 4, and a straightedge 5 as a configuration for measuring the straightness (straightness) of the end faces Ga to Gd of the glass plate G. And a copying mechanism 6 on the table 2.
  • the straightness means the magnitude of deviation from a geometrically correct straight line of a straight line shape.
  • the distance meter 3 measures the distance to the end surface Ga of the glass plate G placed on the mounting portion 2x of the table 2, that is, the displacement of the end surface Ga of the glass plate G from the reference position.
  • the reference position is set to the positions of both end portions in the X direction of the end surface Ga of the glass plate G. That is, the distance meter 3 is calibrated and the mounting position of the glass plate G is adjusted so that the measured value of the distance meter 3 is zero at both ends of the end surface Ga of the glass plate G in the X direction.
  • the distance meter 3 is a contact type distance meter (for example, a dial gauge) including a contactor 3a that contacts the end surface Ga of the measurement target, and a spindle 3b that holds the contactor 3a so as to be movable back and forth in the Y direction.
  • the contactor 3a is a cylindrical roller that rolls while contacting the end surface Ga of the glass plate G (see FIG. 8 described later). Further, the contactor 3a is biased toward the end surface Ga of the measurement target and can follow the end surface Ga of the measurement target.
  • the contactor 3a is, for example, a rolling element (for example, a spherical roller) having a shape other than a cylindrical shape, or a non-rolling element that slides on the end surface Ga of the glass plate G (for example, a needle-shaped member or a cylindrical member). May be
  • the holding mechanism 4 holds the rangefinder 3 so as to be movable in the Y direction (direction away from the end surface Ga of the glass plate G) and the X direction (direction along the end surface Ga of the glass plate G).
  • the holding mechanism 4 includes a first stage 4b movable in the X direction along a rail 4a provided on the table 2 and a first stage 4b movable in the Y direction along a rail 4c provided on the first stage 4b. And two stages 4d.
  • the first stage 4b can be moved in the X direction manually or automatically.
  • the distance meter 3 is attached on the second stage 4d.
  • the moving direction of the second stage 4d is parallel to the Y direction, it may have an angle with respect to the Y direction.
  • the holding mechanism 4 is provided on the table 2 and further includes a scale 4e indicating the position of the distance meter 3 in the X direction.
  • a scale 4e indicating the position of the distance meter 3 in the X direction.
  • predetermined marks indicating the measurement positions of the rangefinder 3 are provided on the scale 4e at equal intervals.
  • the scale 4e may be arranged at any position on the straightedge 5, for example.
  • the scale 4e may be omitted.
  • the straight edge 5 is provided on the table 2 along the X direction.
  • the straightness of the straightedge 5 is measured and recorded in advance.
  • the copying mechanism 6 is a mechanism for aligning the distance meter 3 attached to the holding mechanism 4 with the straightedge 5.
  • the copying mechanism 6 includes a pressing member 6a and a spring 6b.
  • the pressing member 6a has a base end attached to the second stage 4d, and a tip end coming into contact with the straight edge 5.
  • the spring 6b is provided between the first stage 4b and the second stage 4d so as to draw the second stage 4d toward the straight edge 5 side. Since the pressing member 6a is pressed against the straight edge ruler 5 by the pulling force of the spring 6b, the position of the range finder 3 in the X direction is stabilized.
  • the spring 6b may be provided so as to be pushed toward the straight edge 5 side by pushing the second stage 4d.
  • the spring 6b may be another elastic body such as rubber or may be omitted.
  • the pressing member 6a has a cylindrical roller 6c at its tip.
  • the straight edge ruler 5 includes a concave guide groove 5a that receives the roller 6c. That is, the roller 6c rolls on the straight edge ruler 5 while being received in the guide groove 5a.
  • the straightness of the straightedge 5 is measured and recorded in advance.
  • the tip of the pressing member 6a is, for example, a rolling element having a shape other than a cylindrical shape (for example, a spherical roller) or a non-rolling element that slides on the straight ruler 5 (for example, a spherical member or a cylindrical member). It may be.
  • the glass plate measuring device 1 has a first pin 7, a second pin 8 and a first size measuring instrument as a configuration for measuring the X-direction dimension and the Y-direction dimension of the glass plate G. 9 and the second dimension measuring device 10 are provided on the table 2.
  • the first pin 7 comes into contact with the end surface Gc of the glass plate G placed on the placing portion 2x of the table 2 substantially parallel to the Y direction.
  • the second pin 8 comes into contact with the end surface Ga of the glass plate G placed on the placing portion 2x of the table 2 substantially parallel to the X direction. That is, the second pin 8 comes into contact with the end face Ga that intersects the end face Gc with which the first pin 7 comes into contact at a substantially right angle.
  • the first dimension measuring device 9 measures the dimension between the end faces Gc and Gd substantially parallel to the Y direction, that is, the dimension (first dimension) of the glass plate G in the X direction.
  • the second dimension measuring device 10 measures the dimension between the end faces Ga and Gb substantially parallel to the X direction, that is, the Y dimension (second dimension) of the glass plate G.
  • the first dimension measuring device 9 is a contact type distance meter (for example, a dial gauge) including a contactor 9a that comes into contact with the end surface Gd and a spindle 9b that holds the contactor 9a so that it can move back and forth in the X direction.
  • the second dimension measuring device 10 includes a contactor 10a that contacts the end surface Gb, and a spindle 10b that holds the contactor 10a so that it can move back and forth in the Y direction.
  • the contacts 9a and 10a are cylindrical non-rolling elements.
  • the contacts 9a and 10a may be, for example, non-rolling bodies (for example, spherical members or needle-shaped members) having shapes other than the cylindrical shape, or rolling bodies (for example, cylindrical rollers or spherical rollers).
  • the first dimension measuring instrument 9 is provided on the first position adjusting mechanism F capable of adjusting the position in the X direction. As a result, the position of the first dimension measuring instrument 9 can be easily changed so that the glass sheets G having different dimensions can be measured. Further, when measuring other shape data other than the dimensions of the glass plate G, the first dimension measuring instrument 9 can be retracted to a position that does not interfere.
  • the first position adjusting mechanism F is not particularly limited as long as it can adjust the position of the first dimension measuring instrument 9 in the X direction, but in the present embodiment, the first rail Fa provided on the table 2 and the first rail Fa. , A first slider Fb movable in the X direction along the first rail Fa. The first slider Fb can be moved in the X direction manually or automatically.
  • a first dimension measuring meter 9 is attached on the first slider Fb.
  • the second dimension measuring device 10 is provided on the second position adjusting mechanism S whose position in the Y direction can be adjusted. Thereby, the position of the second dimension measuring instrument 10 can be easily changed so that the glass plates G having different dimensions can be measured. Further, when measuring shape data other than the dimensions of the glass plate G, the second dimension measuring instrument 10 can be retracted to a position where it does not interfere.
  • the second position adjusting mechanism S is not particularly limited as long as it can adjust the position of the second dimension measuring instrument 10 in the Y direction, but in the present embodiment, the second rail Sa provided on the table 2 and the second rail Sa are provided. , And a second slider Sb movable in the Y direction along the second rail Sa. The second slider Sb can be manually or automatically moved in the Y direction.
  • the second dimension measuring instrument 10 is attached on the second slider Sb.
  • Two sets of the first pin 7 and the first dimension measuring instrument 9 are provided, and two sets of the second pin 8 and the second dimension measuring instrument 10 are provided. That is, the X-direction dimension and the Y-direction dimension of the glass plate G are measured at two locations.
  • the X-direction dimension and the Y-direction dimension may be average values at two points.
  • the pair of the first pin 7 and the contactor 9a of the first dimension measuring device 9 face each other in the X direction. That is, the first pin 7 and the contactor 9a of the first dimension measuring instrument 9 forming the set have substantially the same Y-direction position.
  • the second pin 8 and the contactor 10a of the second dimension measuring instrument 10 forming a pair are directly opposed in the Y direction. That is, the second pin 8 and the contact 10a of the second dimension measuring instrument 10 forming the set have substantially the same X-direction position.
  • the first pin 7 and the second pin 8 are detachably held on the table 2.
  • engagement holes (not shown) for holding the pins 7 and 8 are provided on the table 2.
  • the engagement holes are preferably provided at a plurality of positions on the table 2 so that the mounting positions of the pins 7 and 8 can be adjusted when the size of the glass plate G is changed.
  • first pin 7 and the first dimension measuring meter 9 forming the set, and the second pin 8 and the second dimension measuring meter 10 forming the pair is omitted, and either the first dimension or the second dimension is omitted.
  • the configuration may be such that only one of them is measured. From the viewpoint of efficiently measuring the longitudinal dimension and the lateral dimension of the glass plate G, both the first pin 7 and the first dimension measuring instrument 9 forming a set, and the second pin 8 and the second dimension measuring instrument 10 forming the pair are both included. Is preferably provided.
  • the glass plate measuring device 1 has a first pin 11, a second pin 12, a range finder 13, and a distance meter 13 as a configuration for measuring the squareness of the end surfaces Ga to Gd of the glass plate G. Is provided on the table 2.
  • Reference numeral 14 in the figure is a calibration rangefinder for calibrating the rangefinder 13.
  • the first pin 11 is configured to come into contact with an end surface Gc (first end surface) of the glass plate G placed on the placing portion 2x of the table 2 substantially parallel to the Y direction.
  • the second pin 12 comes into contact with an end surface Gb (second end surface) of the glass plate G mounted on the mounting portion 2x of the table 2 substantially parallel to the X direction. That is, the first pin 11 and the second pin 12 are respectively in contact with the end faces Gc, Gb intersecting at the corner G1 which is the target of measuring the squareness.
  • the first pin 11 is composed of a pair of pins provided at intervals in the Y direction
  • the second pin 12 is composed of a single pin provided only in the X direction.
  • the end surface Gc is held in parallel with the straight line connecting the pair of first pins 11 by coming into contact with the pair of first pins 11. That is, the end surface Gc is held with a predetermined inclination set in advance.
  • the second pin 12 contacts the end surface Gb while maintaining such inclination of the end surface Gc. Thereby, the glass plate G is positioned by the total of three points of the pair of first pin 11 and second pin 12.
  • the first pin 11 and the second pin 12 are detachably held on the table 2.
  • engagement holes (not shown) for holding the pins 11 and 12 are provided on the table 2.
  • the engagement holes are preferably provided at a plurality of positions on the table 2 so that the mounting positions of the pins 11 and 12 can be adjusted when the size of the glass plate G is changed.
  • the range finder 13 has a reference position (indicated by a one-dot chain line in FIG. 11) where the end surface Gb is located when the end surface Gc and the end surface Gb of the glass plate G positioned by the first pin 11 and the second pin 12 are at right angles. The displacement of the actual position of the end surface Gb (refer to the position) (deviation in the Y direction from the reference position) is measured.
  • the distance meter 13 is a contact type distance meter (for example, a dial gauge) including a contactor 13a that contacts the end surface Gb and a spindle 13b that holds the contactor 13a so as to be movable back and forth in the Y direction.
  • the contact 13a is a cylindrical non-rolling body.
  • the contactor 13a may be, for example, a non-rolling element (for example, a spherical member or a needle-shaped member) having a shape other than a cylindrical shape, or a rolling element (for example, a cylindrical roller or a spherical roller).
  • the distance meter 13 contacts the end surface Gb at a position different from the position where the second pin 12 contacts the end surface Gb. In the present embodiment, the distance meter 13 contacts the end surface Gb between the position where the second pin 12 contacts the end surface Gb and the position where the end surface Gb intersects the end surface Gc.
  • the calibration distance meter 14 also includes a contact type distance meter including a contactor 14a that contacts the end surface Gb and a spindle 14b that holds the contactor 14a so as to be movable back and forth in the Y direction (for example, Dial gauge).
  • the calibration distance meter 14 contacts the end surface Gb at a position different from the position where the second pin 12 and the distance meter 13 contact the end surface Gb.
  • the calibration distance meter 14 contacts the end surface Gb between the position where the second pin 12 contacts the end surface Gb and the position where the distance meter 13 contacts the end surface Gb. ..
  • the distance meters 13 and 14 are held by a holding mechanism (for example, a slide mechanism) so as to be movable in the Y direction. Thereby, when measuring shape data other than the squareness of the glass plate G, the rangefinders 13 and 14 can be retracted to a position where they do not interfere. Further, when the size of the glass plate G is changed, the positions of the distance meters 13 and 14 can be easily adjusted.
  • a holding mechanism for example, a slide mechanism
  • the glass plate measuring apparatus 1 includes a mounting jig 15 that supports the glass plate G from below as a configuration for mounting the glass plate G on the mounting portion 2x of the table 2.
  • the mounting jig 15 is a ladder-shaped member having an opening 15a through which the ridges 2a and 2b and the protrusion 2c of the table 2 can be inserted.
  • the mounting jig 15 is mounted on the table 2 after the glass plate G is transferred from the mounting jig 15 to the ridges 2a and 2b and the protrusion 2c.
  • the ridges 2a and 2b and/or the protrusion 2c may be provided outside the opening 15a in addition to inside the opening 15a as long as they do not interfere with the mounting jig 15.
  • the mounting jig 15 may be, for example, a lattice-shaped member, and may have any shape having an opening through which the protrusions 2a and 2b and the protrusion 2c can be inserted.
  • the glass plate measuring method includes a preparatory step of mounting the glass plate G on the mounting portion 2x of the table 2, a straightness measuring step of measuring straightness of an end surface of the glass plate G, and a glass plate G.
  • a dimension measurement step of measuring the vertical and horizontal dimensions of the and the squareness measurement step of measuring the squareness of the end surface of the glass sheet G are provided in this order.
  • the order of these steps after the preparation step may be interchanged, for example, the dimension measuring step, the straightness measuring step, and the squareness measuring step may be performed in this order.
  • the glass plate G is placed on the placing jig 15 and carried to a position above the table 2 (a state indicated by a chain line in the figure).
  • the mounting jig 15 is lowered from this state, and the projections 2a and 2b and the protrusion (spherical roller) 2c of the mounting portion 2x of the table 2 are inserted into the opening 15a of the mounting jig 15.
  • the glass plate G mounted on the mounting jig 15 is pushed up by the ridges 2a and 2b and the protrusion 2c, and the glass plate G is moved from the mounting jig 15 to the ridges 2a and 2b and the protrusions. It is transferred to the section 2c.
  • the mounting jig 15 is lower than the ridges 2a and 2b and the protrusion 2c in a state of being mounted on the table 2. Therefore, after the glass plate G is transferred from the mounting jig 15 to the ridges 2a and 2b and the protrusion 2c, the mounting jig 15 can be mounted on the table 2 and accommodated.
  • the glass plate G supported by the mounting portion 2x is positioned.
  • the glass plate G is positioned so that one end in the X direction and the other end in the X direction of the end surface Ga of the glass plate G are located at predetermined reference positions. Specifically, at the first position P1 and the second position P2 for measuring both ends of the end surface Ga in the X direction, the glass plate G is placed so that the displacement from the reference position measured by the distance meter 3 becomes zero. Position.
  • the rangefinder 3 when the rangefinder 3 is moved between the first position P1 and the second position P2, in order to prevent wear of the contactor 3a of the rangefinder 3, It is preferable that 3a is retracted from the end surface Ga of the glass plate G.
  • the weight 16 is placed on the glass plate G so that the glass plate G does not move.
  • the distance measuring device 3 while checking the position with the scale 4e, the distance measuring device 3 is moved by a predetermined distance in the X direction by the holding mechanism 4, and the straightness of the end surface Ga of the glass plate G is measured. The weight 16 is removed from the glass plate G when the straightness measuring step is completed.
  • the weight 16 placed on the glass plate G is arranged near the end surface Ga of the glass plate G and along the end surface Ga (that is, the straight edge 5).
  • a support member 17 that extends along the end surface Ga (that is, the straight edge 5) and supports the weight 16 through the glass plate G is arranged on the table 2 near the end surface Ga of the glass plate G.
  • the straightness measuring step it is preferable to remove the pins 7, 8, 11 and 12 from the table 2 and retract the dimension measuring instruments 9 and 10 and the distance measuring instruments 13 and 14 to positions that do not interfere.
  • Examples of the retracting method of the dimension measuring instruments 9 and 10 and the distance measuring devices 13 and 14 include a method of retracting the entire dimension measuring instruments 9 and 10 and the distance measuring devices 13 and 14 to the retracted position, and contactors 9a and 10a. , 13a, 14a are retracted to the retracted position (state of FIG. 6).
  • the contactor 3a of the distance meter 3 is a cylindrical roller and rolls while contacting the end surface Ga of the glass plate G.
  • the portion of the contactor 3a that contacts the end surface Ga of the glass plate G sequentially changes, so that wear of the contactor 3a can be suppressed.
  • the contactor 3a is cylindrical, even if the end surface Ga of the glass plate G is inclined, the displacement of the most protruding portion of the end surface Ga is always measured. Therefore, the measurement error of the straightness by the distance meter 3 becomes small.
  • the rotation axis of the contactor 3a is substantially parallel to the thickness direction (Z direction) of the glass plate G.
  • the displacement (straightness) of the end surface Ga of the glass plate G measured by the rangefinder 3 is a straight line. It is affected by the straightness of ruler 5. Therefore, the difference (S1-S2) between the measured straightness S1 of the end surface Ga of the glass plate G and the straightness S2 of the known straightedge 5 is recorded as the final straightness of the end surface Ga of the glass plate G. To be done.
  • the end surface Ga of the glass plate G After the straightness of the end surface Ga of the glass plate G is measured, it is preferable to measure the end surface Ga of the glass plate G again with the range finder 3 at the positions P1 and P2 to check whether the glass plate G is displaced. That is, if the displacement from the reference position measured by the distance meter 3 at both positions P1 and P2 is zero, it can be confirmed that the glass plate G is not displaced before and after the measurement.
  • the straightness of the end surface Ga of the glass plate G is measured has been illustrated above, it is preferable to measure the straightness of each of the four end surfaces Ga to Gd of the glass plate G.
  • the orientation of the glass plate G with respect to the table 2 is changed by the mounting jig 15 or other means, and the straightness of the remaining end surfaces Gb to Gd is adjusted. Perform the same procedure.
  • the straightness of each of the four end faces Ga to Gd of the glass plate G is measured, for example, in the end face processing step included in the manufacturing process of the glass plate G, based on the straightness of each end face Ga to Gd of the glass plate G, The position of the processing tool can be adjusted accurately. Therefore, it becomes easy to process each of the end surfaces Ga to Gd of the glass plate G with a constant grinding amount.
  • the method of adjusting the position of the working tool based on such straightness can also be applied to the case of performing constant pressure grinding.
  • the first pin 7 and the second pin 8 are brought into contact with the end surfaces Ga and Gc of the glass plate G to position the glass plate G supported by the mounting portion 2x. ..
  • the contactors 9a, 10a of the dimension measuring instruments 9, 10 are brought into contact with the end faces Gb, Gd of the glass plate G, and the X-direction dimension and the Y-direction dimension of the glass plate G are measured. Since the contactors 9a and 10a of the dimension measuring instruments 9 and 10 are cylindrical, the positions of the most protruding portions of the end faces Gb and Gd of the glass plate G are measured, like the contactor 3a of the distance meter 3.
  • the X-direction dimension and the Y-direction dimension of the glass plate G may be measured at the same time or separately.
  • the first pin 7 is brought into contact with the end surface Gc of the glass plate G
  • the dimension of the glass plate G in the X direction is measured by the first dimension measuring instrument 9, and then the first pin 7 is measured.
  • the contact between the first dimension measuring instrument 9 and the glass sheet G is released, the second pin 8 is brought into contact with the end surface Ga of the glass sheet G, and the dimension of the glass sheet G in the Y direction is measured by the second dimension measuring instrument 10.
  • the second dimension measuring instrument 10 is measured.
  • each of the X-direction dimension and the Y-direction dimension is measured at two points, but the number of pairs of pins and the dimension measuring device that faces them can be appropriately changed. That is, each of the X-direction dimension and the Y-direction dimension may be measured at only one place, or may be measured at three or more places.
  • the distance meters 3, 13, 14 it is preferable to retract the distance meters 3, 13, 14 to a position that does not interfere with them.
  • Examples of the method of retracting the rangefinders 3, 13, 14 include a method of retracting the entire rangefinders 3, 13, 14 to the retracted position, or a method of retracting only the contacts 3a, 13a, 14a to the retracted position. (State of FIG. 9) and the like.
  • the perpendicularity measuring step first, the first pin 11 and the second pin 12 are brought into contact with the end faces Gb and Gc of the glass plate G to position the glass plate G supported by the mounting portion 2x. To do. In this state, the contact 13a of the distance meter 13 is brought into contact with the end surface Gb of the glass plate G, and the displacement (displacement in the Y direction) from the reference position of the end surface Gb is measured. Since the contactor 13a of the distance meter 13 has a cylindrical shape, the position of the most protruding portion of the end surface Ga of the glass plate G is measured, like the contactor 3a of the distance meter 3.
  • the displacement measured by the distance meter 13 is converted into the inclination of the end surface Gb with respect to the vertical surface of the end surface Gc, and this inclination indicates the squareness.
  • d1 is the displacement in the Y direction measured by the distance meter 13
  • d2 is the distance in the X direction between the known distance meter 13 and the second pin 12
  • d3 is the known X direction dimension of the glass plate G. (Design value).
  • the inclination of the end surface Gb with respect to the vertical surface of the end surface Gc may be automatically calculated by a calculation device from the displacement measured by the distance meter 13, or may be converted into an inclination by the displacement measured by the distance meter 13.
  • the table may be created in advance and read from the conversion table.
  • the retracting method of the distance meters 3, 14 and the dimension measuring instruments 9, 10 include, for example, a method of retracting the entire distance measuring instruments 3, 14 and the dimension measuring instruments 9, 10 to the retracted position, and the contactors 3a, 9a. , 10a, 14a are retracted to the retracted position (state of FIG. 10).
  • the glass plate measuring method calibrates the first calibrating step for calibrating the dimension measuring instruments 9 and 10 used in the dimension measuring step and the range finder 13 used for squareness measurement before the preparing step. And a second calibration step. These calibration steps may be performed every time the glass plate G is measured, or may be performed after the glass plate G is measured a predetermined number of times or a predetermined time. Moreover, you may implement when the size of the glass plate G of a measuring object changes. Of course, only the first calibration step may be performed, or only the second calibration step may be performed.
  • the rod-shaped first calibration jig 18 is used to calibrate the first dimension measuring instrument 9, and the rod-shaped second calibration jig 19 is used to perform the second calibration.
  • FIG. 12 shows a state in which the first dimension measuring instrument 9 is calibrated by using the first calibration jig 18 by a solid line, and a state in which the second dimension measuring instrument 10 is calibrated by using the second calibration jig 19 is indicated by a chain line. Shows. The calibration of the first dimension measuring instrument 9 and the calibration of the second dimension measuring instrument 10 are performed separately.
  • the lengths of the first calibration jig 18 and the second calibration jig 19 are known.
  • the length of the first calibration jig 18 is set to the reference dimension (design dimension) of the X-direction dimension of the glass plate G
  • the length of the second calibration jig 19 is the glass plate G. Is set to the reference dimension (design dimension) of the Y-direction dimension.
  • the calibration jigs 18 and 19 themselves are preferably calibrated regularly (for example, about once a year).
  • one end of the first calibration jig 18 is brought into contact with the first pin 7, and the other end of the first calibration jig 18 is brought into contact with the contact 9a of the first dimension measuring instrument 9.
  • one end of the second calibration jig 19 is brought into contact with the second pin 8 and the other end of the second calibration jig 19 is brought into contact with the contact 10a of the second dimension measuring instrument 10.
  • the reference position (for example, the zero point) of the first dimension measuring device 9 is calibrated to a position where the contact 9a contacts the first calibration jig 18, and the reference position (for example, the zero point) of the second dimension measuring device 10 is the contact member. 10a is calibrated at a position where it contacts the second calibration jig 19.
  • the first dimension measuring instrument 9 measures the displacement of the end surface Gd of the glass plate G from the reference position
  • the second dimension measuring instrument 10 measures the displacement of the end surface Gb of the glass sheet G from the reference position. taking measurement. That is, the sum of the reference dimension in each direction and the measured displacement (negative displacement when shorter than the reference dimension, positive displacement when longer than the reference dimension) is the dimension of the glass plate G in the X direction and the Y direction. Recorded as dimensions. Therefore, if the reference positions of the dimension measuring instruments 9 and 10 are calibrated as described above, the measurement accuracy of the X-direction dimension and the Y-direction dimension is improved.
  • the first calibration jig 18 includes a small diameter portion 18a and a large diameter portion 18b having a diameter larger than that of the small diameter portion 18a.
  • the second calibration jig 19 includes a small diameter portion 19a and a large diameter portion 19b having a diameter larger than that of the small diameter portion 19a.
  • the material of the small diameter portions 18a, 19a and the large diameter portions 18b, 19b is not particularly limited, but in the present embodiment, the small diameter portions 18a, 19a are made of metal, and the large diameter portions 18b, 19b are made of rubber. Is formed by.
  • a first support portion 20 that supports the large diameter portion 18b of the first calibration jig 18 and a second support portion 21 that supports the large diameter portion 19b of the second calibration jig 19 are provided. There is. Semi-cylindrical concave grooves are formed on the upper surfaces of the supporting portions 20 and 21 to support the cylindrical large diameter portions 18b and 19b.
  • the first supporting portion 20 and the second supporting portion 21 are lower than the placing portion 2x of the table 2, that is, the protruding portions 2a and 2b and the protruding portion 2c. As a result, as shown in FIG. 14, the supporting portions 20 and 21 do not come into contact with the glass plate G placed on the placing portion 2x when the calibration work is not performed.
  • the calibration having the first proof surface 22a and the second proof surface 22b which can be in contact with the first pin 11 and the second pin 12 and which are perpendicular to each other.
  • Jig 22 for example, a squarer
  • a calibration rangefinder 14 that measures the displacement of the position of the second assurance surface 22b from the reference position with the first assurance surface 22a in contact with the first pin 11. Is used to calibrate the range finder 13. It is preferable that the calibration jig 22 itself is also calibrated regularly (for example, about once a year).
  • the distance meter 13 and the calibration distance meter 14 of the second assurance surface 22b of the calibration jig 22 are The calibration jig 22 is moved to the second pin 12 side (Y direction) while confirming that the numerical values match.
  • the second assurance surface 22b of the calibration jig 22 can be brought into contact with the second pin 12 while the calibration jig 22 is maintained in the correct posture.
  • the calibration jig 22 can be installed easily and accurately.
  • the distance meter 13 can be correctly calibrated by measuring the position of the second assurance surface 22b of the calibration jig 22 thus installed with the distance meter 13 and correcting the reference position (zero point).
  • the calibration rangefinder 14 may be detached from the table 2 and retracted, instead of being retracted by the method described above.
  • the glass plate measuring method according to the present embodiment is carried out, for example, in the glass plate manufacturing process.
  • the glass plate manufacturing process includes a forming process for forming a glass plate, a cutting process for cutting the formed glass plate into a predetermined size, and an end face processing process for performing a finishing process such as chamfering on the cut end face of the glass plate.
  • Including and The glass plate measuring method is performed, for example, after the cutting step and/or the end surface processing step.
  • a measurement sample of the glass plate measuring method one or more glass plates are extracted from the glass plates in the process of production.
  • the drawn glass plate (measurement sample) is discarded after the shape data is measured and reused as, for example, cullet.
  • the shape data including the straightness of the end face, the vertical and horizontal dimensions, and the squareness of the end face of the glass plate G can be obtained without using advanced image processing or the like. Easy and reliable measurement. Further, since all of these shape data of the glass plate G can be measured on the mounting portion 2x, space saving can be achieved. Furthermore, since the glass plate G is supported by the ridges 2a and 2b and the protrusion 2c, even if the glass plate G has a large size, its positioning can be realized easily and at low cost.
  • the mounting portion 2x of the table 2 has been described as including the protruding portions 2a and 2b and the protruding portion 2c formed of a spherical roller.
  • the mounting portion 2x is particularly configured.
  • the present invention is not limited to this, and may have a configuration including only one of the protrusions 2a and 2b and the protrusion 2c.
  • the straightness of the end face of the glass plate G is intermittently measured at a plurality of positions on the end face has been described, but the straightness may be continuously measured at the end face.
  • the dimension of the glass plate G may be measured at one point on the end face, or at three or more points or along the end face. It may be measured continuously.
  • the shape data is not limited to this.
  • the shape data may include only dimensions, or may include straightness or squareness in addition to the dimensions.
  • other data such as the thickness and warpage of the glass plate G may be included.
  • the rangefinders 3, 13, 14 and the dimension measuring instruments 9, 10 may be non-contact type rangefinders such as an optical type (for example, a laser rangefinder).

Landscapes

  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • A Measuring Device Byusing Mechanical Method (AREA)
  • Length Measuring Devices By Optical Means (AREA)

Abstract

L'invention concerne un dispositif (1) de mesure d'une plaque de verre qui mesure les dimensions d'une plaque de verre rectangulaire (G), le dispositif (1) de mesure d'une plaque de verre étant pourvu : d'une table (2) comportant une section de montage (2x) sur laquelle est placée la plaque de verre (G) ; d'une première broche (7), en contact avec l'une quelconque des quatre surfaces d'extrémité (Ga-Gd) de la plaque de verre (G) ; d'un premier dispositif de mesure de dimension (9), permettant de mesurer une première dimension entre la surface d'extrémité avec laquelle entre en contact la première broche (7) et la surface d'extrémité faisant face à la surface d'extrémité, avec laquelle entre en contact la première broche (7) ; et d'un premier mécanisme de réglage de position (F), à même de régler la position du premier dispositif de mesure de dimension (9) en fonction de la taille de la plaque de verre (G).
PCT/JP2019/044279 2018-11-28 2019-11-12 Dispositif de mesure d'une plaque de verre WO2020110699A1 (fr)

Priority Applications (2)

Application Number Priority Date Filing Date Title
JP2019563294A JP7328623B2 (ja) 2018-11-28 2019-11-12 ガラス板測定装置
CN201990001193.9U CN216115736U (zh) 2018-11-28 2019-11-12 玻璃板测定装置

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
JP2018222556 2018-11-28
JP2018-222556 2018-11-28
JP2018-222564 2018-11-28
JP2018222564 2018-11-28

Publications (1)

Publication Number Publication Date
WO2020110699A1 true WO2020110699A1 (fr) 2020-06-04

Family

ID=70853195

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/JP2019/044279 WO2020110699A1 (fr) 2018-11-28 2019-11-12 Dispositif de mesure d'une plaque de verre

Country Status (4)

Country Link
JP (1) JP7328623B2 (fr)
CN (1) CN216115736U (fr)
TW (1) TW202024555A (fr)
WO (1) WO2020110699A1 (fr)

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2012101967A (ja) * 2010-11-09 2012-05-31 Nippon Electric Glass Co Ltd ガラス板の角部加工装置及び角部加工方法
CN203224196U (zh) * 2013-05-13 2013-10-02 旭硝子株式会社 板状体的检查装置

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP6367903B2 (ja) 2016-12-21 2018-08-08 株式会社飯田製作所 団子製造機

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2012101967A (ja) * 2010-11-09 2012-05-31 Nippon Electric Glass Co Ltd ガラス板の角部加工装置及び角部加工方法
CN203224196U (zh) * 2013-05-13 2013-10-02 旭硝子株式会社 板状体的检查装置

Also Published As

Publication number Publication date
TW202024555A (zh) 2020-07-01
CN216115736U (zh) 2022-03-22
JP7328623B2 (ja) 2023-08-17
JPWO2020110699A1 (ja) 2021-10-07

Similar Documents

Publication Publication Date Title
EP2466250B1 (fr) Artéfact d'étalonnage de machine
KR102013090B1 (ko) 평면도 측정 방법 및 핀 높이 조정 방법
JP2012211891A (ja) 表面性状測定機の校正方法
US9568308B2 (en) Multi-instrument calibration standard
WO2020110636A1 (fr) Dispositif de mesure d'une feuille de verre et procédé de fabrication d'une feuille de verre
WO2020110634A1 (fr) Dispositif servant à mesurer une feuille de verre
WO2020110635A1 (fr) Table
WO2020110699A1 (fr) Dispositif de mesure d'une plaque de verre
TWI846758B (zh) 桌台
US11255652B2 (en) Methods and apparatus for determining a height of an edge portion of a product
CN108180818A (zh) 一种测量l型工件平面度垂直度的高精度检测仪
KR102418946B1 (ko) 판재 가공대상물 평탄도 측정장치
JP7112880B2 (ja) 標準尺及び真直度測定方法
CN210464877U (zh) 评价线结构光激光器平面度的标定装置
CN106123740A (zh) 一种叉车门架槽钢特定高度内宽测量工具及其测量方法
TWM653844U (zh) 直尺校正裝置
JP3956008B2 (ja) 物体の寸法比較のための物体移動装置および該装置を用いた寸法比較方法
CN115727777A (zh) 一种连铸机扇形段弧度测量方法
CN116969290A (zh) 升降机设备导轨的安装调整工装及调整方法
CN111981958A (zh) 一种深度千分尺检定专用检具及检定方法
TWM259317U (en) Wafer holder calibration tool in semiconductor thermal process

Legal Events

Date Code Title Description
ENP Entry into the national phase

Ref document number: 2019563294

Country of ref document: JP

Kind code of ref document: A

121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 19890547

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 19890547

Country of ref document: EP

Kind code of ref document: A1