KR102862859B1 - An aligning method of the display for the vehicle electrical field and apparatus thereof - Google Patents

Abstract

The present invention relates to a method and device for aligning a vehicle electronic display, which can precisely measure the position of a display and a glass cover bonded to the upper side thereof at a close range through a simple operation in which a vision camera installed in a display alignment device moves in the X, Y, and Z axes to first measure each corner of a display fixed on each display jig, and then a band-shaped glass cover placed and fixed on a stand is spaced apart from the display surface at a fine interval, and the vision camera is moved in the X, Y, and Z axes again to measure each corner of the glass cover, and can easily correct the front-back, left-right, and fine distortion of the display through a UVW stage, thereby significantly reducing the position error of the display and the glass cover, improving the alignment precision of the vehicle electronic display, and shortening the alignment time of the vehicle electronic display.
In particular, a step in which a band-shaped glass cover (20) attached to the surface of the display (10) to protect each of a plurality of displays (10) is positioned on a cover holder (40) that can move back and forth through front and rear LM guides (30) on both sides, and the band-shaped glass cover (20) is supported by a support piece (41) so that the glass cover (20) is not bent and is fixed by being mounted on the cover holder (40), and a step in which a plurality of displays, each having an optically clear adhesive film (OCA: Optically Clear Adhesive) attached to the surface, is fixed and settled on a display jig (50) in a state in which the surface thereof is protruded through a support piece (51) in front of the display alignment device (100), and an X-axis LM guide (60) is horizontally arranged on the upper portion of the display alignment device (100), and a Y-axis LM guide (60) is vertically arranged on one side of the X-axis LM guide (60). A step of moving a measuring tool for aligning a display (10) in the X, Y, and Z axes by installing a guide (70) and a Z-axis LM guide (80) in the front and rear directions, a step of installing an alignment measuring tool (120) in which a vision camera (90) is installed on the lower axis of the Y-axis LM guide (70) and a compression roller (110) for bonding and pressing a glass cover (20) to the surface of the display (10) is installed on one side thereof, a step of moving the vision camera (90) installed in the alignment measuring tool (120) in the X, Y, and Z axes through the X-axis LM guide (60), the Y-axis LM guide (70), and the Z-axis LM guide (80) to measure each corner of a display (10) fixed on each display jig (50), a belt-shaped glass cover (20) positioned on the cover holder (40) is moved forward through the front and rear LM guides (30) on both sides, and at this time, the display A step of raising and lowering a support (140) installed on the upper side of a vertical LM guide (130) installed on both sides of an alignment device (100) to place the glass cover (20) in the shape of a belt, and then lowering it again to fix it at a predetermined interval on the surface of the display (10), a step of measuring the corners of the glass cover (20) by moving the vision camera (90) installed in the alignment measuring hole (120) in the X, Y, and Z axes of the glass cover (20) fixed at a predetermined interval on the surface of the display (10) through the support (140), and a step of correcting the front-back, left-right, and fine distortion of the display (10) placed on the display jig (50) by installing a UVW stage (150) at the lower side of each display jig (50), and installing a precision control motor (160) at the lower side of each UVW stage (150). It consists of an alignment method and a configuration of the device.

Description

{An aligning method of the display for the vehicle electrical field and apparatus thereof}

The present invention relates to a method and device for aligning a vehicle-mounted display, which can improve the alignment precision of the vehicle-mounted display, and more particularly, to a method and device for aligning a vehicle-mounted display, which can improve the alignment precision of the vehicle-mounted display, and can shorten the alignment time of the vehicle-mounted display, by a simple operation in which a vision camera installed in a display alignment device moves in the X, Y, and Z axes to first measure each corner of a display fixed on each display jig, and then a band-shaped glass cover placed and fixed on a stand is spaced apart from the display surface at a fine interval, and the vision camera is moved in the X, Y, and Z axes again to measure each corner of the glass cover, thereby enabling precise measurement of the position of the display and the glass cover attached to the upper side thereof through the vision camera at a close range, and can easily correct the front-back, left-right, and fine distortion of the display through a UVW stage, thereby remarkably reducing the positional error of the display and the glass cover, thereby improving the alignment precision of the vehicle-mounted display, and shortening the alignment time of the vehicle-mounted display.

In general, with the electrification of vehicles, the infotainment system, which provides information such as driving and route guidance, is developing further through the combination of the Internet and smartphones. At this time, a vehicle electrification display that transmits information is being used by bonding a display and protective glass together using a vacuum bonder and installing it on the vehicle's dashboard.

As described above, in the case of mounting a single display, a device that structures the product by combining a display and a protective glass using a vacuum bonder has been widely used. However, recently, when two or more displays are applied, the problem has arisen that the size of the vacuum bonder must be very large. In particular, as the demand for mounting a 3D display rather than a flat display for the sake of the interior space of a vehicle is increasing, it has become difficult to mount a display using a vacuum bonder as described above, and the development of a device capable of combining a display and a glass cover on its surface in an atmospheric pressure state rather than a vacuum has emerged.

In order to bond the display and the glass cover under the above atmospheric pressure, a bonding method using a pressure roller is common, but there is a technical problem that makes it extremely difficult to align the display and the glass cover, which is one of the most important quality factors.

1. Republic of Korea Patent Publication No. 10-1248136 (Registration date: March 21, 2013)

The present invention has been devised in consideration of the above problems, and its purpose is to provide a display alignment device in which a vision camera installed in a display alignment device is moved in the X, Y, and Z axes through an X-axis LM guide, a Y-axis LM guide, and a Z-axis LM guide to first measure each corner of a display fixed on each display jig, and then a band-shaped glass cover placed and fixed on a stand is spaced apart from the display surface at a fine interval of 1-5 mm, and the vision camera is moved in the X, Y, and Z axes again to measure each corner of the glass cover, thereby enabling precise measurement of the position of a display and a glass cover bonded to the upper side thereof through a close range through a vision camera, and accordingly, the front-back, left-right, and fine distortion of the display can be easily corrected through a UVW stage, thereby significantly reducing the positional error of the display and the glass cover, improving the alignment precision of an automotive display mounted on a vehicle, and shortening the alignment time of the automotive display. The purpose is to provide a method for aligning a battlefield display.

As a technical configuration for achieving the above object, the method and device for aligning a vehicle electrical display according to the present invention comprises the steps of: a band-shaped glass cover (20) attached to the surface of a display (10) to protect each of a plurality of displays (10) is positioned on a cover holder (40) that can move forward and backward via front and rear LM guides (30) on both sides; the band-shaped glass cover (20) is supported by a support piece (41) so that the glass cover (20) is fixedly mounted on the cover holder (40) without being bent;

A step in which a plurality of displays, each having an optically clear adhesive film (OCA: Optically Clear Adhesive) attached to its surface, are fixed and secured on a display jig (50) in a state in which the surface protrudes through a support (51) in front of the display alignment device (100);

A step of moving an alignment measuring tool (120) for alignment of a display (10) in the X, Y, and Z axes, in which an X-axis LM guide (60) is installed horizontally on the upper portion of the display alignment device (100), and a Y-axis LM guide (70) is installed vertically on one side of the X-axis LM guide (60), and a Z-axis LM guide (80) is installed forward and backward;

A step of installing an alignment measuring tool (120) in which a vision camera (90) is installed on the lower axis of the above Y-axis LM guide (70), and a pressing roller (110) for bonding a glass cover (20) to the surface of a display (10) is installed on one side thereof;

A step of measuring each corner of a display (10) fixed on each display jig (50) by moving the vision camera (90) installed in the alignment measuring device (120) in the X, Y, and Z axes through the X-axis LM guide (60), the Y-axis LM guide (70), and the Z-axis LM guide (80);

A belt-shaped glass cover (20) positioned on the cover holder (40) is moved forward through front and rear LM guides (30) on both sides, and at this time, a pillow (140) installed on the upper side of a vertical LM guide (130) installed on both sides of a display alignment device (100) is raised and lowered to place the belt-shaped glass cover (20), and then lowered again to fix it on the surface of the display (10) at a certain distance;

A glass cover (20) fixed to the surface of the display (10) by a stand (140) is moved in the X, Y, and Z axes by a vision camera (90) installed in the alignment measuring part (120) to measure each corner of the glass cover (20);

A step in which a UVW stage (150) is installed at the lower side of each of the above display jigs (50), and a precision control motor (160) is installed at the lower side of each of the above UVW stages (150) to correct the front-back, left-right, and fine distortion of the display (10) mounted on the display jig (50); and

It is characterized by comprising a configuration including a step of completing alignment with a glass cover (20) of a display (110).

In addition, the cover holder (40) is characterized in that a plurality of support pieces (41) are arranged at regular intervals, so that the belt-shaped glass cover (20) is supported by the support pieces (41), so that the glass cover (20) is fixedly placed on the cover holder (40) without being bent.

In addition, the interval at which the glass cover (20) in the shape of a belt is spaced apart from the surface of the display (10) so as to measure the corner of the glass cover (20) through the vision camera (90) is characterized by being spaced apart from the surface of the display (10) by 1-5 mm.

In addition, the pillow (140) installed on the upper side of the vertical LM guide (130) installed on both sides of the display alignment device (100) is characterized in that it is moved up and down by a driving motor (170) installed on the lower side.

In addition, the present invention provides an alignment device for a vehicle electrical display characterized by an alignment device for a display that performs the alignment method of the above display.

According to the present invention, a method and device for aligning a vehicle electrical display, a vision camera installed in a display alignment device is moved in the X, Y, and Z axes through an X-axis LM guide, a Y-axis LM guide, and a Z-axis LM guide, and the corners of the displays fixed on each display jig are first measured, and then a band-shaped glass cover placed and fixed on a stand is spaced apart from the surface of the display at a fine interval of 1-5 mm, and the vision camera is moved in the X, Y, and Z axes again to measure the corners of the glass cover, thereby enabling precise measurement of the positions of the display and the glass cover bonded to the upper side thereof at a close range through the vision camera, and accordingly, the front-back, left-right, and fine distortion of the display can be easily corrected through a UVW stage, and the positional error between the display and the glass cover can be significantly reduced, and the alignment precision of the vehicle electrical display can be improved, and the alignment time for the vehicle electrical display can be shortened.

Figure 1 is a flowchart for explaining an alignment method of a vehicle electrical display according to the present invention.
Figure 2 is a schematic perspective view of an alignment device for a vehicle electrical display according to the present invention.
Fig. 3(a) is a schematic front structural drawing of an alignment device for a vehicle electrical display according to the present invention, and (b) is a planar schematic structural drawing showing a state in which a display jig and a display fixed thereto and an upper glass cover thereof are sequentially fixed thereto.
Fig. 4(a) is a schematic front structural diagram of a state in which the vision camera of the present invention measures a corner of a display, and (b) is a schematic planar structural diagram of the main part of Fig. 4(a).
Fig. 5(a) is a schematic front structural diagram of a state in which the vision camera of the present invention measures a corner of a glass cover, and (b) is a schematic planar structural diagram of the main part of Fig. 5(a).

Hereinafter, a method and device for aligning a vehicle electrical display according to an embodiment of the present invention will be described in detail.

FIG. 1 is a flowchart for explaining a method for aligning a vehicle electrical display according to the present invention, FIG. 2 is a schematic perspective view of an alignment device for a vehicle electrical display according to the present invention, FIG. 3(a) is a schematic front structural diagram of the alignment device for a vehicle electrical display according to the present invention, (b) is a planar schematic configuration diagram showing a state in which a display jig and a display fixed thereto and an upper glass cover thereof are sequentially fixed, FIG. 4(a) is a schematic front structural diagram of a state in which a vision camera according to the present invention measures a corner of a display, (b) is a planar schematic configuration diagram of a main part of FIG. 4(a), and FIG. 5(a) is a frontal schematic configuration diagram of a state in which a vision camera according to the present invention measures a corner of a glass cover, and (b) is a planar schematic configuration diagram of a main part of FIG. 5(a). A band-shaped glass cover (20) attached to the surface of the display (10) to protect each of a plurality of displays (10) is positioned on a cover holder (40) that can move back and forth by interposing front and rear LM guides (30) on both sides, and at this time, the cover holder (40) has a plurality of support pieces (41) arranged at regular intervals, so that the band-shaped glass cover (20) is supported by the support pieces (41) so that the glass cover (20) is not bent and is fixed by being placed on the cover holder (40), and in front of the display alignment device (100), a support piece (51) is interposed so that a plurality of displays (10) each having an optically clear adhesive film (OCA: Optically Clear Adhesive) attached to the surface are fixed and settled in a state where the surface protrudes on the display jig (50), and an X-axis LM guide (60) is horizontally arranged on the upper part of the display alignment device (100), and the X-axis LM On one side of the guide (60), a Y-axis LM guide (70) in the vertical direction and a Z-axis LM guide (80) in the front-back direction are respectively installed to move a measuring tool for aligning the display (10) in the X, Y, and Z axes, and on the lower axis of the Y-axis LM guide (70), a laser measuring device (80) is installed in the center and a vision camera (90) is installed on one side thereof, and on the other side of the laser measuring device (80), an alignment measuring device (120) is installed on which a pressing roller (110) for pressing a glass cover (20) to the surface of the display (10) is installed.

In addition, the vision camera (90) installed in the alignment measuring device (120) is moved in the X, Y, and Z axes through the X-axis LM guide (60), the Y-axis LM guide (70), and the Z-axis LM guide (80) to measure each corner of the display (10) fixed on each display jig (50), and the belt-shaped glass cover (20) positioned on the cover holder (40) is moved forward through the front and rear LM guides (30) on both sides, and at this time, the support (pillow) (140) installed on the upper side of the vertical LM guide (130) installed on both sides of the display alignment device (100) is raised and lowered to place the belt-shaped glass cover (20), and then lowered again to fix it on the surface of the display (10) at a certain interval, while the glass cover (20) fixed on the surface of the display (10) at a certain interval through the support (140) is, A vision camera (90) installed in a measuring device (120) moves in the X, Y, and Z axes to measure each corner of the glass cover (20), a UVW stage (150) is installed at the bottom of each display jig (50), and a precision control motor (160) is installed at the bottom of each UVW stage (150), so as to correct the front/rear, left/right, and fine distortion of the display (10) mounted on the display jig (50), and complete the alignment of the display (110) with the glass cover (20).

In addition, the interval at which the glass cover (20) in the shape of a belt is spaced apart from the surface of the display (10) so that the corner of the glass cover (20) can be measured through the vision camera (90) is spaced apart from the surface of the display (10) by 1-5 mm.

In addition, the support (pillow) (140) installed on the upper side of the vertical LM guide (130) installed on both sides of the display alignment device (100) is configured to be moved up and down by a driving motor (170) installed on the lower side.

Meanwhile, the present invention features a display alignment device that performs the display alignment method.

An embodiment of the alignment method and device for a vehicle electrical display of the present invention having the above configuration is described in detail as follows.

As shown in FIGS. 1 to 5, the method and device for aligning a vehicle electrical display of the present invention comprises a band-shaped glass cover (20) attached to the surface of a display (10) by interposing an optically clear adhesive (OCA: Optically Clear Adhesive) which is a double-sided adhesive in the form of a sheet so as to protect each of the plurality of displays (10), and is positioned on a cover holder (40) which can move back and forth through front and rear LM guides (30) which are extended on both sides, and a plurality of support pieces (41) are extended at regular intervals on the cover holder (40) so that the band-shaped glass cover (20) is supported by the support pieces (41) so that the glass cover (20) is fixedly mounted on the cover holder (40) without being bent.

In addition, a support (51) extending downward is interposed in front of the display alignment device (100) so that a plurality of displays, each having an optically clear adhesive film (OCA: Optically Clear Adhesive) attached to its surface, are fixed and placed on a display jig (50) with their surfaces protruding.

In addition, in a state where the X-axis LM guide (60) is horizontally arranged on the upper portion of the display alignment device (100), a vertical connection (71) is provided on one side of the X-axis LM guide (60) so that the Y-axis LM guide (70) is vertically arranged, and a Z-axis LM guide (80) is installed in the front-back direction, so that a measuring tool for aligning the display (10) can be moved in the X, Y, and Z axes.

At this time, a laser measuring device (80) is installed in the center on the lower axis of the Y-axis LM guide (70) and a vision camera (90) is installed on one side thereof, and an alignment measuring device (120) is installed on the other side of the laser measuring device (80) and a pressing roller (110) for pressing a glass cover (20) to the surface of a display (10) is installed, so that the glass cover (20) can be freely moved in the X, Y, and Z axes.

At this time, the vision camera (90) installed in the alignment measuring device (120) measures each corner of the display (10) fixed on each display jig (50) while moving in the X, Y, and Z axes through the X-axis LM guide (60), the Y-axis LM guide (70), and the Z-axis LM guide (80), as shown in FIG. 4, to measure the exact position of the display (10) and store it as data in an input device (not shown).

Continuing, the belt-shaped glass cover (20) positioned on the cover holder (40) is moved forward through the front and rear LM guides (30) installed on both sides, and then the belt-shaped glass cover (20) is placed and fixed on a pillow (140) installed on the upper side of the vertical LM guides (130) installed on both sides of the display alignment device (100), and then lowered again to be fixed at a distance of 1-5 mm from the surface of the display (10).

The reason why the glass cover (20) fixed to the above-mentioned pillow (140) is spaced 1-5 mm apart from the surface of the display (10) is to enable precise measurement of the position of the glass cover (20) bonded to the display (10) and its upper side through a vision camera (90) at a close range, thereby further improving the precision when bonding the glass cover (20) through the pressing roller (110).

At this time, if the glass cover (20) is spaced apart from the surface of the display (10) by a gap of 1 mm or less, the glass cover (20) easily adheres to the surface of the display (10), making it impossible to perform an alignment operation of the display (10) mounted on the display jig (50) through the UVW stage (150) described later, and if the glass cover (20) is spaced apart from the surface of the display (10) by a gap of 1 mm or less, it becomes impossible to precisely measure the positions of the glass cover (20) and the display (10) due to the gap being too wide.

Meanwhile, the glass cover (20) fixed to the surface of the display (10) by being spaced apart from each other through a stand (140) is moved in the X, Y, and Z axes by the vision camera (90) installed in the alignment measuring hole (120) to measure each corner of the glass cover (20) to confirm the current position of the glass cover (20) and compare it with the position of the display (10) input as data in advance, and when an error occurs between the position of the display (10) measured by the vision camera (90) and the position of the glass cover (20) attached thereto, a UVW stage (150) is installed at the bottom of each display jig (50), and alignment work such as front-back, left-right, and fine misalignment of the display (10) mounted on the display jig (50) is performed by driving a precision control motor (160) installed at the bottom of each UVW stage (150).

In addition, the alignment measuring tool (120) that is moved to the X, Y, and Z axes through the X-axis LM guide (60), Y-axis LM guide (70), and Z-axis LM guide (80) is moved by a precision control motor (160) on the lower side of the UVW stage (150).

In addition, the support (pillow) (140) installed on the upper side of the vertical LM guide (130) installed on both sides of the display alignment device (100) to place and fix the glass cover (20) in the shape of a belt moves the glass cover (20) up and down by the driving motor (170) installed on the lower side, and in this way, the positional error of the display (10) and the glass cover (20) by the UVW stage (150) can be significantly reduced, the alignment precision of the display (10) mounted on the vehicle can be improved, and the alignment time of the vehicle electrical display (10) can be shortened.

While preferred embodiments of the present invention have been described above, the present invention is not limited to the specific embodiments described above. That is, those skilled in the art to which the present invention pertains may make numerous modifications and variations to the present invention without departing from the spirit and scope of the appended claims, and all such appropriate modifications and equivalents should be considered within the scope of the present invention.

10...Display 20...Glass Cover
30...front and rear LM guides 40...cover holder
41...Support piece 50...Display jig
51... Support 60... X-axis LM guide
70...Y-axis LM guide 71...Connection
80...Z-axis LM guide 90...Vision camera
100...display aligner
110...Compression roller 120...Alignment measuring hole
130...Vertical LM guide 140...Pillow
150...UVW stage 160...Precision control motor
170... drive motor

Claims (5)

A step in which a band-shaped glass cover (20) attached to the surface of the display (10) to protect each of a plurality of displays (10) is positioned on a cover holder (40) that can move forward and backward via front and rear LM guides (30) on both sides, and the band-shaped glass cover (20) is supported by a support piece (41) so that the glass cover (20) is fixedly mounted on the cover holder (40) without being bent;
A step in which a plurality of displays (10) each having an optically clear adhesive film (OCA: Optically Clear Adhesive) attached to the surface are fixed and placed on a display jig (50) in a state in which the surface protrudes through a support (51) in front of the display alignment device (100);
A step of moving a measuring tool for alignment of a display (10) along the X, Y, and Z axes, in which an X-axis LM guide (60) is installed horizontally on the upper portion of the display alignment device (100), and a Y-axis LM guide (70) is installed vertically on one side of the X-axis LM guide (60), and a Z-axis LM guide (80) is installed forward and backward;
A step of installing an alignment measuring tool (120) in which a vision camera (90) is installed on the lower axis of the above Y-axis LM guide (70), and a pressing roller (110) for bonding a glass cover (20) to the surface of a display (10) is installed on one side thereof;
A step of measuring each corner of a display (10) fixed on each display jig (50) by moving the vision camera (90) installed in the alignment measuring device (120) in the X, Y, and Z axes through the X-axis LM guide (60), the Y-axis LM guide (70), and the Z-axis LM guide (80);
A belt-shaped glass cover (20) positioned on the cover holder (40) is moved forward through front and rear LM guides (30) on both sides, and at this time, a pillow (140) installed on the upper side of a vertical LM guide (130) installed on both sides of a display alignment device (100) is raised and lowered to place the belt-shaped glass cover (20), and then lowered again to fix it on the surface of the display (10) at a certain distance;
A glass cover (20) fixed to the surface of the display (10) by a stand (140) is moved in the X, Y, and Z axes by a vision camera (90) installed in the alignment measuring part (120) to measure each corner of the glass cover (20);
A step in which a UVW stage (150) is installed at the lower side of each of the above display jigs (50), and a precision control motor (160) is installed at the lower side of each of the above UVW stages (150) to correct the front-back, left-right, and fine distortion of the display (10) mounted on the display jig (50); and
A method for aligning a vehicle electrical display, characterized in that it comprises a configuration including a step of completing alignment with a glass cover (20) of a display (110).
In the first paragraph,
The above cover holder (40) is characterized in that a plurality of support pieces (41) are arranged at regular intervals, and the belt-shaped glass cover (20) is supported by the support pieces (41) so that the glass cover (20) is fixedly mounted on the cover holder (40) without being bent.
In paragraph 1,
A method for aligning a vehicle electrical display, characterized in that the glass cover (20) in the shape of a belt is installed at an interval of 1-5 mm on the surface of the display (10) so that the corner of the glass cover (20) can be measured by a vision camera (90).
In paragraph 1,
A method for aligning a vehicle electrical display, characterized in that a pillow (140) installed on the upper side of a vertical LM guide (130) installed on both sides of the display alignment device (100) is moved up and down by a driving motor (170) installed on the lower side.
An alignment device for a vehicle electrical display characterized by an alignment device for a display that performs the alignment method of the display of the first clause above.