JP2013200495A - Array type display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an array type display device capable of displaying a good image high in continuity while substantially reducing the visual recognition of a non-display area between the display devices.SOLUTION: An array type display device 100 is formed by arranging a plurality of display devices 10A to 10D. The plurality of display devices 10A to 10D is configured to provide transparent plates 20A to 20D to an observer side, respectively. These transparent plates 20A to 20D are arranged close to the adjoining transparent plates and located on the surface of display devices 10A to 10D which is a position corresponding to the outer peripheral portion close to the non-display portions 12A to 12D of the display portions 11A to 11D. The array type display device 100 includes: incident side deflection portions 24A to 24D for deflecting at least a part of light beams emitted from the display portions 11A to 11D to the non-display portions 12A to 12D side; and irradiation side deflection portions 22A to 22D provided at the outer peripheral portion of the observer side surface which is a position corresponding to at least non-display portions 12A to 12D so as to deflect and emit the light beams to the center side of the display portions 11A to 11D.

Description

  The present invention relates to an array type display device in which a plurality of display devices are arrayed to form a display screen.

A rear projection type display device, a plasma display device, a liquid crystal display device, an organic EL (Electro-Luminescence) (organic LED (light-emitting diode)) display device, etc. are arranged to expand the screen size. Widely used in digital signage and control monitoring that require large display screens of several tens of inches or more.
With respect to such an array type display device, in order to display a better image, the weather resistance of the screen, the flatness of the screen, the improvement of visibility, and the like are achieved (for example, see Patent Documents 1 and 2). ).

JP 2007-192977 A JP 2000-122571 A

However, for example, a rear projection type display device requires a frame structure for holding a rear projection type screen. In a plasma display device, a liquid crystal display device, and an organic EL display device, the display unit of the display device is made of glass. Since it is a panel, a frame structure for holding the panel is necessary.
Therefore, these frame structures and the like cause a non-display area in which no image can be displayed in the peripheral portion of the display device in any display device. When these are arranged on a plane to constitute an array type display device, a frame-like joint portion (joint portion) is formed between the display devices due to a non-display area where an image cannot be displayed. Since the video image is not displayed at the joint portion between the display devices, there is a problem that the image continuity is lowered and the image quality is lowered.
In plasma display devices, liquid crystal display devices, organic LED display devices, and the like, it is also considered that the holding member is bonded to the end face of the panel of the display unit to reduce the width of the holding member as much as possible to reduce the non-display area. . However, in these display devices, since electrodes must be arranged in the peripheral portion, even in such a configuration, a non-display area is generated on the order of several millimeters, and image continuity is not improved.

In patent document 1, the method of arrange | positioning organic LED on a joint part is disclosed. However, since an electrode is required in the peripheral part of the organic LED, the electrode part actually becomes a non-display area. Moreover, the structure disclosed in Patent Document 1 has a complicated structure, which causes an increase in production cost.
Patent Document 2 discloses a technique for reducing the width of a seam portion serving as a non-display area by devising electrodes and wiring such as FED (Field Emission Display). However, since there is a non-display area caused by a sealant, side connection wiring, or the like, improvement of screen continuity is insufficient.

  An object of the present invention is to provide an array type display device capable of displaying a good image with significantly reduced visibility of a non-display area between display devices, high image continuity.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.
The invention of claim 1 is an array type display device formed by arraying a plurality of display devices (10A to 10D), and each of the plurality of display devices includes a display unit (11A to 11A) capable of displaying an image. 11D) has a non-display portion (12A to 12D) that does not display an image on the outer peripheral side, and each of the plurality of display devices covers the display portion and the non-display portion closer to the viewer than the display portion. Transparent plates (20A to 20D) that are arranged in contact with adjacent transparent plates, are surfaces on the display device side, and viewed from the front direction of the display device. A light incident side deflection unit (24A to 24D, 44A) provided at a position corresponding to an outer peripheral portion close to the non-display unit and deflecting at least a part of the light emitted from the display unit to the non-display unit side; The outer periphery of the observer side surface, A light output side deflection unit (22A to 22D, 42A) provided at least in a position corresponding to the non-display unit when viewed from the front direction of the display device and configured to deflect the light toward the center of the display unit and emit light; It is an arrangement type display device (100) characterized by comprising.
According to a second aspect of the present invention, in the array type display device according to the first aspect, the light output side deflection section (22A to 22D, 42A) is formed of a curved surface or a plurality of inclined surfaces that are convex toward the viewer side. The light exit side deflection unit is located on the display device (10A to 10D) side in the thickness direction on the outer peripheral side compared to the inner peripheral side of the transparent plate, and the tangential plane of the curved surface or the inclined surface is the The angle formed with the display surface of the display unit gradually increases toward the outer peripheral side, and at least part of the light emitted from the light output side deflection unit proceeds in a direction perpendicular to the display surface of the display unit. An array type display device (100) characterized by the following.
According to a third aspect of the present invention, in the array type display device according to the first or second aspect, the light incident side deflection sections (24A to 24D, 44D) are a curved surface or a plurality of curved surfaces that are convex toward the viewer side. The light incident side deflection section is located on the display device (10A to 10D) side in the thickness direction in the thickness direction compared to the inner peripheral side of the transparent plate, and the tangential plane of the curved surface, Alternatively, the array type display device (100) is characterized in that an angle between the inclined surface and the display surface of the display unit gradually increases toward the outer peripheral side.

According to a fourth aspect of the present invention, in the array type display device according to any one of the first to third aspects, the width of the light exit side deflection section (22A to 22D, 42A) is W1, and the light incident is performed. When the width of the side deflection section is W2, the area (A) corresponding to the light incident side deflection sections (24A to 24D, 44D) of the display section as viewed from the front direction of the display sections (11A to 11D). The array-type display device (100) is characterized in that the image displayed on the screen is reduced by a factor of W2 / W1 with respect to the image displayed in the area of the display unit other than the area.
According to a fifth aspect of the present invention, in the array type display device according to the fourth aspect, the luminance of the image displayed in the area (A) is W1 of the luminance of the image displayed by the area of the display unit other than the area. This is an array type display device (100) characterized by being / W2 times.
A sixth aspect of the present invention is the array type display device according to any one of the first to fifth aspects, wherein the side surfaces of the transparent plates (20A to 20D) and the display portions (11A to 11D) are displayed. In the cross section perpendicular to the plane, the point on the light emitting side deflection section (22A to 22D, 42D) closest to the display device in the thickness direction of the transparent plate is defined as a point T1, and the light incident side deflection section (24A to 24A to 24D, 44D) is a point T2 that is the most outer peripheral side, a plane that passes through the point T2 and is parallel to the display surface of the display unit, and a straight line that passes through the point T1 and is perpendicular to the display surface of the display unit. The intersection point is a point T3, the distance between the point T1 and the point T3 is H, the distance between the point T2 and the point T3 is W, and the light incident on the point T2 is transmitted through the transparent plate and passes through the transparent plate. Outgoing from the point T1 in the normal direction of the display surface of the display unit The angle between the light and the plane parallel to the display surface in the transparent plate is θ (0 ° ≦ θ ≦ 90 °), and satisfies the relationship H = W × tan θ. This is a featured array type display device (100).

  According to the present invention, the visibility of the non-display area between the display devices is greatly reduced, the image continuity is high, and a good image can be displayed. In addition, it is possible to easily configure an array type display device that can display such a good image.

It is a figure explaining the array type display apparatus 100 of embodiment. It is a figure explaining the display apparatus 10A and the transparent plate 20A with which the arrangement type display apparatus 100 of embodiment is equipped. It is sectional drawing of the arrangement type display apparatus 100 of embodiment. It is a figure explaining in detail about the shape of light exit side deflection part 22A and light entrance side deflection part 24A of an embodiment. It is a figure explaining the dimension H in the outer peripheral side edge part of 20 A of transparent plates of embodiment. It is a figure explaining the expansion ratio of the image displayed on 22 A of light emission side deflection | deviation parts of embodiment. It is a figure explaining the design method of light output side deflection | deviation part 22A and light incidence side deflection | deviation part 24A of embodiment. It is a figure explaining the array type display apparatus 100 of another embodiment. It is a figure which shows the deformation | transformation form of transparent board 20A-20D. It is a figure explaining the deformation | transformation form of the array type display apparatus. It is a perspective view which shows the conventional arrangement type display apparatus 90. FIG. It is a figure which shows the structure of display apparatus 90A (90A1-90A3) used for the conventional arrangement type display apparatus 90. FIG. It is a figure which shows an example of the shape of light emission side deflection | deviation part 22A and light incidence side deflection | deviation part 24A of embodiment.

Embodiments of the present invention will be described below with reference to the drawings. In addition, each figure shown below including FIG. 1 is the figure shown typically, and the magnitude | size and shape of each part are exaggerated suitably for easy understanding.
Further, the terms “plate”, “sheet”, “film” and the like are generally used in the order of thickness, “plate”, “sheet”, “film”, and are also used in this specification. However, there is no technical meaning for such proper use, so the terms of sheets, plates, and films can be replaced as appropriate.
Furthermore, numerical values such as dimensions and material names of each member described in the present specification are examples of the embodiment, and the present invention is not limited thereto, and may be appropriately selected and used.

(Conventional array type display device)
First, a conventional array type display device will be described.
FIG. 11 is a perspective view showing a conventional array display device 90. A conventional array type display device 90 shown in FIG. 11 has a display screen having a rectangular shape and four display devices 90A, 90B, 90C, and 90D having the same size, and a display unit capable of displaying these images. Two pieces are arranged vertically and horizontally so that 91A, 91B, 91C, and 91D are positioned on one plane.
As the display devices 90A to 90D, a rear projection display device, a plasma display device, a liquid crystal display device, an organic EL display device (organic LED display device), and other display devices are used. Further, the number of display devices forming the array type display device 90 is not limited to four as shown in FIG. 11, but may be two, six, eight, or the like.

FIG. 12 is a diagram showing a configuration of a display device 90A (90A1 to 90A3) used in the conventional array display device 90. As shown in FIG. In FIG. 12, only the display device 90A (90A1 to 90A3) is shown as a representative, and a part of a cross section parallel to the normal direction is shown on the display screen (display unit 91A) of the display device 90A (90A1 to 90A3). ing.
12A shows an example in which a rear projection display device is used as a display device, and FIG. 12B shows a plasma display device, a liquid crystal display device, and an organic EL display device (organic LED display device) as the display device. FIG. 12C illustrates an example in which a shape different from that of FIG. 12B, such as a plasma display device, a liquid crystal display device, and an organic EL display device (organic LED display device) used as a display device. An example is shown.
As shown in FIG. 12A, the display device 90 </ b> A <b> 1 that is a rear projection display device includes a frame structure 92 for holding the rear projection screen 91. The peripheral portion of the viewer side surface of the rear projection screen 91 is covered with a frame member 92 a on the viewer side of the frame structure 92. Therefore, the area becomes a non-display part (seam part) where an image cannot be displayed.

Further, as shown in FIG. 12B, the display device 90 </ b> A <b> 2 that is a plasma display device, a liquid crystal display device, an organic EL display device or the like includes a frame structure 94 for holding the display panel 93. The peripheral surface of the observer-side surface of the display panel 93 is covered with the observer-side frame member 94a of the frame structure 94, and the region becomes a non-display part (seam part).
Further, as shown in FIG. 12C, a display device 90A3 such as a plasma display device, a liquid crystal display device, or an organic EL display device has a holding member 96 adhered to the end face of the display panel 95, and the width of the holding member 96 is increased. It is set as the structure which narrows. However, in the display panel 95, it is necessary to provide a region 97 in which an electrode part, a wiring part, and the like are provided at the peripheral part. Therefore, the portion that becomes the region 97 becomes a non-display portion.

Therefore, as shown in FIG. 11, non-display portions 92 </ b> A to 92 </ b> D that cannot display images exist on the outer peripheral sides of the display portions 91 </ b> A to 91 </ b> D of the display devices 90 </ b> A to 90 </ b> D.
When an image is displayed on such a conventional array-type display device 90, the non-display portions 92A to 92D between the display devices 90A to 90D are recognized as dark lines like a joint, and the continuity and visibility of the image are remarkably increased. There is a problem that image quality is deteriorated.
The present invention improves this, and provides an array type display device having image continuity and good visibility.

(Embodiment)
FIG. 1 is a diagram illustrating an array type display device 100 according to this embodiment.
FIG. 2 is a diagram illustrating the display device 10A and the transparent plate 20A included in the array display device 100 of the present embodiment. FIG. 2A is a view showing a cross section cut in parallel with the thickness direction of the array type display device 100 along the arrows A1-A2 shown in FIG. FIG. 2B is a plan view of the display device 10A as viewed from the front side on the viewer side. FIG. 2C is a plan view of the transparent plate 20A viewed from the front side of the observer, and FIG. 2D is a plan view of the transparent plate 20A viewed from the front side of the display device 10A. For ease of understanding, FIGS. 2B, 2C, and 2D show only the display device 10A and the transparent plate 20A as representatives, but other display devices 10B to 10D and transparent are shown. The plates 20B to 20D also have the same shape as the display device 10A and the transparent plate 20A.
The array display device 100 according to the present embodiment includes a display device unit 10 and a transparent plate unit 20. The transparent plate portion 20 is provided on the viewer side of the display device portion 10. In the present embodiment, the transparent plate portion 20 is interposed via a bonding layer (not shown) provided between the transparent plate portion 20 and the display device portion 10. The display device unit 10 is integrally joined. The joining layer that joins the transparent plate portion 20 and the display device portion 10 has high optical transparency, and the refractive index is the same as that of the transparent plate portion 20 (or is almost equal to no difference in refractive index), and is optically equivalent. It is preferable to use one.

As shown in FIG. 1, the display device unit 10 is a portion formed by arranging a plurality of display devices that display images. The display device unit 10 of the present embodiment is adjacent to each other such that the display devices 10A to 10D are positioned on a single plane on the observation side surfaces (display surfaces) of the display units 11A to 11D that can display the images. It is arranged.
Further, the display devices 10A to 10D are arranged two by two vertically and horizontally (the screen vertical direction and the screen horizontal direction of the array type display device in use). Note that the number of display devices forming the array type display device 100 can be changed according to the desired size of the screen size, and is not limited to four, but may be two, six, eight, or the like. It is good.

As shown in FIG. 2B, the display device 10A is a display screen that can display an image when viewed from the normal direction of the display surface of the display unit 11A (the front side on the observer side of the display device 10A). 11 A of display parts and the non-display part 12A which is located around the display part 11A and cannot display an image | video by a frame member, an electrode part, etc. are included.
In the present embodiment, the display portion 11A has a substantially rectangular shape, and the non-display portion 12A is located adjacent to the display portion 11A on the outer peripheral side thereof. Although the display device 10A has been described, the other display devices 10B to 10D have the same shape.
The display devices 10A to 10D may be a plasma display device, a liquid crystal display device, an organic EL display device (organic LED display device), or the like, or a rear projection display device.

The transparent plate portion 20 is a transparent substantially flat plate-like member disposed on the viewer side of the display screen of the display device portion 10. As shown in FIG. 1, the transparent plates 20 </ b> A to 20 </ b> D are arranged so that two transparent plates 20 </ b> A to 20 </ b> D are arranged adjacent to each other vertically and horizontally (the screen vertical direction and the screen horizontal direction of the array type display device in use). It is flat.
The transparent plates 20 </ b> A to 20 </ b> D of the transparent plate portion 20 are preferably formed using a highly light transmissive member, and preferably a transparent member. As materials for the transparent plates 20A to 20D, polycarbonate (PC) resin, acrylic resin, styrene resin, olefin resin, glass, ceramic, and the like can be appropriately selected and used. Further, the transparent plates 20A to 20D are formed by an injection molding method, a cast molding method, or the like using the above-described materials.

The transparent plates 20A, 20B, 20C, and 20D are disposed at positions corresponding to the display devices on the viewer side of the display devices 10A, 10B, 10C, and 10D, respectively. Further, when viewed from the front direction of the screen of the array-type display device 100, the sizes of the transparent plates 20A to 20D are equal to the sizes of the corresponding display devices 10A to 10D, respectively.
All of these transparent plates 20A to 20D are substantially flat members.
As shown in FIG. 2C, the surface on the observer side (light output side) of the transparent plate 20A includes a flat surface portion 21A and a light output side deflection portion 22A located on the outer peripheral side of the flat surface portion 21A. . Further, as shown in FIG. 2D, the surface of the transparent plate 20A on the display device unit 10 side (light incident side) is a flat surface portion 23A, and a light incident side deflection portion located on the outer peripheral side of the flat surface portion 23A. 24A, and a joining portion 25A provided in an area corresponding to the non-display portion 12A and located on the outer peripheral side of the light incident side deflection portion 24A.
As shown in FIG. 2A, the side surface 27A is parallel to the thickness direction and orthogonal to the plane portions 21A and 23A.
Although the transparent plate 20A has been described as an example, the other transparent plates 20B to 20D have the same shape.

  In the present embodiment, as shown in FIG. 1 and the like, the light exit side deflection units 22A to 22D are surfaces of the transparent plates 20A to 20D on the observer side when viewed from the front direction (the normal direction of the plane portions 21A to 21D). Are located at the upper and lower ends of the screen and the left and right ends of the screen. In addition, joints 25A to 25D are located at the upper and lower ends of the screen and the left and right ends of the screen on the display device 10 side of the transparent plates 20A to 20D, and adjacent to the inner peripheral side of the light incident side deflection unit. 24A to 24D are formed. Moreover, in this embodiment, as shown in FIGS. 1-3, the magnitude | sizes of the plane parts 21A-21D on the light emission side and the plane parts 23A-23D on the light incident side are slightly smaller than the display parts 11A-11D. It has a form.

FIG. 3 is a cross-sectional view of the array type display device 100 of the present embodiment. In FIG. 3, in order to enlarge a part of a cross section cut in parallel to the thickness direction of the array type display device 100 along the line A <b> 1-A <b> 2 shown in FIG. Only the plate 20A is shown, and the configuration of the display device 10A is greatly simplified. The cross section shown in FIG. 3 is a cross section that is adjacent to the light exit side deflection section 22A shown in the figure, and is orthogonal to the side face 27A parallel to the light exit side deflection section 22A and the display surface of the display section 11A. .
3 and FIGS. 4 to 7 described later, only the cross section of one side of the display device 10A and the transparent plate 20A is shown, but the four sides have the same shape. Further, in the following description, the display device 10A and the transparent plate 20A are described for ease of understanding. However, the display devices 10B to 10D and the transparent plate 20B are excluded unless otherwise specified. It is assumed that the shape is the same in -20D.

The light emitting side flat surface portion 21A of the transparent plate 20A is a surface parallel to the display surface (observer side surface) of the display portion 11A. The shape of the planar portion 21A viewed from the front direction is similar to the shape of the display surface of the display portion 11A, and is a rectangular shape in the present embodiment.
The light exit side deflection section 22A is provided adjacent to the plane section 21A on the outer peripheral side of the plane section 21A (see FIGS. 1 and 2A, 2C).
The light output side deflection unit 22A of the present embodiment is a curved surface convex toward the observer side, and a tangent plane at an arbitrary point on the surface is parallel to the display surface of the display unit 11A (parallel to the plane unit 21A). The angle γ2 formed with the surface) gradually increases toward the outer peripheral side of the transparent plate 20A.
Further, the light exit side deflection section 22A is formed so that the position on the outer peripheral side of the transparent plate 20A is positioned closer to the display device 10A than the inner peripheral side (plane section 21A side). In the cross section shown in FIG. 3, the point T1 that is the outermost peripheral side of the light output side deflection section 22A is located closest to the display device 10A in the thickness direction.

The light incident side flat portion 23A of the transparent plate 20A is a surface parallel to the viewer side surface of the display portion 11A. The shape of the planar portion 23A viewed from the front direction is similar to the shape of the display surface of the display portion 11A, and is a rectangular shape in the present embodiment.
The light incident side deflection section 24A is provided in a region adjacent to the outer peripheral side of the flat section 23A and corresponding to the outer peripheral edge of the display section 11A when viewed from the front of the display section 11A (FIG. 2 ( d)). The light incident side deflection unit 24A of the present embodiment is a curved surface convex toward the observer side, and a tangent plane at an arbitrary point on the surface is parallel to the display surface of the display unit 11A (parallel to the plane unit 23A). The angle [gamma] 1 formed with the smooth surface increases gradually toward the outer peripheral side.

The joining portion 25A is located on the outermost peripheral side of the surface on the display device 10A side of the transparent plate 20A, is located on the outer peripheral side of the light incident side deflection portion 24A, and is located in a region corresponding to the non-display portion 12A. It is provided so as to protrude toward the part 10 side. The surface on the display device section 10 side of the joint section 25A is parallel to the observer-side surface of the non-display section 12A.
The transparent plate 20A and the display device 10A are bonded to each other by bonding the bonding portion 25A and the non-display portion 12A via a bonding layer. At this time, as shown in FIGS. 2A and 3, an air layer 26 </ b> A is formed with a predetermined thickness between the light incident side deflection unit 24 </ b> A and the plane unit 23 </ b> A and the display unit 11 </ b> A.
In the present embodiment, the width of the light exit side deflection unit 22A in the cross section shown in FIG. 3 is W1, the width of the light entrance side deflection unit 24A is W2, and the width of the non-display unit 12A is W. In addition, the dimension in the thickness direction from the point T1 that is the outermost peripheral side (most display device 10A side) of the light output side deflection unit 22A to the bonding surface of the bonding unit 25A is H.

Here, the deflection action of the light exit side deflection unit 22A and the light entrance side deflection unit 24A will be described.
The light L0 emitted in the front direction (normal direction of the display surface) from the area corresponding to the flat part 23A of the display part 11A enters the flat part 23A and passes through the transparent plate 20A as shown in FIG. The light is emitted from the plane portion 21A in the front direction.
On the other hand, light L1 and L2 emitted perpendicularly to the display surface from the region A, which is the outer peripheral side (non-display unit 12A side) end of the surface of the display unit 11A and corresponding to the light incident side deflection unit 24A, In the cross section shown in FIG. 3, the light is incident on the light incident side deflection unit 24A, is refracted to the outer peripheral side at the interface between the air layer 26A and the light incident side deflection unit 24A, is transmitted through the transparent plate 20A, and the light output side deflection unit. Incident on 22A. The lights L1 and L2 are refracted at the interface between the light output side deflection unit 22A and the air, bent to the center side (display unit 11A side) of the display device 10A, and perpendicular to the surface of the display unit 11A. Go in the direction. For this reason, when this display device 10A is observed from the front side on the observation side, it is observed that an image is displayed on the entire transparent plate 20A, and the non-display portion 12A is not visually recognized.

Further, as described above, the light incident side deflection unit 24A has an angle γ1 that increases toward the outer peripheral side, so that the light that is emitted vertically from the display unit 11A and incident on the light incident side deflection unit 24A is As it enters the outer peripheral side of the light incident side deflection unit 24A, it is refracted to the outer peripheral side (non-display unit side) and passes through the transparent plate 20A. Further, as described above, the angle γ2 of the light exit side deflecting unit 22A increases toward the outer peripheral side, so that the light deflected to the outer peripheral side by the light incident side deflecting unit 24A is transmitted from the light output side deflecting unit 22A. As the light enters the outer peripheral side, the light is deflected more toward the display unit 11A and emitted in the normal direction (front direction) of the display surface.
From the above, since the image displayed in the area A is viewed as if it is enlarged and displayed on the light output side deflection unit 22A, the image observed through the transparent plate 20A is the entire area on the surface on the viewer side. Are recognized as a good image without a joint portion by the non-display portion 12A.

FIG. 4 is a diagram illustrating in detail the shapes of the light exit side deflection unit 22A and the light entrance side deflection unit 24A of the present embodiment. 4 and FIGS. 5 to 7 described later show the same cross section as the cross section shown in FIG.
The light L3 emitted perpendicularly to the surface (display surface) of the display unit 11A from the display unit 11A and incident on the light incident side deflection unit 24A is perpendicular to the display unit 11A from the light output side deflection unit 22A. In order to emit in the (front direction), the angle γ1 formed by the plane tangent to the incident point of the light incident side deflection unit 24A of the light L3 and the plane parallel to the display unit 11A is incident on the light output side deflection unit 22A of the light L3. It is desirable that the angle γ2 formed by the tangent plane of the point (exit point) to be made with the plane parallel to the display portion 11A is equal.
When γ1 = γ2 is satisfied, the refraction angle α1 of the light L3 at the light incident side deflection unit 24A is equal to the incident angle α2 at the light output side deflection unit 22A. Therefore, the incident angle β1 to the light incident side deflection unit 24A is equal to the emission angle β2 from the light output side deflection unit 22A, and the traveling direction (front direction) of the light L3 when entering the light incident side deflection unit 24A, The traveling direction of the light at the time of emission from the light output side deflection unit 22A becomes equal, and the light L3 is emitted in the front direction of the display surface.
Therefore, it is desirable to design the curves formed by the light incident side deflection unit 24A and the light output side deflection unit 22A in the cross section shown in FIG. 4 so as to satisfy γ1 = γ2, and to select the refractive index of the material of the transparent plate 20A. .

Further, from the viewpoint of improving the continuity of the image by reducing the visibility of the joint portion by the non-display portion 12A, it is preferable that the non-display portion 12A and the light output side deflection unit 22 have an appropriate distance.
FIG. 5 is a diagram for explaining the dimension H at the outer peripheral side end of the transparent plate 20A of the present embodiment.
In the cross section shown in FIG. 5, a boundary portion between the non-display portion 12A and the transparent plate 20A, that is, a point on the outermost peripheral side of the light incident side deflection portion 24A is defined as a point T2. An intersection of a plane passing through the point T2 and parallel to the display surface of the display unit 11A and a straight line passing through the point T1 and perpendicular to the display surface of the display unit 11A is defined as a point T3. At this time, the distance between the points T1 and T3 (in this embodiment, equal to the dimension in the thickness direction from the point T1 to the joint surface of the joint portion 25A) is H, and the distance between the points T2 and T3 (this embodiment) In this case, W is equal to the width of the non-display portion 12A.

When the light L4 incident on the point T2 passes through the transparent plate 20A and exits from the point T1 in the normal direction of the display surface of the display unit 11A, the light L4 transmitted through the transparent plate 20A is parallel to the display surface. When the angle formed with the surface is θ (0 ° ≦ θ ≦ 90 °), the dimension H preferably satisfies the following formula 1.
H = W × tan θ (Formula 1)
At this time, the angle θ is an angle ε formed by the normal line N of the tangent plane at the point T2 and a plane parallel to the display unit 11A, and is emitted from the display unit 11A in the normal direction and incident on the transparent plate 20A at the point T2. Is equal to the sum of the refraction angle α of the light L4 and θ = (ε + α).

When this (Equation 1) is satisfied, the light L4 emitted from the point T2 which is the outermost periphery of the display unit 11A is emitted from the point T1 which is the outermost side of the transparent plate 20A as shown in FIG. Therefore, an image is displayed on the entire transparent plate 20A, and the non-display portion 12A is not visually recognized.
Further, if this (Expression 1) is satisfied, the light emitted from the outer peripheral edge of the display unit 11 is not emitted from the adjacent transparent plate 20D, for example, but is displayed on the adjacent display device 10D or the like. Continuity with the image is not impaired. Therefore, an image that is no different from an image displayed on a single display device can be displayed by the array display device 100.

  Since the above-described conditions are satisfied, the array type display device 100 according to the present embodiment displays a continuous image over the entire surface on the observation side of each of the transparent plates 20A to 20D, and between the individual display devices 10A to 10D. The joint portions by the non-display portions 12A to 12D are not visually recognized. Therefore, the array type display device 100 according to the present embodiment can display an image that is not inferior to an image displayed on a single display device.

FIG. 6 is a diagram for explaining an enlargement ratio of an image displayed on the light output side deflection unit 22A of the present embodiment.
The image displayed in the region A of the display unit 11A that emits light incident from the direction parallel to the normal direction of the display surface of the display unit 11A with respect to the light incident side deflection unit 24A is other than that of the display unit 11A. It is desirable that the image is reduced than the image displayed in the portion.
The image displayed by the light emitted from the region A in the normal direction of the display surface is enlarged by the light incident side deflection unit 24A and the light output side deflection unit 22A. Therefore, the image displayed on the light output side deflection unit 22A is not stretched or contracted with respect to the image displayed on the flat surface part 21A, and the continuity is high over the entire surface of the observer side of the transparent plate 20A, and the distortion or the like. In order to display an image having no image, the image displayed in the area A needs to be reduced more than the image displayed in the other part. Therefore, it is preferable that the reduction ratio of the image displayed in the area A is a reciprocal of the enlargement ratio.

Here, the width of the region A and the plane perpendicular to the end surface 27A of the transparent plate 20A and the surface of the display unit 11A (that is, the width of the region A shown in FIG. 6 and the width of the light incident side deflection unit 24A). Is equal to W2. Further, the width of the light emitted in the front direction of the display surface from the light output side deflection unit 22A and the plane perpendicular to the end surface 27 of the transparent plate 20A and the display unit 11A (that is, the light output side deflection unit 22A shown in FIG. 6). Width) is W1. At this time, since the enlargement ratio is W1 / W2, the reduction ratio is desirably W2 / W1.
Furthermore, since the image displayed on the light output side deflection unit 22A is enlarged as described above, the luminance is reduced by W2 / W1 times compared to the luminance in the region A. Therefore, it is desirable that the luminance of the image displayed in the area A is set to be W1 / W2 times higher than the luminance of the image displayed on the other part of the display unit 11A. By setting it as such brightness | luminance, the brightness | luminance of the image displayed on 20 A of transparent plates becomes uniform on the whole.

When the image is magnified at the magnification as described above by the light exit side deflection unit 22A and the light entrance side deflection unit 24A, the image is evenly magnified regardless of the position in the width direction of the light exit side deflection unit 22A. Is preferred. A design method for the light exit side deflection unit 22A and the light entrance side deflection unit 24A will be described below so that an image is uniformly enlarged in the width direction of the light exit side deflection unit 22A and the light entrance side deflection unit 24A.
FIG. 7 is a diagram illustrating a design method of the light exit side deflection unit 22A and the light entrance side deflection unit 24A according to the present embodiment.
Generally, when designing a curve, it is possible to design the curve as a collection of minute line segments. Therefore, in the cross section as shown in FIG. 3 and the like, the curves indicated by the curved surfaces of the light exit side deflection unit 22A and the light entrance side deflection unit 24A are designed as an assembly of minute line segments.

First, a point T2 which is the outermost periphery of the light incident side deflection unit 24A is set as a starting point, and a point T2 = T2 (1) which is the outermost periphery is set. From this point T2 (1), an angle of γ1 (1) with a plane parallel to the display unit 11A is formed, and a straight line 24A (1) extending toward the display unit 11A side (inner side) is extended.
Here, if the angle γ1 (1) is too small, the distance H in the thickness direction between the point T2 and the point T1 becomes too large. If the angle γ1 (1) is too large, the light radiated from the display unit 11A in the direction perpendicular to the display surface and incident on the point T2 (1) and refracted is totally reflected by the light output side deflection unit 22A and observed. The light is not emitted to the side. Therefore, the angle γ1 (1) is preferably 50 to 70 °, more preferably around 60 °. In FIG. 7, it is shown as γ1 (1) = 65 °.

Next, the width W2 of the light incident side deflection unit 24A is divided into a predetermined number. At this time, it is preferable that the curve is not visually recognized as an assembly of line segments, but is recognized as a curve, and therefore, it is preferable to divide so that the dimension of one divided width is about 100 μm or less. Therefore, for example, when the value of the width W2 is about several mm, it is preferable that the width W2 is 100 or more.
Here, the length of one width obtained by dividing the width W2 is WP. A point advanced by WP parallel to the display unit 11A from T2 (1) to the display unit 11A side is defined as a point WA (2). It should be noted that WA (2) is used instead of WA (1) in order to make arguments (numbers in parentheses) of various amounts such as angles at the same point the same.
A straight line orthogonal to the display surface of the display unit 11A is extended from the point WA (2). The intersection of this straight line and the aforementioned straight line 24A (1) is defined as a point T2 (2). A line segment from the starting point T2 (1) of the light incident side deflection unit 24A is defined as a line segment 24A (1) connecting T2 (1) and T2 (2). In order to avoid complexity and facilitate understanding, a straight line and a minute line segment that is a part of the straight line will be described with the same reference numerals.

Next, the line segment on the outermost periphery side of the light output side deflection unit 22A is designed. First, the outermost peripheral point T1 (1) that is the starting point of the light exit side deflection unit 22A is determined by the angle γ1 (1) and the width W of the non-display unit 12A.
That is, the light emitted from the display unit 11A in the direction perpendicular to the surface of the display unit 11A and incident on the line segment 24A (1) is refracted by the line segment 24A (1) and is a plane parallel to the display unit 11A. And proceed in a direction that forms an angle θ (1) represented by the following equation. This angle θ (1) is expressed by the following equation, where N is the refractive index of the transparent plate 20A.
θ (1) = 90 ° −γ1 (1) + arcsin ((sin (γ1 (1))) / N)
Accordingly, the light emitted from the display unit 11A in the direction perpendicular to the display surface of the display unit 11A and incident on T2 (1) travels through the optical path indicated by the line segment K (1) in the transparent plate 20A. . Here, while the light travels by the width W of the non-display portion 12A on the outer peripheral side in the transparent plate 20A, the light exits the distance H in the direction perpendicular to the display surface of the display portion 11A. Proceed to At this time, the distance H is expressed by the following equation according to the above (Equation 1).
H = W × tan (θ (1))

A point advanced from the point T2 by a distance H in the direction perpendicular to the display unit 11A and a width W of the non-display unit 12A on the outer peripheral side is defined as a starting point T1 (1) of the light exit side deflection unit 22A.
Next, a line segment from the starting point T1 (1) of the light output side deflection unit 22A is determined.
As shown in FIG. 4 and the description thereof, the angle γ1 (1) and γ2 (1) are equal (γ1 (1) = γ2 (1)), so that a good image without distortion is displayed. To preferred. Here, the angles γ1 (1) and γ2 (1) are as follows.
Angle γ1 (1): The tangent plane at the incident point of the light emitted from the display unit 11A perpendicular to the display surface of the display unit 11A with respect to the incident-side deflection unit 24A is a plane parallel to the display surface of the display unit 11A. The angle to make.
Angle γ2 (1): An angle formed by a tangent plane at which the light is incident on the light exit side deflection unit 22A and a plane parallel to the display surface of the display unit 11A.

Accordingly, the straight line 22A (1) is extended from the point T1 (1) in a direction that forms an angle γ2 (1) that is the same angle as the angle γ1 (1). Next, a point advanced by the width WQ from the T1 (1) to the display unit side in a direction parallel to the display unit 11A is defined as a point WB (2).
This width WQ is expressed by the equation WQ = WP × W1 / W2. At this time, the magnification of the image displayed on the light exit side deflection unit 22A is W1 / W2. By satisfying this formula for the width WQ, the light incident on the entire width direction of the light incident side deflection section 24A can be emitted from the entire area in the width direction of the light output side deflection section 22A, and then emitted. An image without distortion can be displayed.
Then, a straight line is extended from the point WB (2) in a direction perpendicular to the display surface of the display unit 11A, and the intersection of the straight line and the straight line 22A (1) is defined as T1 (2), and the starting point T1 ( A line segment connecting 1) and T1 (2) is defined as a line segment 22A (1).

Next, a line segment 24A (2) extending from the point T2 (2) of the light incident side deflection unit 24A to the inner peripheral side is determined.
As described above, the magnification rate of the image displayed on the light output side deflection unit 22A is W1 / W2. Accordingly, the line 24A (2) is incident on the point T2 (2) so that the light refracted by the line 24A (2) extending next from the point T2 (2) is incident on the point T1 (2). You only have to set it.
Therefore, the light emitted from the display unit 11A in the direction perpendicular to the display surface of the display unit 11A is refracted by the line segment 24A (2), and the line segment K (connecting the point T2 (2) and the point T1 (2). What is necessary is just to set angle (gamma) 1 (2) and angle (theta) (2) so that it may follow the optical path shown by 2).
Accordingly, the straight line 24A (2) is extended in a direction that forms an angle γ1 (2) with a plane parallel to the display surface of the display unit 11A. At this time, when the angle formed by the light incident on the straight line 24A (2) and the plane parallel to the display unit 11A in the transparent plate 20A is θ (2) and the refractive index of the transparent plate 20A is N, the angle γ1 (2) and the angle θ (2) satisfy the following expression.
θ (2) = 90 ° −γ1 (2) + arcsin ((sin (γ1 (2))) / N)

Next, a point advanced from the point WA (2) by the width WP to the display unit side parallel to the display unit 11A is defined as a point WA (3), and a straight line extending vertically from the point WA (3) to the display unit 11A An intersection point with the straight line 24A (2) is defined as a point T2 (3), and a line segment connecting the point T2 (2) and the point T2 (3) is defined as a line segment 24A (2).
Thereafter, the line segment 22A (2) is determined from the line segment 24A (2), and the line segment 22A (1) is determined from the line segment 24A (1). Similarly to the determination of the line segment 24A (2), the line segment 24A (3) is determined from the line segment 22A (2).
Then, by repeating these steps and determining each line segment one after another, in the cross section shown in FIG. 3, an assembly of minute line segments corresponding to the light incident side deflection unit 24A and the light output side deflection unit 22A is obtained. Can do.
And in the cross section shown in FIG. 3, by making into the light-incidence side deflection | deviation part 24A and the light emission side deflection | deviation part 22A which are the curved surfaces which make the curve approximated with the aggregate | assembly of the minute line segment designed by the above-mentioned method, It is possible to display a good image in which the image is uniformly enlarged W1 / W2 times in the width direction.

FIG. 13 is a diagram illustrating an example of the shapes of the light exit side deflection unit 22A and the light entrance side deflection unit 24A according to the present embodiment.
FIG. 13 shows an example of an assembly of minute line segments that approximate the curves formed by the light exit side deflection unit 22A and the light entrance side deflection unit 24A in the cross section shown in FIG. The aggregate of these minute line segments is calculated by the above-described calculation method. FIG. 13A shows an assembly of minute line segments that approximate the curve formed by the light exit side deflection section 22A in the cross section shown in FIG. 3, and FIG. 13B shows the light incident in the cross section shown in FIG. It is an assembly of minute line segments that approximate the curve formed by the side deflection section 24A. In FIG. 13, the vertical axis indicates the dimension in the thickness direction of the transparent plate 20A when the width W of the non-display portion 12A is 3, and the horizontal axis indicates the light exit side deflection unit 22A and the light entrance side deflection unit 24A. The maximum value is 500.

The curve illustrated in FIG. 13 is calculated by the above calculation method under the following conditions.
The number of divisions of the width W2 of the light incident side deflection unit 24A (number of line segments 24A) 500 (that is, the number of divisions of the width W1 of the light emission side deflection unit 22A (number of line segments 22A) is also 500)
The angle γ1 (1) = 60 ° between the line segment 24A (1) and the plane parallel to the display unit at the starting point T2 (1) of the light incident side deflection unit 24A.
・ Magnification rate W1 / W2 = 3.0
-Refractive index 1.49 of transparent plate 20A
The ratio W / W2 = 2.0 of the width W of the non-display portion 12A and the width W2 of the light incident side deflection portion 24A.
In the cross section shown in FIG. 3, the light exit side deflection unit 22A emits light from the light exit side deflection unit 22A by using the light exit side deflection unit 22A and the light entrance side deflection unit 24A which show curves approximated by an assembly of line segments as shown in FIG. Light is emitted in the front direction, and a good array type display device with high image continuity without distortion can be obtained.

Since the array-type display device 100 includes the transparent plate portion 20 including the transparent plates 20A to 20D having the above-described shape and the display device portion 10 including the display devices 10A to 10D, the image continuity is high. It is possible to display a good image in which the non-display portion is not visually recognized.
Further, it is not necessary to form a complicated lens on the transparent plate, and the array type display device 100 capable of displaying a good image as described above can be easily configured.

FIG. 8 is a diagram illustrating an array type display device 100 according to another embodiment. FIG. 8 shows a cross section corresponding to the cross sections shown in FIGS.
In an array type display device 100 according to another embodiment, the light exit side deflection unit 42A and the light entrance side deflection unit 44A formed on the transparent plate 20A are not curved surfaces but from a plurality of inclined surfaces (planes) arranged in the width direction. It is the same form as the array type display device 100 of the first embodiment described above except that it is a bent plane.
Therefore, the same reference numerals or the same reference numerals are given to the portions that perform the same functions, and redundant descriptions are omitted as appropriate. In order to facilitate understanding, only the display device 10A and the transparent plate 20A will be described, but the other display devices 10B to 10D and the transparent plates 20B to 20D (not shown) have the same configuration.

As shown in FIG. 8, the light exit side deflection unit 42A and the light entrance side deflection unit 44A are configured by a plurality of planes (slopes), and each plane is a plane parallel to the display surface of the display unit 11A. The angles γ4 and γ3 are gradually increased toward the outer peripheral side in the width direction of the light exit side deflection unit 42A and the light entrance side deflection unit 44A.
Any of the shapes formed by the plurality of planes of the light exit side deflection unit 42A and the light entrance side deflection unit 44A can be approximated by a curved surface convex toward the viewer side.
Therefore, also in the case of the transparent plate portion 20 including the bent light-emitting side deflection unit 42A and the incoming side deflection unit 44A as in this embodiment, the aforementioned outgoing side deflection unit 22A and incoming side deflection unit 24A. The same effect as that of the array type display device 100 according to the embodiment including the transparent plate portion 20 including the above can be obtained.

(Deformation)
Without being limited to the embodiments described above, various modifications and changes are possible, and these are also within the scope of the present invention.
FIG. 9 is a diagram illustrating a modification of the transparent plates 20A to 20D.
FIG. 10 is a diagram for explaining a modification of the array type display device 100.
In FIGS. 9 and 10 and the following description, the transparent plate 20A and the display device 10A are shown as examples for easy understanding. However, in the transparent plates 20B to 20D and the display devices 10B to 10D, Is equally applicable.
(1) In each of the embodiments, the light exit side deflection units 22A and 42A and the light entrance side deflection units 24A and 44A are all curved surfaces, or all are formed of a plurality of planes (slopes). However, the present invention is not limited to this. For example, one of the light exit side deflection units 22A and 42A and the light entrance side deflection units 24A and 44A may have a curved surface shape and the other may have a bent surface shape.

(2) In each embodiment, the side surface 27A of the transparent plate 20A closer to the display device unit 10 than the light output side deflection units 22A and 42A is the normal line of the display surfaces (observer side surfaces) of the display units 11A to 11D. Although an example of a planar shape parallel to the direction has been shown, the present invention is not limited thereto, and may be a curved surface shape or a shape formed by combining a plurality of flat surfaces. In addition, a reflective layer or the like may be formed on the side surface 27A of the transparent plate 20A closer to the display device unit 10 than the light output side deflection unit 22A. The same applies to the other transparent plates 20B to 20D, and the same applies to the transparent plates 20A to 20D, which are another embodiment shown in FIG.
For example, as shown in FIG. 9A, a reflective layer 30 capable of reflecting light may be formed on the side surface 27A closer to the display device unit 10 than the light output side deflection unit 22A of the transparent plate 20A. By adopting such a shape, the light incident on the side surface 27A is reflected, and part of the light exits from the light exit side deflection unit 22A. Therefore, the visibility of the non-display part (seam part) can be further reduced. Image continuity can be improved.
The reflective layer 30 may have a concavo-convex shape on the side surface 27A side. In such a shape, since the light incident on the side surface 27A is diffusely reflected, the amount of light reflected by the side surface 27A and emitted from the light output side deflection unit 22A is increased, and image continuity is improved. Can be made.

Further, as shown in FIG. 9B, at least a part of the side surface 27A may be a slope 28A, or the reflective layer 30 may be formed on the slope 28A and the side face 27A.
Further, as shown in FIG. 9C, the side surface 27 </ b> A may be curved and the reflective layer 30 may be formed.
At this time, the bonding layer 35A may be formed as shown in FIGS. 9B and 9C to increase the degree of bonding between the transparent plate 20A and the display device 10A.
By adopting such a shape, it is possible to increase the light reflected from the side surface 27A and the inclined surface 28 and emitted from the light output side deflection unit 22A, and the continuity of the image can be improved. At this time, the reflective layer 30 may have an uneven shape on the side surface 27A side as described above.
In addition, although the example which shapes uneven | corrugated shape to the reflection layer 30 was mentioned as an example, it was not restricted to this, You may form uneven | corrugated shape in the side surface 27A and the slope 28A.

(3) In each embodiment, although the transparent plate part 20 showed the example in which several transparent plate 20A-20D was arranged adjacently, it was not restricted to this, and it was from one plate-shaped member. It may be formed. FIG. 10A is a diagram schematically showing a cross section corresponding to the cross section taken along arrow A1-A2 in FIG. 1 when the transparent plate portion 20 is a single plate-like member. By adopting such a shape, it becomes easier for the observer to recognize the display screen on which the video is displayed as one screen, and the continuity of the image can be further enhanced.

(4) In each embodiment, although the array type display device 100 has shown the example in which the display devices 10A to 10D and the transparent plates 20A to 20D are arranged in a planar shape, the present invention is not limited to this, for example, FIG. ), The display devices and the transparent plates may be arranged so that the display screens form an angle with each other. By adopting such a shape, the convenience and design of the array type display device can be improved, and an image display suitable for the application and environment can be performed for the observer O.

(5) In each embodiment, although the example where the display surfaces (observer-side surfaces) of the display units 11A to 11D of the display devices 10A to 10D are planar has been shown, the present invention is not limited thereto, and the display screen is a cylinder. A curved surface shape such as a planar shape or a spherical shape may be used. When setting it as such a form, transparent board 20A-20D (especially plane part 21A-21D, 23A-23D) should just be made into the shape which followed display part 11A-11D of display apparatus 10A-10D.

(6) Transparent plate 20A-20D is good also as a form which contains a spreading | diffusion agent inside according to the optical performance etc. which are desired suitably, and the mat | matte shape may be formed in the surface. Furthermore, layers having various functions such as an antiglare layer, an antireflection layer, a hard coat layer, an antifouling layer, an antistatic layer, an ultraviolet absorbing layer, and a touch panel layer are appropriately provided on the observer side of the transparent plates 20A to 20D. May be.

(7) In each embodiment, an example in which a plurality of display devices 10A to 10D are arranged as the array type display device 100 and the transparent plates 20A to 20D corresponding to the display devices 10A to 10D are arranged has been described. Even in a normal display device (for example, a device including one display device 10A), by providing the transparent plate 20A, it is possible to reduce the visibility of the non-display portion due to the frame member or the like.

  In addition, although the above-mentioned embodiment and modification can also be used in combination suitably, detailed description is abbreviate | omitted. In addition, the present invention is not limited to the embodiment described above.

DESCRIPTION OF SYMBOLS 100 Array type display apparatus 10 Display apparatus part 10A-10D Display apparatus 11A-11D Display part 12A-12D Non-display part 20 Transparent board part 20A-20D Transparent board 21A-21D Plane part 22A-22D, 42A Emission side deflection | deviation part 23A, 23D Plane part 24A, 24D, 44A Light incident side deflection part 25A Joint part 26A Air layer 27A Side surface

Claims (6)

An array type display device formed by arranging a plurality of display devices,
Each of the plurality of display devices has a non-display portion that does not display an image on the outer peripheral side of a display portion capable of displaying an image,
Each of the plurality of display devices includes a transparent plate covering the display unit and the non-display unit on the viewer side from the display unit,
Each of the transparent plates is
Arranged in contact with adjacent transparent plates,
At least one of the light emitted from the display unit, provided at a position corresponding to an outer peripheral part of the display unit side that is close to the non-display unit of the display unit when viewed from the front direction of the display device. A light incident side deflecting part for deflecting the part to the non-display part side,
An outer peripheral portion of the surface on the observer side, provided at least at a position corresponding to the non-display portion when viewed from the front direction of the display device, and emits light by deflecting the light toward the center side of the display portion A side deflection part;
Providing
An array type display device. The array type display device according to claim 1,
The light output side deflection unit is formed from a curved surface that is convex to the viewer side, or a plurality of inclined surfaces,
The light exit side deflection unit is positioned on the display device side in the thickness direction of the transparent plate, and the tangential plane of the curved surface or the inclined surface is the display of the display unit. The angle formed by the surface gradually increases toward the outer circumference,
At least part of the light emitted from the light exit side deflection unit travels in a direction perpendicular to the display surface of the display unit;
An array type display device. The array type display device according to claim 1 or 2,
The light incident side deflection section is formed from a curved surface that is convex to the viewer side, or a plurality of inclined surfaces,
The light incident side deflection unit has an outer peripheral side positioned on the display device side in the thickness direction of the transparent plate as compared to an inner peripheral side of the transparent plate, and a tangential plane of the curved surface or the inclined surface of the display unit The angle formed with the display surface gradually increases toward the outer circumference,
An array type display device. In the arrangement type display device according to any one of claims 1 to 3,
When the width of the light exit side deflection unit is W1, and the width of the light entrance side deflection unit is W2,
When viewed from the front direction of the display unit, the image displayed in the display unit region corresponding to the light incident side deflection unit is W2 with respect to the image displayed in the display unit region other than the region. / W1 reduction
An array type display device. The array type display device according to claim 4,
The brightness of the image displayed in the area is W1 / W2 times the brightness of the image displayed in the display area other than the area;
An array type display device. The array type display device according to any one of claims 1 to 5,
In a cross section orthogonal to the side surface of the transparent plate and the display surface of the display unit,
In the thickness direction of the transparent plate, the point closest to the display device side of the light output side deflection unit is a point T1,
A point that is the outermost peripheral side of the light incident side deflection unit is a point T2,
An intersection of a plane passing through the point T2 and parallel to the display surface of the display unit and a straight line passing through the point T1 and perpendicular to the display surface of the display unit is defined as a point T3.
The distance between the point T1 and the point T3 is H,
The distance between the point T2 and the point T3 is W,
When the light incident on the point T2 passes through the transparent plate and exits from the point T1 in the normal direction of the display surface of the display unit, the light is parallel to the display surface in the transparent plate. When the angle formed with the flat surface is θ (0 ° ≦ θ ≦ 90 °),
H = W × tan θ
Satisfying the relationship
An array type display device.

Images