JP2013186381A - Display position alignment device for three-dimentional (3d) display type liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display position alignment device for quickly and easily improving accuracy of mutual 3D display positions of a 2D display type liquid crystal display unit and a display conversion perspective board.SOLUTION: The display position alignment device for a liquid crystal display device of a 3D liquid crystal panel is mounted on a workbench W and allows a worker to adjust and align mutual 3D display positions of a 2D liquid crystal display panel and a barrier while visually observing the 2D liquid crystal display panel and the barrier on a monitor. The display position alignment device for the 3D display type liquid crystal display device further includes a camera position changeover support mechanism.

Description

  The present invention relates to a display position alignment device for a 3D display type liquid crystal display device. Specifically, for example, the game display information (for example, symbol combinations) and the like is developed in accordance with the progress of the game content. The present invention relates to a device for adjusting and aligning the display position of a 3D display type liquid crystal display device for display to a person along plane coordinates.

For example, in pachinko machines that use pachinko balls as game media and slot machines that use coins, as a means of displaying game display information and the like according to the development of game content, In particular, 3D display type (stereoscopic display type) liquid crystal display devices are being used frequently. According to such a 3D liquid crystal display device, not only a background image that enhances the player's mood, but also a pattern as game display information related to the establishment of a special game (also called a big hit game) that has a stronger interest and interest than anything else. It is suitable for developing and displaying combination games.
The 3D liquid crystal display device has a 3D-dedicated liquid crystal display unit as its configuration and form, or a display conversion see-through board (also known as a barrier in the conventional 2D display type liquid crystal display unit). ) Is used. In the case of the former configuration, a dedicated 3D electronic display control device or the like is required, so that it becomes very expensive.

In the case of the latter configuration, the cost can be lower than that of the former configuration, and the 2D display type liquid crystal display unit can be reused by removing the display conversion see-through panel (barrier). There are many cases. However, in this case, it is necessary to adjust the display position and conditions of the liquid crystal display unit and the display conversion fluoroscopic board very precisely (this position is referred to as “3D display position / condition”). It is absolutely important and essential. However, it is still easy to handle and there is no proper dedicated alignment device, and even if the dedicated alignment device is used, accurate alignment assembly is still complicated and requires labor and skill of the operator. For this reason, each component of the 3D display type liquid crystal display unit has to be dependent on long-time manual work by a worker with high expertise and visual experience. The display conversion see-through panel (barrier) must be accurately aligned with the 3D display position of the type liquid crystal display unit and fixed using, for example, double-sided tape or adhesive.
Further, in a 3D display type liquid crystal display device, when the display conversion see-through board (barrier) is separated and returned to the original 2D display type liquid crystal display unit, a double-sided adhesive tape that adheres both firmly, When the agent or the like is forcibly removed, the liquid crystal display unit may be damaged, or an adhesive part such as a double-sided tape may remain, making it difficult to reuse the liquid crystal display unit itself.
Therefore, the inventor of the present application can quickly and easily set the 3D display position / condition of the 2D display type liquid crystal display unit and the display conversion see-through display panel (barrier) quickly and accurately, and can easily and easily separate them. Thus, the liquid crystal display unit itself was invented so that it can be restored and reused as a regular / genuine 2D display (Patent Document 1 by the present applicant).

Japanese Patent No. 4756108

In the above-mentioned patent document, the 2D display type liquid crystal display unit and the display conversion see-through board still need to be assembled manually. The assembly error between the liquid crystal display unit and the display conversion see-through panel was about 0.1 mm at the maximum. For this reason, it is necessary to use a magnifying glass or the like in order to match the liquid crystal display unit and the display conversion see-through board (barrier) with the normal position condition, which is a laborious operation.
The present invention has been made in view of the above circumstances, and its purpose is to quickly and easily determine the 3D display positions and conditions of a 2D display type liquid crystal display unit and a display conversion perspective board (barrier) quickly and easily. It is to provide a display position alignment device that can be improved.

Thus, the display position alignment device of the 3D display type liquid crystal display device according to the invention for achieving the above object is placed on the work table, and the 2D liquid crystal display panel and the display conversion see-through panel (barrier) are mutually connected. It is a 3D liquid crystal panel that can be assembled and aligned with each other at the 3D display position while visually recognizing the position on the monitor,
An apparatus main body horizontally held on the upper surface of the workbench, and a positioning coordinate device installed on a horizontal substrate of the apparatus main body, the positioning coordinate device includes a Y table plate, an X table plate, A θ table plate is provided in a three-stage configuration, and the uppermost θ table plate has a panel housing portion for housing the 2D liquid crystal display panel and a panel fixing for positioning and fixing the 2D liquid crystal display panel in the panel housing portion. Tools are provided,
The Y table plate is slidable in the Y direction with respect to the apparatus body, the X table plate is slidable in the X direction with respect to the Y table plate, and the θ table plate is the X table plate. A Y coordinate adjuster that adjusts the position of the horizontal board by sliding the Y table board in the Y direction is provided on the horizontal board. An X coordinate adjuster that adjusts the position by sliding the X table plate in the X direction is provided, and the X table plate is provided with a θ coordinate adjuster that adjusts the position by rotating the θ table plate. And
The apparatus main body is provided with a holding frame for positioning for fixing and holding the display conversion perspective board (barrier) so as to be separable, with a cantilevered fulcrum, which can be opened and closed.
When positioning the 2D liquid crystal display panel and the display conversion see-through panel, the plane coordinates of the lower 2D liquid crystal display panel with respect to the upper display conversion see-through board at a fixed position above the θ table plate. A coordinate detection camera for enlarging and detecting an image position shift and sending an image signal to the monitor; a retreat position for retracting the coordinate detection camera from a position above the display conversion perspective board; and a detection position above the display conversion perspective board. And a camera position switching support mechanism movable between the two.

In the present invention, the “display conversion see-through board” is a see-through board that enables 3D display by placing the display on a proper display reference alignment (display mark alignment) position condition on the image display surface of the 2D liquid crystal display panel. Means. Such display conversion see-through boards include a parallax barrier (simply referred to simply as a barrier) that enables stereoscopic viewing by the parallax barrier method, and a lenticular lens that enables stereoscopic viewing by the lenticular screen method. It is.
In the present invention, “X direction” and “Y direction” mean directions orthogonal to each other in two-dimensional coordinates, and the X direction is not necessarily the horizontal direction, and the Y direction is not necessarily the vertical direction. That is, when the X direction is the horizontal direction, the Y direction is the vertical direction, and when the Y direction is the horizontal direction, the X direction is the vertical direction.
In the present invention, it is preferable that the Y table plate, the X table plate, and the θ table plate be a positioning coordinate device provided in one outer body.

According to the present invention, the 2D liquid crystal display panel is positioned and fixed by the panel fixture on the uppermost θ table plate, the holding frame is closed from above, and the display conversion see-through panel is positioned in the holding frame. Thus, the display conversion see-through board is temporarily set on the image display surface side of the 2D liquid crystal display panel. In the present invention, from this state, the position of the lower 2D liquid crystal display panel (not the display conversion see-through panel) is adjusted along the X / Y plane coordinates to obtain a predetermined 3D display position. That is, by operating the Y coordinate adjustment tool, the X coordinate adjustment tool, and the θ coordinate adjustment tool while the 2D liquid crystal display panel and the display conversion perspective board are enlarged and displayed on the monitor by the coordinate detection camera as the detection position, While finely adjusting the position of the 2D liquid crystal display panel, it is guided to the 3D display position.
As described above, according to the present invention, it is possible to provide a display position matching device for quickly and easily adjusting the 2D liquid crystal display panel and the display conversion see-through panel to 3D display position conditions with high accuracy.

It is a perspective view which shows the outline | summary of the display position alignment apparatus in 1st Embodiment of this invention. It is a front view of a display position alignment apparatus. It is a rear view of a display position alignment apparatus. It is a left view of a display position alignment apparatus. It is a right view of the display position alignment apparatus when a holding frame is opened. It is a top view of a display position alignment apparatus when a holding frame is opened and a coordinate detection camera is set to a retracted position. It is a top view of a display position alignment apparatus when a holding frame is closed and a coordinate detection camera is set to a detection position. It is a figure which shows the structure of the back surface side of the Y table board of a positioning coordinate device, an X table board, and (theta) table board, and the structure of a coordinate adjustment tool. It is a figure which shows the structure of a fixing tool. (A) shows an open state in which the pressing and fixing portion is pulled toward the axis, and (B) shows a fixing state in which the pressing and fixing portion is extended. It is a figure which shows the structure of a coordinate adjustment tool. (A) shows a state where the operating portion is turned to the left to shorten the pressing shaft, and (B) shows a state where the operating portion is turned to the right to extend the pressing shaft. It is a top view which shows the structure of a coordinate detection camera. (A) shows the state when in the retracted position, and (B) shows the state when the motor is driven to the detection position. FIG. 3 is a perspective view schematically showing a main configuration of a 3D display type liquid crystal display device in an exploded state. FIG. 3 is a perspective view schematically showing a display conversion see-through board (barrier). It is a partial sectional side view before the assembly of a 3D display type liquid crystal display unit. It is explanatory drawing which illustrates the assembly | attachment procedure of 3D liquid crystal panel in steps. (A) is supported by a cushioning material when the barrier fixed to the holding frame is placed on the upper surface of the rear frame case and the 2D liquid crystal display panel fixed in the panel housing, and can be slid relative to each other. In (B), after adjusting the 3D display position with the coordinate adjuster, the front frame case presses the barrier from the front, compresses and deforms the cushioning material, and the crimping material is closely fixed to the support edge. It is a sectional side view which shows the state which carried out. It is a monitor image figure (1) for showing the operation procedure which matches a 2D liquid crystal display panel and a barrier with 3D display position conditions. (A) shows the initial position before the positioning operation, (B) shows the position where the X coordinate is temporarily matched, and (C) shows the position where the Y coordinate is temporarily matched. It is a monitor image figure (2) for showing the operation procedure which matches a 2D liquid crystal display panel and a barrier with 3D display position conditions. (A) shows the horizontal position by matching the θ coordinate, (B) shows the position where the Y coordinate is matched, and (C) shows the 3D display position by matching the X coordinate. . It is a front view of the display position alignment apparatus in 2nd Embodiment of this invention. It is a left view of the display position alignment apparatus when a protective frame is opened. It is a top view of the display position alignment apparatus when a protective frame is closed. The coordinate detection camera is in the retracted position. It is a top view of a position coordinate device. It is a front view of a position coordinate device. It is a rear view of a position coordinate device. It is a right view of a position coordinate device. It is a left view of a position coordinate device.

Next, embodiments of the present invention will be described with reference to the drawings. However, the technical scope of the present invention is not limited by these embodiments, and various forms can be made without changing the gist of the invention. Can be implemented. Further, the technical scope of the present invention extends to an equivalent range.
Hereinafter, a display position alignment apparatus according to the present invention will be described in detail with reference to the accompanying drawings by way of preferred embodiments.

<Configuration of liquid crystal display device and simple assembly process>
Prior to describing the details of the display position alignment device 30, the structure of the liquid crystal display device 10 which is a 3D display type liquid crystal panel will be briefly described. As the 3D display type liquid crystal display device 10, the one disclosed in Patent Document 1 can be used.
The liquid crystal display device 10 is installed in the center of a game board of a pachinko machine, for example, and is used as a symbol combination display device that can sequentially display various symbols (numbers, alphabets, various characters, fruits) based on a start signal input. . As a basic configuration of the liquid crystal display device 10, as schematically shown in FIG. 12, a conventionally used horizontal rectangular 2D liquid crystal display panel 11 and a rear frame that accommodates and protects the 2D liquid crystal display panel 11. Case 12, barrier 13 as a horizontal rectangular display conversion see-through board that is aligned and held at the 3D display position as a display conversion see-through board on the front side (surface displaying image) of 2D liquid crystal display panel 11, and this barrier 13 and a horizontal rectangular front frame case 14 which is screwed and joined to the front side of the rear frame case 12 in a positioning alignment state with the cover 13 being protected. The rear frame case 12 is formed in a rectangular frame shape from a transparent hard synthetic resin material (for example, polycarbonate), and the 2D liquid crystal display panel 11 can be attached and detached from the front side of the opening 12B formed in the rectangular shape. Contain and protect. On the left and right frame edges and the upper and lower frame edges of the rear frame case 12, bosses 12A capable of screwing assembly screws are arranged and molded.

A metallic outer peripheral protective frame 16 is attached to the four outer peripheral edges (left and right edges excluding the image display surface 11A and upper and lower edge portions) of the display main body 11B to protect the display main body 11B. Support edges 16 </ b> A (width of about 10 to 15 mm) on the four sides (left and right, upper and lower) of the outer peripheral protection frame 16 are flat surfaces as mounting and fixing edges of the barrier 13.
The barrier 13 is mainly composed of a rectangular plate glass, and on the back surface thereof (that is, the surface facing the image display surface 11A), the barrier 13 covers a rectangular surface area excluding the outer peripheral edge of about 10 to 15 mm, for 3D display conversion. A display conversion screen 17 is formed. On the outer peripheral edge of the rear surface of the barrier 13, as shown in FIG. 13, the pressure-sensitive adhesive 18 having a thickness t 1 that is detachably pressed against the front surface of each support edge 16 A of the outer peripheral protective frame 16, and the outer peripheral protective frame 16 On the other hand, a cushioning material 19 having a thickness t2 (> t1) capable of being compressively deformed, which can be inseparably separated from each other, is arranged. Both the pressure-bonding material 18 and the buffer material 19 are formed in a band shape having a width of about 5 to 8 mm, and are bonded to the left and right edges and the upper and lower edges of the barrier 13 with an adhesive (for example, double-sided tape) in advance (see FIG. 13). Shows a state in which some of the pressure-bonding material 18 and the cushioning material 19 are removed for convenience of explanation, but these members are moved and adhered in the direction of arrow A). The pressure-bonding material 18 does not have adhesiveness or stickiness, and has a soft elasticity that presses tightly against a flat surface (metal outer peripheral protective frame 16) with a pressing force. Further, the buffer material 19 has predetermined elasticity, and is elastically compressed and deformed by an appropriate pressing force to allow the pressure bonding material 18 and the outer peripheral protection frame 16 to be pressure bonded. That is, the pressure bonding material 18 has a property capable of being pressure bonded to the surface of the support edge 16 </ b> A of the outer peripheral protection frame 16.

Next, an assembly process of the 3D display type liquid crystal display device 10 will be briefly described with reference to FIGS. 14 and 15. As shown in FIG. 14, the rear frame case 12 and the 2D liquid crystal display panel 11 are accommodated and fixed in a horizontal state on a display position alignment device 30 (described in detail later).
Next, the display conversion screen 17 of the barrier 13 is placed facing the rear surface toward the image display surface 11A. In this state, the cushioning material 19 provided on the back surface outside the outer periphery of the barrier 13 is in an uncompressed state in which it is not pressed while being in contact with the upper surface of the support edge 16A of the outer peripheral protection frame 16 of the 2D liquid crystal display panel 11. A predetermined gap t3 (= t2−t1) exists between the lower surface of the pressure bonding material 18 and the upper surface of the support edge 16A of the outer peripheral protection frame 16, and the display conversion screen 17 of the barrier 13 and the 2D liquid crystal display. There is a gap between the panel 11 and the image display surface 11A, and they are in a facing state where the two are vertically separated (the barrier 13 is still floating) (see FIG. 15A).

Here, the position of the 2D liquid crystal display panel 11 is finely adjusted along the plane coordinates while the barrier 13 is not crimped using the display position alignment device 30, so that both the members 11 and 13 are set to the 3D display positions and conditions. Align (details later). Thereafter, the entire outer peripheral edge is strongly pressed against the 2D liquid crystal display panel 11 from the upper surface side of the barrier 13. Thereby, the cushioning material 19 provided on the lower surface side around the barrier 13 is in close contact with the upper surface of the support edge 16A of the outer peripheral protection frame 16 of the 2D liquid crystal display panel 11 in a state of being compressed and deformed, and the pressure-bonding material 18 is slightly The barrier 13 is immobilized and held in a state in which it is strongly pressed against the upper surface of the support edge 16A of the outer peripheral protection frame 16 after being subjected to compression wall thickness deformation (or almost with the original thickness t1). In a state where the 2D liquid crystal display panel 11 and the barrier 13 are fixed at the 3D display position and conditions, the front frame case 14 is positioned and aligned with the rear frame case 12 while covering the barrier 13, and the boss 12A and the screw hole 14A are aligned. A screw (not shown) is tightened and assembled (FIG. 15B).
If necessary, the barrier 13 and the 2D liquid crystal display panel 11 can be easily separated by releasing the pressure-bonded state between the pressure-bonding material 18 and the outer peripheral protective frame 16.

<First Embodiment: Configuration of Display Position Matching Device>
Next, the configuration of the display position alignment device 30 for aligning the 2D liquid crystal display panel 11 and the barrier 13 with the 3D display position / condition will be described.
FIG. 1 is a perspective view schematically showing the display position alignment device 30 and the liquid crystal display device 10 before combination.
As shown in FIGS. 2 to 5, the display position alignment device 30 is used in a state where it is horizontally placed on the work table W. Above the display position alignment device 30, a pair of left and right coordinate detection cameras 31, 32 are provided, and visual monitors 33, 34 for receiving and displaying image signals from the coordinate detection cameras 31, 32 are provided. Is provided. The coordinate detection cameras 31 and 32 can enlarge and detect the positional deviation of the coordinates between the barrier 13 and the 2D liquid crystal display panel 11 and display them on the monitors 33 and 34.

The display position alignment apparatus 30 is provided with an apparatus main body 35 that is horizontally held on the upper surface of the work table W, and a horizontal substrate 36 that is positioned at the lowermost position of the apparatus main body 35. On the upper surface of the horizontal substrate 36, a positioning coordinate device 37 is provided. The positioning coordinate unit 37 includes a Y coordinate adjustment table (hereinafter also simply referred to as a Y table plate) 38, an X coordinate adjustment table (hereinafter also simply referred to as an X table plate) 39, as adjustment members along the plane coordinates, in order from below. Three sheets of θ angle adjustment tables (hereinafter also simply referred to as θ table plates) 40 are provided in a three-stage state.
As shown in FIG. 8, a Y rail structure 41 is provided on the upper surface side of the horizontal substrate 36 and the lower surface side of the Y table plate 38 so as to be slidable in the Y direction. An X rail structure 42 is provided on the upper surface side of the Y table plate 38 and the lower surface side of the X table plate 39 so as to be slidable in the X direction. Further, on the upper surface side of the X table plate 39 and the lower surface side of the θ table plate 40, there are provided rotating assembly structures 43 that can rotate in both the left and right directions with the center of the θ table plate 40 as an axis. Each structure 41, 42, 43 is provided with two helical springs 44, 45, 46 so as to be sandwiched between a pair of upper and lower plates. Both ends of the helical springs 44, 45, 46 are fixed to the upper and lower plates, respectively, so that both plates are biased toward the initial position (for example, the horizontal substrate 36 and the Y table plate 38). A helical spring 44 provided between the horizontal substrate 36 and the Y table plate 38 has one end fixed to the horizontal substrate 36 and the other end fixed to the Y table plate 38 so that the overlap between the horizontal substrate 36 and the Y table plate 38 increases. Energized).

  In addition, the apparatus main body 35 is provided with a Y coordinate adjusting tool 47 that abuts on and presses the Y table plate 38 to slide the Y table plate 38 in the Y direction. As shown in FIG. 8, the Y coordinate adjuster 47 is configured to apply a force parallel to the Y axis direction along a virtual line L passing through the center of the Y coordinate table plate 38. Further, the Y table plate 38 is provided with an X coordinate adjusting tool 48 that abuts against and presses the X table plate 39 to slide the X table plate 39 in the X direction. The X coordinate adjustment tool 48 is configured to apply a force parallel to the X axis direction along an imaginary line M passing through the center of the X coordinate table plate 39. The X table plate 39 is in contact with and pressed against the θ table plate 40 to change (rotate) the angle of the rotating assembly structure 43 provided at the center of the θ table plate 40. Is provided. The θ coordinate adjuster 49 presses the right end portion of the θ table plate 40.

  As shown in FIG. 10, the structure of each adjustment tool 47,48,49 is provided with the same thing. In other words, the adjusters 47, 48, and 49 come close to the operation unit 50 that can be rotated in both the left and right directions (see arrow B in FIG. 10), as the operation unit 50 rotates. A pressing shaft 51 that is movable in a direction and a direction away from it is provided, which is just similar to the structure of a micrometer. The tip of the pressing shaft 51 is always in contact with the table plates 38, 39, and 40. When the pressing shaft 51 is operated in the extending direction, the table opposes the urging force of the helical springs 44, 45, and 46. When the plates 38, 39, and 40 are moved, the table plates 38, 39, and 40 are moved by the biasing force of the helical springs 44, 45, and 46 when the pressing shaft 51 is operated in a contracting direction.

  On the upper surface side of the θ table plate 40, a panel housing portion 52 having a dent slightly larger than the rear frame case 12 housing the 2D liquid crystal display panel 11 is provided. On the left-hand side, panel fixtures 53A and 53B that contact and fix the rear frame case 12 are provided. As shown in FIG. 9, the panel fixtures 53A and 53B are configured by a link mechanism. From the open position shown in FIG. 9 (A), the handle portion 54 is rotated around the axis 55 to the right (in the drawing). The position of the rear frame case 12 and the 2D liquid crystal display panel 11 can be fixed by moving the pressing and fixing portion 56 forward by rotating in the direction of arrow A). Note that when the handle portion 54 is rotated leftward, the pressing fixing portion 56 is retracted, and the fixing to the 2D liquid crystal display panel 11 is released. In this embodiment, the panel fixtures 53A and 53B are provided at two locations in the X-axis direction and the Y-axis direction, but may be provided at only one location in the direction of pressing in the upper right direction at the lower left corner.

  In the apparatus main body 35, a holding frame 57 for fixing and positioning the barrier 13 is provided on the right side of the positioning coordinate unit 37. One end side of the holding frame 57 includes a cantilever fulcrum that can be rotated by a hinge portion 58. Thus, the holding frame 57 is between a closed position that covers the upper surface of the 2D liquid crystal display panel 11 that is mounted and fixed to the panel housing portion of the θ table plate 40 and an open position that opens the upper space of the 2D liquid crystal display panel 11. It can be opened and closed. In the center of the holding frame 57, a barrier accommodation port 59 having an approximately rectangular opening slightly larger than the barrier 13 is opened. Contact avoidance grooves 59A are provided at various locations on the periphery of the barrier housing port 59 so that the barrier 13 can be attached and detached smoothly. As shown in FIG. 7, in a state where the holding frame 57 is closed, a barrier fixture 60 that positions and fixes the barrier 13 to the barrier accommodation port 59 by pressing the barrier 13 in the upper right direction is provided on the lower left side. ing. The barrier fixture 60 is configured by a link mechanism similar to the panel fixture 53 described above.

  As shown in FIGS. 2 and 6, a pair of left and right coordinate detection cameras 31 and 32 are provided on the upper side of the apparatus main body 35. The coordinate detection cameras 31 and 32 have a magnification of about 50 times and are capable of enlarging and detecting a coordinate displacement between the 2D liquid crystal display panel 11 and the barrier 13. For example, a CCD sensor or a CMOS sensor is used. It is configured. The image signals from the coordinate detection cameras 31 and 32 are transmitted to the monitors 33 and 34 installed at positions where the operator of the assembling apparatus 30 can visually recognize, and the state of the 2D liquid crystal display panel 11 and the barrier 13 is in real time. Is displayed. These coordinate detection cameras 31 and 32 are detected from a detection position (position shown in FIGS. 7 and 11B) at which the 2D liquid crystal display panel 11 and the upper left and right upper portions of the barrier 13 can be detected, and a position above the barrier 13. By retreating, it is possible to move between retraction positions (positions shown in FIG. 11A) to avoid interference caused by the opening / closing operation of the holding frame 57.

That is, the coordinate detection cameras 31 and 32 are supported by the camera position switching support mechanism 61. The position switching support mechanism 61 includes a rail member 62 extending from the side of the coordinate detection camera 31 and drive mechanisms 64A and 64B that move in the front-rear direction by driving the motors 63A and 63B. The motors 63A and 63B are driven by the operation of the left set button S3-1 and the right set button S3-2 provided respectively on the lower left and right sides on the front side (operator side) of the apparatus main body 35, and the coordinate detection cameras 31 and 32 are driven. Move between the detection position and the retracted position.
In addition to power being supplied to the control mechanism 65 provided between the two coordinate detection cameras 31, 32, the switches S1, S2, S3-1, S3-2, S4, S5 and the two cables C1- 1 and C1-2 are connected to receive signals from these switches and cables and perform control assigned to each switch and cable.

  Details of each switch and cable are as follows: power switch S1 for coordinate detection camera, LCD backlight lighting switch S2, left set button S3-1, right set button S3-2, reset button S4, LCD backlight off switch S5, They are the left coordinate detection camera cable C1-1 and the right coordinate detection camera cable C1-2. The coordinate detection camera power switch S1 is provided on the upper surface of the holding frame receiving portion 66 provided in the apparatus main body 35, and is turned on when the holding frame 57 reaches the closed position. With the switch S1 turned on, power can be supplied to the motors 63A and 63B by operating the set buttons S3-1 and S3-2, and the retraction position and the detection position of the coordinate detection cameras 31 and 32 can be moved. It becomes possible. On the other hand, at the position where the holding frame 57 is opened, the switch S1 is in an off state, power is not supplied to the motors 63A and 63B, and the coordinate detection cameras 31 and 32 cannot move from the retracted position to the detection position. . In this way, contact between the holding frame 57 and the coordinate detection cameras 31 and 32 is avoided.

Similarly, the LCD backlight lighting switch S2 is provided on the upper surface of the holding frame receiving portion 66. The LCD backlight lighting switch S2 is turned on when the holding frame 57 reaches the closed position, and power is supplied to the 2D liquid crystal display panel 11 and the backlight is turned on. The light comes on. Note that a 3D display alignment operation between the 2D liquid crystal display panel 11 and the barrier 13, which will be described later, is performed with the backlight turned on. The LCD backlight extinction switch S5 is a switch for extinguishing the backlight.
The left set button S3-1 and the right set button S3-2 are switches that move the coordinate detection cameras 31, 32 from the retracted position to the detected position. The buttons S3-1 and S3-2 can be operated only when the coordinate detection camera power switch S1 is on (that is, the holding frame 57 is in the closed position). The reset button S4 is a switch for moving both the coordinate detection cameras 31, 32 from the detection position to the retracted position.
The coordinate detection camera cables C1-1 and C1-2 are used to supply power to the coordinate detection cameras 31 and 32 and exchange image signals.

<Procedure for positioning the 2D liquid crystal display panel and the barrier by the display position alignment device>
Next, a procedure for aligning the 2D liquid crystal display panel 11 and the barrier 13 with each other in the 3D display position / condition using the display position aligning device 30 configured as described above will be described.
First, power is supplied to the display position alignment device 30 to set an initial state (that is, a state in which both coordinate detection cameras 31 and 32 are in the retracted position and the holding frame 57 is in the open position). Here, the rear frame case 12 containing the 2D liquid crystal display panel 11 is attached to the panel housing portion 52 provided on the θ table plate 40, and the handle portions 54 of the panel fixtures 53A and 53B are rotated to the right. The 2D liquid crystal display panel 11 (more specifically, the rear frame case 12 and the 2D liquid crystal display panel 11) is positioned and fixed. Here, a connector for supplying power to an LCD backlight (not shown) and a power connector (not shown) provided in the display position alignment device 30 are connected.
Next, after the holding frame 57 is closed from the open position to the closed position, the barrier 13 is attached to the barrier accommodation port 59, and the barrier 13 is positioned and fixed by operating the barrier fixture 60. When the holding frame 57 reaches the closed position, the LCD backlight lighting switch S2 is turned on and the backlight of the 2D liquid crystal display panel 11 is turned on. At the same time, the coordinate detection camera power switch S1 is turned on, and the coordinate detection cameras 31 and 32 can be moved.

Next, the left and right set buttons S3-1 and S3-2 are operated to drive the motors 63A and 63B to move the two coordinate detection cameras 31 and 32 from the retracted position to the detected position. When the coordinate detection cameras 31 and 32 reach the detection positions, the image signals from both the cameras 31 and 32 are enlarged and displayed on the monitors 33 and 34. At this detection position, the 2D liquid crystal display panel 11 and the upper left and right ends of the barrier 13 are set to be displayed.
16 and 17, the 2D liquid crystal display panel 11 displayed on the monitors 33 and 34 (in which a vertically long RGB pixel is lit) and the barrier 13 (black in an oblique staircase shape) are shown. Stuff). In this embodiment, the position of the barrier 13 is fixed, and the position of the 2D liquid crystal display panel 11 positioned below is finely corrected.

  The allowable degree of rattling with respect to the fixed position of the rear frame case 12 and the fixed position of the barrier 13 at the design time is about 1 to 2 mm. For this reason, the positional deviation in the initial state when the 2D liquid crystal display panel 11 and the barrier 13 are installed is about several hundred μm at the maximum. Each pixel of the 2D liquid crystal display panel 11 has a size of about 50 μm × 200 μm. In the initial state of FIG. 16A, the size is about 400 in the vertical direction (Y-axis direction in this embodiment). There is a positional shift of about 250 μm in the lateral direction (X-axis direction in the present embodiment) of ˜500 μm. Further, the right end portion has an upward inclination of about 200 μm as compared with the left end portion.

Hereinafter, an example of an operation procedure of the display position alignment device 30 will be described with reference to FIGS. 16 and 17, but according to the present invention, the positioning procedure is not limited to this method.
From the initial position shown in FIG. 16A, the X coordinate adjuster 48 is operated to move the 2D liquid crystal display panel 11 leftward on the X axis (horizontal axis), and the left edge of the barrier 13 and the 2D liquid crystal display panel 11 are moved. And the left and right edges of the two members 11 and 13 are temporarily aligned with the X-axis (FIG. 16B). Next, the Y coordinate adjuster 47 is operated to move the 2D liquid crystal display panel 11 downward in the Y axis (vertical axis), and below the upper edge of the barrier 13 and the first row of RGB pixels of the 2D liquid crystal display panel 11. The two members 11 and 13 are temporarily aligned with the Y-axis (FIG. 16C).
Next, the θ coordinate adjuster 49 is operated to rotate the 2D liquid crystal display panel 11 in the direction in which the right side is lowered (right direction), so that the upper edge of the barrier 13 is an RGB pixel on the left and right monitors 33 and 34. The barrier pattern and the RGB pixel are set to the horizontal position (the main adjustment θ plane angle alignment: FIG. 17A).

Next, the Y coordinate adjusting tool 47 is operated to move the 2D liquid crystal display panel 11 downward in the Y-axis (vertical axis) to align the upper edge of the barrier 13 with the upper edge of the RGB pixel, and both members 11 , 13 are aligned with the final adjustment Y axis (FIG. 17B).
Finally, the X coordinate adjustment tool 48 is operated to move the 2D liquid crystal display panel 11 to the left of the X axis (horizontal axis) to align the left edge of the barrier 13 with the left edge of the 2D liquid crystal display panel 11. The both members 11 and 13 are aligned with the final adjustment X-axis (FIG. 17C). Thus, the positions of the 2D liquid crystal display panel 11 and the barrier 13 are aligned, and the adjustment operation is completed when the 3D display position is reached.
In this embodiment, after the adjustment work, the reset button S4 is pressed to move the two coordinate detection cameras 31, 32 to the retracted position, and the barrier fixture 60 is released in a state where the barrier 13 does not move, and the holding frame After rotating 57 to the open position, the barrier 13 is pressed and pressed to fix the position. Further, the front frame case 14 is placed on the rear frame case 12 from above the barrier 13, and a bolt (not shown) is turned around the bolt hole 14A and the boss 12A to complete the assembly of the liquid crystal display device 11. .
As described above, according to the present embodiment, it is possible to provide the display position alignment device 30 that adjusts the 2D liquid crystal display panel 11 and the barrier 13 to the 3D display position / condition quickly and easily and with high accuracy.

Second Embodiment: Configuration of Display Position Matching Device
Next, a display position alignment apparatus 80 according to the second embodiment of the present invention will be described with reference to FIGS. The main difference from the first embodiment is a positioning coordinate device 81 provided with X, Y, θ table plates combined in one outer body, and a camera position switching support mechanism 82 for the coordinate detection cameras 31, 32. . For this reason, about the structure which show | plays the same effect | action as 1st Example, the same code | symbol is attached | subjected and description is abbreviate | omitted.
In the center of the display position aligning device 80, a positioning coordinate device 81 is provided that is provided with a Y table plate, an X table plate, and a θ table plate assembled in the outer body. A Y coordinate adjuster 47 projects in the right direction on the front surface of the positioning coordinate device 81, an X coordinate adjuster 48 projects in the rear direction on the right surface, and a θ coordinate adjuster 49 projects in the left direction on the left surface. Yes. Further, on the upper surface of the positioning coordinate device 81, a support base 85 is provided which is fixed to the uppermost θ table plate and interlocks with the θ table plate. On the lower surface side of the support base 85, a support base 86 that supports the support base 85 around the positioning coordinate device 81 is erected. A ball bearing that makes point contact with the support table 86 is provided at the upper end of the support table 86.

In addition, as shown in FIG. 20, a pair of coordinate detection cameras 31 and 32 are provided on the upper left and right in the plan view of the display position matching device 80. The coordinate detection cameras 31 and 32 are provided with camera position switching support mechanisms 82 and 82 that rotate about 90 degrees rightward or leftward. The camera position switching support mechanism 82 is provided with a motor 83 that rotates by a predetermined angle, and a support shaft 84 that connects the motor 83 and the coordinate detection cameras 31 and 32. In the retracted position shown in FIG. 20, the support shaft 84 is directed rightward so that the interference between the coordinate detection cameras 31 and 32 and the holding frame 57 is avoided. On the other hand, at the detection position indicated by the dotted line in FIG. 20, the support shaft 84 rotates about 90 degrees to the right by driving the motor 83, and the positional deviation between the 2D liquid crystal display panel 11 and the barrier 13 is detected at the upper left and right ends. . Thus, the coordinate detection cameras 31 and 32 can be rotated between the retracted position and the detected position by driving the motor 83.
A handle protrudes from the central portion of the holding frame 57 on the free end side, and an iron electromagnetic attaching / detaching portion 57A is provided at the center of the handle. On the other hand, in the holding frame receiving portion 66, an electromagnet 66A having a solenoid is provided at a portion where the electromagnetic attaching / detaching portion 57A hits when the holding frame 57 is set to the closed position. Energization of the electromagnet 66A is linked to the switches S3-1 and S3-2 that move the coordinate detection cameras 31 and 32 from the retracted position to the detected position. That is, when the switches S3-1 and S3-2 are turned on, the coordinate detection cameras 31 and 32 are rotationally moved to the detection positions, the electromagnet 66A is energized, and the electromagnetic attaching / detaching portion 57A is locked. The holding frame 57 is fixed at the closed position. When the reset button S4 is pressed, the coordinate detection cameras 31 and 32 are rotated to the retracted position, the energization to the electromagnet 66A is stopped, and the holding frame 57 is unlocked. Thus, the holding frame 57 is prevented from being accidentally opened to the open position during the operation of the 3D display position / condition.
According to the second embodiment configured as described above, the same operations and effects as the first embodiment are achieved. In the second embodiment, a compact and integrated positioning coordinate device 81 is used, so that the 2D liquid crystal display panel 11 and the barrier 13 can be matched to the 3D display positions and conditions even in a small work space. Can work. Furthermore, since the holding frame 57 is locked at the closed position as the coordinate detection cameras 31 and 32 move to the detection position, an erroneous opening operation of the holding frame can be prevented.

DESCRIPTION OF SYMBOLS 10 ... Liquid crystal display device (3D liquid crystal panel), 11 ... 2D liquid crystal display panel, 13 ... Barrier (display conversion perspective board), 30 ... Display position alignment apparatus, 31, 32 ... Coordinate detection camera, 33, 34 ... Monitor, 35 ... Main body, 36 ... Horizontal substrate, 37 ... Positioning coordinate device, 38 ... Y table plate, 39 ... X table plate, 40 ... θ table plate, 47 ... Y coordinate adjuster, 48 ... X coordinate adjuster, 49 ... θ Coordinate adjustment tool, 52... Panel housing portion, 53A, 53B .. panel fixing tool, 57 .. holding frame, 59 .. barrier housing port, 60 .. barrier fixing tool, 61 ... camera position switching support mechanism, 80. 81 ... Positioning coordinate device, 82 ... Camera position switching support mechanism

Claims (2)

A display position matching device of a liquid crystal display device of a 3D liquid crystal panel that is placed on a work table and adjusts and matches the 3D display position and conditions to each other while visually checking the 2D liquid crystal display panel and the display conversion see-through panel on a monitor. There,
An apparatus main body horizontally held on the upper surface of the work table, and a positioning coordinate device installed on a horizontal substrate of the apparatus main body are provided. The positioning coordinate device includes a Y table plate and an X table in order from the bottom. A plate and a θ table plate are provided in a three-stage configuration, and the uppermost θ table plate has a panel housing portion for housing the 2D liquid crystal display panel, and the 2D liquid crystal display panel is positioned and fixed in the panel housing portion. Panel fixing tool to be provided,
The Y table plate is slidable in the Y direction with respect to the apparatus body, the X table plate is slidable in the X direction with respect to the Y table plate, and the θ table plate is the X table plate. A Y coordinate adjuster that adjusts the position of the horizontal board by sliding the Y table board in the Y direction is provided on the horizontal board. An X coordinate adjuster that adjusts the position by sliding the X table plate in the X direction is provided, and the X table plate is provided with a θ coordinate adjuster that adjusts the position by rotating the θ table plate. And
The apparatus main body is provided with a holding frame for positioning for holding the display conversion see-through display panel in a separable manner so as to be openable and closable with a cantilevered fulcrum.
When positioning the 2D liquid crystal display panel and the display conversion see-through panel, the plane coordinates of the lower 2D liquid crystal display panel with respect to the upper display conversion see-through board at a fixed position above the θ table plate. A coordinate detection camera for enlarging and detecting an image position shift and sending an image signal to the monitor; a retreat position for retracting the coordinate detection camera from a position above the display conversion perspective board; and a detection position above the display conversion perspective board. A display position matching device for a liquid crystal display device, characterized in that a camera position switching support mechanism movable between the two is provided. 2. The display position alignment of the liquid crystal display device according to claim 1, wherein the Y table plate, the X table plate, and the θ table plate are positioning coordinate units that are provided in one outer body. apparatus.

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