JP5341162B2 - 3D image display device - Google Patents

Description

  The present invention relates to a three-dimensional display device, and more particularly to a three-dimensional video display device that displays a video displayed on a video display device as a three-dimensional video using a mirror.

  As a conventional three-dimensional video display device, a three-dimensional video display device in which a mirror assembly composed of a plurality of half mirrors is arranged in the video display device is known. For example, in Patent Document 1 and Patent Document 2, a virtual image generated by a half mirror from a video displayed on a two-dimensional video display device is simultaneously displayed on a plurality of display surfaces having different depth positions as viewed from the viewer. A three-dimensional video display device that generates a stereoscopic video is disclosed. For example, the three-dimensional display device described in Patent Document 1 has been proposed by the present inventor, and this three-dimensional display device is formed such that the heights of a plurality of half-meers are higher as they are closer to the viewer and lower toward the depth direction. By doing so, the image area is generated and the visible range is expanded.

  A stereoscopic image in which a plurality of half mirrors are arranged in a two-dimensional video apparatus and a planar virtual image is viewed in the depth direction is a stereoscopic image like a book split used in a play stage. Does not require glasses. In terms of the physiological factors of stereoscopic vision, all the factors of vergence, focus adjustment, binocular parallax, and motion parallax are used, which is exactly the same as when viewing normal stereoscopic images. There is no eye fatigue like a 3D image device seen only by the factor.

  Recently, as described in Patent Document 3 and Patent Document 4, it has been proposed to install a two-dimensional display and a three-dimensional display function in a portable terminal having a display such as a mobile phone or a portable game device. Yes. That is, the technique described in Patent Document 3 includes a mechanism for holding a display device having a lenticular three-dimensional display screen on a mobile phone or the like in a reversible manner. The technique described in Patent Document 4 is displayed as a stereoscopic image of a virtual image so that it is projected onto a stereoscopic display member made up of a built-in half mirror, concave mirror, etc. and floats in space via a stereoscopic image display window of a mobile phone. To do.

JP 2008-20564 A JP 2009-53539 A JP 2002-372929 A JP 2010-141447 A

  According to the technique described in Patent Document 3, a mechanism for holding a display device having a three-dimensional display screen by a lenticular method in an invertible manner is essential. However, a user using a mobile phone of a certain communication carrier does not necessarily need this kind of 3D display function, and as a result, purchases a costly mobile phone equipped with the 3D display function. Will be allowed to.

Moreover, according to the technique described in Patent Document 4, it is essential to provide a mobile phone with a stereoscopic display device including a half mirror, a concave mirror, and the like. Therefore, as in the case of the technique of Patent Document 3, a special mechanism for three-dimensional display is required for the mobile phone, which increases the cost.
In addition, since the techniques of Patent Documents 3 and 4 require a special mechanism for a mobile phone, it is practically difficult to uniformly adopt this three-dimensional display function for mobile phones that are generally spread in, for example, communication carrier companies. It is.

Accordingly, an object of the present invention is to provide a 3D video display for displaying a video displayed on the screen of the video display device as a 3D video without any special mechanism or modification to the video display device for the 3D video display. To provide an apparatus.
It is another object of the present invention to provide a three-dimensional image display device having a compact structure by rotating and folding a plurality of mirrors that reflect images.
It is another object of the present invention to provide a three-dimensional video display device that can accept video display devices having different sizes such as width and thickness.

The 3D image display apparatus according to the present invention is preferably a 3D image display apparatus that displays an image displayed on the screen of the image display apparatus in a 3D manner using a plurality of mirrors.
A body case for mounting the video display device;
A mirror device comprising a mirror case rotatably supported at the rear of the main body case, and a plurality of mirrors mounted on the mirror case so as to be rotatable in parallel at predetermined intervals toward the back of the mirror case Have
When viewing a three-dimensional image, the mirror case rotates about an axis, and the plurality of mirrors are on the viewer's side with respect to the screen so that the tips of the plurality of mirrors form substantially the same plane. In a state where it is supported at a predetermined angle, the image displayed on the screen is reflected,
With the video display device removed from the main body case, the mirror case rotates about the axis in a closing direction with the main body case, and the plurality of mirrors are rotated and stored in a folded state. It is comprised as a 3D video display device characterized by the above.

In a preferred example, each of the plurality of mirrors is mounted on a quadrilateral mirror frame,
In a state where the video display device is mounted on the main body case, the mirror case is supported with the tip of the plurality of mirror frames in contact with the screen of the video display device by rotating about the axis. In this state, the image displayed on the screen is reflected toward the viewer.

Preferably, in a state where the video display device is mounted on the main body case,
A first position that reflects the image displayed on the screen in a state in which the mirror case is rotated about an axis and the plurality of mirrors are supported at an angle with respect to the screen;
The mirror case is rotated backward about the axis, the plurality of mirrors are separated from the screen of the video display device, and a second position where the video displayed on the screen of the video display device can be viewed The mirror case can be rotated.

Preferably, the side that defines the height of the plurality of quadrilateral mirrors is formed to be shorter toward the back,
The plurality of mirrors are arranged on the front side, and are capable of rotating with respect to the mirror case around an axis, and first and second half mirrors;
It includes a full mirror disposed behind the first and second half mirrors and fixed to the mirror case.

  Preferably, the mirror case, the mirror frame, and the main body case are made of synthetic resin.

  Preferably, the main body case includes a flange that surrounds the main body case, and an accommodating portion that is disposed inside the flange and accommodates the video display device.

  Preferably, the main body case includes a pair of soft members disposed on both sides of the inner portion thereof, and the side portions of the video display device to be mounted are held by the soft members.

  Preferably, the main body case has a socket part into which a head part of the video display device is inserted at a deep part of the main body case, and a bottom part in the socket part. A leaf spring for pressing in the direction is provided.

Preferably, the shaft provided at the rear end of the mirror case when viewing a three-dimensional image and the front ends of the plurality of mirror frames are on the same plane,
A bearing that engages with the shaft of the mirror case is provided at the rear end of the main body case, and a reference surface formed by an upper portion in the socket portion of the main body case is on the same plane as the bearing.
When the video display device is attached to the main body socket, the screen of the video display device comes into contact with the reference surface by pressing the leaf spring portion of the main body case,
Regardless of the inclination due to the difference in thickness of the video display device, the plurality of mirror frames are positioned on the screen.

Preferably, a hook is provided at a front end of the mirror case, and a hook hole is provided at a front portion of the flange of the main body case.
When the mirror case rotates and is closed by the main body case, the hook and the hook hole are engaged with each other to maintain the combined state of the mirror case and the main body case.

  Preferably, the main body case is equipped with a portable video display device having a screen for displaying video.

  Preferably, each of the main body case and the mirror case has a box shape, and in the state where the mirror case is closed and united with the main body case, the two cases have a single box shape.

According to the 3D image display apparatus of the present invention, the image display apparatus can be easily attached, and 3D images can be easily viewed without wearing special glasses as in the prior art. In addition, it is possible to display a three-dimensional video by using a video display device that is generally put into practical use without modifying the video display device.
In addition, the mirror device can be rotated with respect to the main body case, and a plurality of mirrors that reflect images are rotated and folded to be housed in the mirror device, so that the structure is compact and convenient to carry.
Furthermore, a plurality of video display devices having different sizes such as width or height can be accepted, and the types of display devices capable of viewing three-dimensional video are expanded.

1 is a perspective view of a 3D video display device in a state where a 3D video can be viewed according to an embodiment. FIG. 1 is a perspective view of a 3D video display device in a state in which 2D video can be viewed on a screen of the video display device according to an embodiment. The disassembled perspective view of the mirror apparatus in one Embodiment. The perspective view of the three-dimensional image display apparatus of the state which closed the mirror apparatus in one Embodiment. The perspective view of the mirror device in one embodiment. The perspective view which looked at the main part case in one embodiment from the upper part. The perspective view which looked at the main body case in one embodiment from the bottom. The side sectional view of the mirror device in one embodiment. Sectional drawing seen from three directions of the main body case in one Embodiment. Sectional drawing seen from three directions of the three-dimensional image display apparatus in the state which can appreciate the three-dimensional image in one Embodiment. Sectional drawing seen from three directions of the three-dimensional image display apparatus in the state which can appreciate the three-dimensional image in one Embodiment. The sectional side view of the three-dimensional image display apparatus of the state which folded the mirror in one Embodiment. The perspective view which shows the principle of a three-dimensional video display apparatus. The side view which shows the principle of a three-dimensional video display apparatus.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
13 and 14 are a perspective view and a side view showing the principle of the 3D image display apparatus according to the embodiment. In these drawings, the 3D video display device is mainly composed of a 2D video display device 60 and a mirror device 90 disposed on the upper side of the 2D video display device 60. The mirror device 90 is mainly composed of a plurality of mirrors, that is, two flat half mirrors 91 and 92 and one flat full mirror 93. 13 and 14 show the principle of the three-dimensional video display device, and only the arrangement relationship between the half mirrors 91 and 92 and the full mirror 93 is shown, and a configuration for fixing these mirrors at predetermined positions. Elements are not shown.

  As shown in FIG. 14, the half mirrors 91 and 92 and the full mirror 93 are disposed at a predetermined interval with respect to the two-dimensional image display surface 61 and inclined at a predetermined angle toward the viewer side (front). . In this embodiment, “full mirror” refers to a mirror having a reflectance of 100% to 80%. The “mirror” includes a half mirror and a full mirror.

  The half mirrors 91 and 92 and the full mirror 93 are preferably arranged at an angle of about 45 ° to the viewer 200 side. Also, the height of the mirror 91 on the viewer side is set high so that the height of the upper ends of the plurality of mirrors 91, 92, 93 decreases toward the back, and the height decreases toward the back. Has been. The half mirrors 91 and 92 and the full mirror 93 reflect the images displayed on the image areas 61a, 61b and 61c of the screen 61 of the two-dimensional image display device 60, and generate virtual images 91a, 92a and 93a. Thus, the virtual image 91a of the video area 61a under the half mirror 91, the virtual image 92a of the video area 61b under the half mirror 92, and the virtual image 93a of the video area 61c under the full mirror 93 are in the line-of-sight direction 201 of the viewer 200. It looks like a 3D image that overlaps the depth position.

  In this embodiment, the visible light transmittance of the foremost half mirror 91 as viewed from the viewer 200: The reflectance is in the range of 67:33 to 60:40, and the visible light transmittance of the next half mirror 92 is: By setting the reflectance to 50:50 to 55:45 and the reflectance of visible light of the innermost full mirror 93 to 100% to 80%, all virtual images 91a, 91b, 91c are almost the same brightness from the viewers. It can be seen that a sufficiently bright image can be obtained even when the light is turned on indoors.

As a preferable combination of the transmittance and the reflectance of each mirror constituting the mirror device, the half mirror 91 may be 67:33, the half mirror 92 may be 50:50, and the full mirror 93 may have a reflectance of 100%. This assumes that the reflection performance of the full mirror 93 is high.
In another preferred combination, the half mirror 91 is 69:31, the half mirror 92 is 55:45, and the full mirror 93 has a reflectance of 80%. This assumes that the reflection performance of the full mirror 83 is slightly inferior.

  In another preferred combination, the half mirror 91 is 60:40, the half mirror 92 is 50:50, and the full mirror 93 has a reflectance of 80%. Although the above two combinations are values based on theoretical calculations, this value is an experimentally obtained value.

  In order to reduce the ghost in this case, the reflective surfaces of the half mirrors 91 and 92 and the full mirror 93 are arranged so that the viewer 200 is on the side of the viewer. The material of the half mirrors 91 and 92 and the full mirror 93 is preferably transparent glass. The reflective material is preferably a dielectric multilayer coating.

  The two-dimensional image display device 60 is a liquid crystal display, a plasma display, an LED display, an organic EL display, or the like used for a flat-screen TV, a mobile phone, a smartphone, and the like. , Portable game players, touch tablets, and other portable devices having a display.

  Next, a specific configuration example of the 3D video display device will be described with reference to FIG. The basic dimensional ratios of the half mirror and full mirror are the same as those shown in FIGS.

  FIG. 1 is a perspective view of a 3D video display device in a state in which 3D video can be viewed, and FIG. 2 is a 3D video in a state in which 2D video can be viewed on the screen of the 2D video display device with the mirror device opened. 3 is an exploded perspective view of the mirror device, FIG. 4 is a perspective view of the three-dimensional image display device in a state where the mirror device is closed, and FIG. 5 is a perspective view of the mirror device.

  As shown in FIG. 4, the three-dimensional video display device includes a mirror device 90 and a main body case 3. As shown in FIG. 1, the main body case 3 has a substantially box shape, and a two-dimensional video display device 70 is accommodated therein. The 2D video display device 70 is, for example, a smartphone. The mirror device 90 includes a substantially box-shaped mirror case 2 on which a plurality of mirrors (three mirrors in this example) are mounted in parallel in the depth direction at a predetermined interval. 2k is supported by a bearing 3k (see FIGS. 6 and 7) at the rear end of the main body case 3 and is rotatable. FIG. 2 shows a state in which the mirror case 2 is rotated and completely opened from the main body case 3. In addition, as shown in FIG. 4, when the mirror case 2 is closed to the main body case 3, the 3D image display device is a single box, so that it is compact and easy to store and carry in a bag. Become.

  As shown in FIGS. 1 to 6, the main body case 3 is surrounded by a flange (a side wall having a low height) 3i, and a housing portion 3m surrounded by the flange 3i is provided at the center. A 2D video display device 70 having a screen 71 for displaying a 2D video is detachably attached to the housing 3m. A pair of guide walls 3b for preventing the 2D image display device 70 from moving to the near side and dropping off is provided on the left and right sides in front. Details of the main body case 3 will be described later with reference to FIGS.

Next, the configuration of the mirror device 90 will be described in detail.
Referring to FIG. 2, two half mirrors 11 and 12 and one full mirror 13 are mounted on the mirror case 2 in order from the front. Two quadrilateral half mirrors 11 and 12 are attached so as to fit into quadrilateral mirror frames 21 and 22, and quadrilateral full mirror 13 is similarly attached to quadrilateral mirror frame 23. The widths of the four-sided shapes of the plurality of mirrors 11, 12, and 13 (long sides in the illustrated example) are the same, but the other side (short side) becomes shorter toward the back (far from the viewer). Here, the mirror case 2 and the mirror frames 21, 22, and 23 are preferably formed of a material such as an elastic synthetic resin, such as ABS, polycarbonate, or polypropylene.

Next, the assembly structure of the mirror device 90 will be described with reference to the exploded perspective view of FIG.
The half mirrors 11 and 12 are fitted into the mirror frames 21 and 22, respectively, and the full mirror 13 is fitted into and attached to the mirror frame 23 that forms a part of the mirror case 2. Each mirror frame 21 has a pair of shafts 21a. With the torsion coil spring 41 engaged with one of the shafts 21a, the shaft 21a is attached to a pair of bearing portions 2a provided on the mirror case 2. Similarly, the mirror frame 22 fitted with the half mirror 12 is attached to a pair of bearing portions 2b provided in the mirror case 2 with the torsion coil spring 42 engaged. Since the bearing portions 2a and 2b are made of an elastic synthetic resin, they can be deformed to some extent, and the shafts 21a and 22a of the mirror frames 21 and 22 can be fitted.

  In this way, the mirror frames 21 and 22 to which the half mirrors 11 and 12 are attached are forces that cause the mirror frames 21 and 22 to rotate about the axes 21a and 22a by the acting force of the torsion coil springs 41 and 42, respectively. Acts to bring the tip 21d, 22d of the mirror frame into close contact with the surface of the screen 71 of the two-dimensional image display device (see FIGS. 8 and 10 for details). On the other hand, the mirror frame 23 to which the full mirror 13 is attached is formed integrally with the mirror case 2 and does not rotate. In this state, the tip 2d of the mirror frame 23 forms a surface (S in FIG. 8) in contact with the screen 71 in the same manner as the tips 21d and 22d of the mirror frame.

FIG. 5 is a perspective view showing a state where the assembly of the mirror device 90 is completed.
A pair of shafts 2k are provided at the rear end of the mirror case 2, and the shaft 2k is engaged with a pair of bearings 3k provided on the main body case 3, so that the mirror device 90 and the main body case 3 are combined. Construct a solid. The mirror device 90 to the mirror case 2 can be rotated around the axis 2k with respect to the main body case 3.

  In FIG. 1, the two-dimensional image displayed on the screen 71 of the two-dimensional image display device 70 is reflected by the mirrors 21 to 23 in a state where the two-dimensional image display device 70 is accommodated in the accommodating portion 3 m of the main body case 3. The state in which a three-dimensional image is displayed to the viewer is shown. 2 shows a state in which the two-dimensional video display device 70 is housed in the housing portion 3m of the main body case 3 and the mirror device 90 is rotated and the screen 71 is opened to open the two-dimensional video display device. A state in which a normal two-dimensional image displayed on the screen 71 of 70 can be viewed is shown. In this state, 3D images cannot be viewed. When the screen 71 such as a smartphone has a touch panel function, the screen 71 can be freely touched with a finger or the like even while watching a two-dimensional image.

FIG. 8 is a side sectional view of the mirror device.
The operation and action of the mirror frames 21 and 22 will be described with reference to FIG.
The mirror frame 21 is in a state of being rotatable within a certain range about the axis 21a. However, the rotational force is applied to the mirror frame 21 by the force of the torsion coil spring 41, and the end 21b is in contact with the stopper 2e. In this state, when no force is applied to the mirror frame 21, the mirror frame 21 continues to maintain this position with respect to the mirror case 2. Further, when a certain level of force is applied to the mirror frame 21 (that is, when the mirror case is closed to the main body case 3), the repulsive force of the torsion coil spring 41 is lost, and the mirror frame 21 has the end 21d at the mirror case 2. Rotate towards it.

  The mirror frame 22 is also in the same state as the mirror frame 21. However, in the case of the mirror frame 22, the end 22b is in contact with the bottom surface 2g of the mirror case 2. When a force exceeding a certain level is applied to the mirror frame 22, the end 22 d rotates toward the mirror case 2. The torsion coil springs 41 and 42 may be engaged with portions other than the shafts 21a and 22a.

  In the state of FIG. 8, the end 21d of the mirror frame 21, the end 22d of the mirror frame 22, and the end 2d of the mirror frame 23 are on the same plane S (ie, the screen 71). Furthermore, the center of the pair of axes 2k of the mirror case 2 is also on the same plane S. Further, the reflecting surfaces of the half mirrors 11 and 12 and the full mirror 13 are kept parallel to the plane S at 45 °.

  The reason why the end 21d of the mirror frame 21 is at an angle of 45 ° with respect to the reflecting surface of the half mirror 11 is that when the end 21d contacts the screen 71 of the two-dimensional image display device 70, the two-dimensional This is because the glass half mirror 21 is not damaged by touching the screen 71 of the video display device 70 in as wide an area as possible.

The configuration of the main body case 3 will be described in detail with reference to FIGS. 6, 7, and 9.
A socket portion 3e into which the leading portion of the 2D image display device 70 is inserted is provided at the back of the main body case 3, and a part of the socket portion 3e is notched at the bottom of the main body case 3 facing the socket portion 3e. Accordingly, a leaf spring portion 3a that is bent and extended inside the socket portion 3e is provided. These components are made of a synthetic resin integrally formed with the main body case 3.

  A pair of soft members 51 made of, for example, sponge or rubber is disposed on the left and right inside the socket portion 3e. FIG. 9 shows the arrangement position of the soft member 51. 9A is a longitudinal sectional view, FIG. 9B is a plan view, and FIG. 9C is a transverse sectional view. The reason why the pair of soft members 51 are arranged inside the socket portion 3e is to accept a plurality of types of two-dimensional image display devices 70 having different widths and to absorb the difference in the widths by the soft members 51.

  As shown in FIG. 9 (A), the reason why the leaf spring portion 3a is provided at the bottom of the main body case 3 is that there are a plurality of types having different heights between the leaf spring portion 3a and the inside of the socket portion 3e of the main body case 3. The two-dimensional image display device 70 is received, and the screen 71 is always in contact with the reference surface 3g by the elastic force of the leaf spring portion 3a. Further, the two-dimensional image display device 70 is held by the pressure of the leaf spring 3a so that the two-dimensional image display device 70 does not easily come out of the socket portion 3e.

  A bearing 3k for rotatably mounting the shaft 2k of the mirror device 90 is provided at the rear end of the main body case 3. As shown in FIG. 9A, the bearing 3k is on the same plane R as the reference surface 3g. Further, the end portions 21d, 22d, 2d and the axis 2k of each mirror frame in FIG. 8 are on the same plane S. When the mirror device 90 rotates about the axis 2k with respect to the main body case 3, the plane S also rotates simultaneously, and the plane R and the plane S coincide with each other as shown in FIG. Since the screen 71 of the two-dimensional image display device 70 is in contact with the reference plane 3g, the end portions 21d, 22d, and 2d of each mirror frame are in close contact with the screen 71. In this way, a three-dimensional image can be displayed to the viewer in a state where the half mirrors 11 and 12 and the full mirror 13 are positioned with high accuracy with respect to the screen 71.

FIG. 10 is a cross-sectional view of the 3D video display device viewed from three directions in a state where the 2D video display device 70 is accommodated in the main body case 3 and a 3D video can be viewed using the mirror device 90.
When the 2D image display device 70 is inserted into the socket portion 3e of the main body case 3, the pair of soft members 51 contracts in accordance with the width shape of the 2D image display device 70, and the 2D image display device 70 is moved at a constant pressure. Press down. Since the soft member 51 has a certain friction, the two-dimensional image display device 70 is prevented from being easily removed from the socket portion 3e of the main body case 3.

  Further, the pair of substantially L-shaped walls 3b (FIGS. 9 to 10) provided in front of the main body case 3 prevents the two-dimensional image display device 70 from being easily detached from the main body case 3. Yes. Here, the wall 3b is installed at a position allowing a size slightly larger than the width and length of the two-dimensional image display device 70.

  10A and 10C, the leaf spring 3a of the main body case 3 presses the two-dimensional image display device 70 against the reference plane 3g with a constant pressure, and the end of the screen 71 is always at the reference plane 3g. Is in contact with.

  Further, as shown in FIG. 10A, even when the three mirror frames 21, 22, and 23 are in a state of displaying a three-dimensional image, the mirror frame 23 and the mirror case 2 are integrally formed, and the end portion 2d. And the axis 2k and the combined vertex P (maintaining the angle β) of the mirror frame 23 and the mirror case 2 are in a three-point support state and are strong, so the mirror case 2 is a mirror in a parallel arrangement state. The external force is not transmitted to the frames 21 and 22. For this reason, even if an external force is applied from the outside of the mirror case 2, it is possible to prevent the mirror frames 21 and 22 in the 3D video display state from being folded in the parallel arrangement state.

FIG. 11 shows a case where a 2D video display device 80 having a size different from that of the 2D video display device 70 shown in FIG.
The dimensions Ws2, Ds2, and Ts2 of the two-dimensional image display device 80 in FIG. 11 are all slightly smaller than the dimensions Ws1, Ds1, and Ts1 of the two-dimensional image display device 70 in FIG. As shown in FIGS. 11B and 11C, the soft member 51 holds the two-dimensional image display device 80 with sufficient pressure from the width direction. Further, the leaf spring 3a of the main body case 3 presses the two-dimensional image display device 80 against the reference surface 3g with a constant pressure, and the end of the screen 81 is always in contact with the reference surface 3g. Since the soft member 51 has a certain friction, the two-dimensional image display device 80 is prevented from being easily removed from the socket portion 3e of the main body case 3.

  Further, the pair of substantially L-shaped walls 3c shown in FIGS. 9 and 10 prevent the two-dimensional image display device 80 from easily coming off the main body case 3. The wall 3c is installed at a position allowing a slightly larger size than the two-dimensional image display device 80. Further, since there is a step between the guide wall 3b and the wall 3c, it is possible to accept both two types of two-dimensional video display devices 70 and 80 having different sizes.

  In the example of FIG. 10A, the bottom 3h of the main body case 3 and the screen 71 are parallel, but in the example of FIG. 11A, the thickness Ts2 of the two-dimensional video display device 80 is thin, so the screen 81 Makes a slight angle θ with the bottom 3h.

  As shown in FIG. 11, even if the screen 81 makes a slight angle θ with respect to the bottom 3h, the end portions 21d and 22d of the mirror frames 21 and 22, the case end 2d of the mirror frame 23, the mirror case 2 Since the shaft 2k is on the same plane and the screen 81 is substantially in contact with the reference surface 3g, the bearing 3k is on the screen 81. Thus, the plane S (FIG. 8) formed by the end portions 21d and 22d and the end portion 2d is in the same plane as the screen 81, and the half mirrors 11 and 12 and the full mirror 13 are higher than the screen 81. It is arranged at a predetermined position with accuracy.

  As described above, according to the present embodiment, the two-dimensional image display devices having different sizes by the soft member 51, the leaf spring 3a, and the substantially L-shaped walls 3b and 3c can be accommodated and mounted in the main body case 3. Therefore, it can correspond to a plurality of 2D video display device models. In addition, when the 2D video display device is a smartphone, it is common to always wear a dedicated case called a jacket or the like. Since the dedicated case has a certain thickness, the size of the two-dimensional image display device increases when it is attached. However, according to the present embodiment, it is possible to deal with two-dimensional video display devices of different sizes, so that the same model can be applied to both types of two-dimensional video display devices with and without a dedicated case. it can.

  Further, by devising the arrangement of the end portions 21d and 22d of the mirror frames 21 and 22, the end portion 2d of the mirror frame 23, the shaft 2k, the reference surface 3g of the main body case 3, and the bearing 3k, a two-dimensional image display surface Even if the mirror is mounted with a slight inclination with respect to the main body case bottom surface 3h within the range of the angle θ, the mirror can be arranged at a predetermined position.

  When the 2D video display device 70 is removed from the 3D video display device, the mirror device 90 is rotated to open the main body case 3 as shown in FIG. Then, the two-dimensional video display device 70 is taken out from the housing 3m. In this case, the height of the flange 3i of the main body case 3 is designed to be lower than the heights of the plural types of two-dimensional image display devices 70, 80, and the side surface 70a of the two-dimensional image display device 70 is exposed from the flange 3i. ing. Therefore, the two-dimensional image display device 70 can be easily detached from the main body case 3 by holding the side surface 70a with a finger. The same applies to the two-dimensional video display device 80 having a different size.

Next, with reference to FIG. 12, a three-dimensional image display apparatus when three mirrors are folded will be described. The mirror frames 21 and 22 are rotated and folded inside the mirror case 2 around the axes 21a and 22a, respectively. When the mirror frames 21 and 22 are folded, they fit between the mirror case 2 and the main body case 3. The torsion coil springs 41 and 42 are repelled, and the mirror frames 21 and 22 try to open the mirror case 2, but the hook frame 2f and the hook hole 3f are engaged with each other and the mirror frame 21 is held in a connected state. , 22 is stable in the folded state.
When the mirror case 2 to the mirror device 90 are closed, as shown in FIGS. 8 to 4, the three-dimensional image display device is thin and has a single box shape with no protrusions around, so it is compact. It becomes a state suitable for carrying.

  On the other hand, when opening the mirror case 2 to the mirror device 90, by pushing the hook point 2i portion of the mirror case 2, the hook 2f is released and the mirror case 2 can be opened. At this time, the mirror frames 21 and 22 are automatically rotated by the repulsive force of the coil springs 41 and 42 to return to the predetermined positions shown in FIGS. Thus, it is possible to perform a simple operation from a state in which the mirror case 2 is closed to a state in which a three-dimensional image as shown in FIG. 1 is viewed.

As mentioned above, although preferable embodiment of this invention was described, this invention is not limited to the said Example, It can implement in various deformation | transformation.
For example, in the above embodiment, a total of three mirrors of two half mirrors and one full mirror at the rear thereof are arranged. However, the present invention is not limited to this, and an example of arranging three or more half mirrors is also possible. Good.

2: Mirror case 21, 22, 23: Mirror frame 21d, 22d, 2d: End 3: Body case 3m: Housing part 41, 42: Torsion coil spring 51: Soft member
60, 70, 80: 2D image display device 61, 71, 81: Screen 90: Mirror device
91, 92, 11, 12: Half mirror 93, 13: Full mirror 91a, 92a, 93a: Virtual image

Claims (12)

In a 3D video display device that displays video displayed on a screen of a video display device in 3D using a plurality of mirrors,
A body case for mounting the video display device;
A mirror device comprising a mirror case rotatably supported at the rear of the main body case, and a plurality of mirrors mounted on the mirror case so as to be rotatable in parallel at predetermined intervals toward the back of the mirror case Have
When viewing a three-dimensional image, the mirror case rotates about an axis, and the plurality of mirrors are on the viewer's side with respect to the screen so that the tips of the plurality of mirrors form substantially the same plane. In a state where it is supported at a predetermined angle, the image displayed on the screen is reflected,
With the video display device removed from the main body case, the mirror case rotates about the axis in a closing direction with the main body case, and the plurality of mirrors are rotated and stored in a folded state. 3D video display device. Each of the plurality of mirrors is mounted on a quadrilateral mirror frame;
In a state where the video display device is mounted on the main body case, the mirror case is supported with the tip of the plurality of mirror frames in contact with the screen of the video display device by rotating about the axis. The three-dimensional image display apparatus according to claim 1, wherein an image displayed on the screen in a state is reflected toward a viewer. In a state where the video display device is mounted on the main body case,
A first position that reflects the image displayed on the screen in a state in which the mirror case is rotated about an axis and the plurality of mirrors are supported at an angle with respect to the screen;
The mirror case is rotated backward about the axis, the plurality of mirrors are separated from the screen of the video display device, and a second position where the video displayed on the screen of the video display device can be viewed The three-dimensional image display apparatus according to claim 1, wherein the mirror case is rotatable between the two. The side that defines the height of the plurality of quadrilateral mirrors is formed so as to become shorter toward the back,
The plurality of mirrors are arranged on the front side, and are capable of rotating with respect to the mirror case around an axis, and first and second half mirrors;
4. The three-dimensional image display device according to claim 1, comprising a single full mirror disposed behind the first and second half mirrors and fixed to the mirror case. 5. The three-dimensional image display device according to any one of claims 1 to 4, wherein the mirror case, the mirror frame, and the main body case are made of synthetic resin. The main body case includes a flange that surrounds the main body case, and an accommodating portion that is inside the flange and accommodates the video display device.
The three-dimensional image display apparatus according to any one of claims 1 to 5. The main body case includes a pair of soft members disposed on both sides of the inner portion thereof, and holds the side portions of the video display device to be mounted by the soft members.
The three-dimensional image display apparatus according to any one of claims 1 to 6. The main body case has a socket part into which the head part of the video display device is inserted, and a plate that is at the bottom of the socket part and presses the bottom part of the inserted video display device upward. With springs,
The three-dimensional image display apparatus according to any one of claims 1 to 7. The axis provided at the rear end of the mirror case when viewing a three-dimensional image and the front ends of the plurality of mirror frames are on the same plane,
A bearing that engages with the shaft of the mirror case is provided at the rear end of the main body case, and a reference surface formed by an upper portion in the socket portion of the main body case is on the same plane as the bearing.
When the video display device is attached to the main body socket, the screen of the video display device comes into contact with the reference surface by pressing the leaf spring portion of the main body case,
The three-dimensional image display device according to claim 8, wherein the plurality of mirror frames are positioned on the screen regardless of an inclination due to a difference in thickness of the image display device. A hook is provided at the front end of the mirror case, and a hook hole is provided at the front of the flange of the main body case.
When the mirror case is rotated and closed to the main body case, the hook and the hook hole are engaged to maintain the combined state of the mirror case and the main body case.
The three-dimensional image display apparatus according to any one of claims 1 to 9. The three-dimensional video display device according to any one of claims 1 to 10, wherein the main body case is equipped with a portable video display device having a screen for displaying video. Each of the main body case and the mirror case has a box shape, and in a state where the mirror case is closed and united with the main body case, both become one box shape.
The three-dimensional image display apparatus according to any one of claims 1 to 11.

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