KR100443765B1 - 3d visual display system - Google Patents

Abstract

The present invention constitutes a light source device for illuminating the left image film, the polarizing plate and the left image film from the bottom of the bottom in one main body case in the three-dimensional image display device structure, the right image film and the polarizing plate at a right angle position of 90 degrees And a light source device vertically constructed, and a translucent mirror at a 45 ° angle between them, and a reflecting mirror installed at a 45 ° angle on the top to enable clear stereoscopic image display and simultaneous viewing of stereoscopic images within the shortest viewing distance. After the vertical symmetrical configuration of the above-described structure in two stages up and down, the center reflector is configured on both sides, and the invention is capable of observing three-dimensional images from above and below as well as from both sides of the device, as well as from the ceiling and floor.

Description

Stereoscopic Display System {3D VISUAL DISPLAY SYSTEM}

The present invention displays a three-dimensional photograph by installing a large number or dozens or more of them by combining the optical device such as a polarizing device and a semi-transparent mirror with a large-size transparent photograph with different left and right photographing angles, and then building them in one body case. Is a possible invention.

In other words, the structure of the present invention more than tens of trillion in a certain place, and exhibited a large amount of three-dimensional pictures required, and the invention was invented so that many people can enjoy the three-dimensional image.

For example, in the case of a tourism promotion exhibition, a panoramic view of the Grand Canyon or Niagara Falls can be exhibited in three-dimensional pictures.

In the case of company public relations, large-scale manufacturing processes or products can be displayed in three dimensions.

For example, to display expensive or real items such as automobiles and motorcycles, it is possible to display products in which a lot of places and expenses are included in three-dimensional pictures.

In the case of museums, it is possible to display three-dimensional photographs of expensive display products or large structures that cannot be displayed.

At the marine exhibition, backcountry exploration, exploration house, haunted house, amusement park, theme park, etc., the three-dimensional photographs are displayed on the top and bottom, as well as on the ceiling and the floor. Exhibit is possible.

Such stereoscopic image presentation can be conceived as a method of projecting a small slide film of about 35m / m through the projector as shown in FIG.

However, when exhibiting a large amount of more than tens of trillion as in the present invention, two expensive projectors are required per one scene, and the amount of electricity consumption and expenses are excessive.

In particular, the projection method using the projector occupies a large occupied area per device by the projection distance, and thus it is not possible to display three-dimensional images of many scenes in a certain place.

In the conventional stereoscopic image, a small pixel of a film or a projector is largely projected and then polarized by a polarizing plate, so that the screen is dark and the polarization is not properly emitted, and thus the stereoscopic sensitivity is not clear.

In addition, such a stereoscopic image takes about 1.2 to 1.5 m when the projector displays a screen of about 40 " (60 cm x 80 cm) using a slide projector as shown in FIG.

When it is installed on both sides of the front and rear so that it can be seen before and after, the occupied area becomes 2.4-3m, which is twice that of the above.

As shown in Fig. 6, the image projected by the projector is imaged on the transmission screen 16. All images should have a minimum viewing distance (A, B, C, D) of at least twice the size of the screen image. Since the observations are made, the installation area becomes larger.

Therefore, the excessive occupancy of this installation area acts as a critical limiting factor for mass installation in a certain place.

In particular, due to the limitation of the height of the building structure, there were many installation restrictions due to securing the shortest viewing distance when installing the ceiling and floor.

In addition, since the height of the screen is fixed in the stereoscopic image device, it is difficult to simultaneously view a child with a different height.

In view of the above, the present invention prints a transmissive picture in a large size without using a projector and combines with an optical device to enable a stereoscopic image after combining with a light source device to enable a clear stereoscopic image.

It can be installed and moved in one unit case and installed and moved

Two different images can be viewed in front and rear, i.e. in both directions, but two images can be combined in one main body case (1). By reducing the following, the shortest viewing distance to the inside of the main body case (1) is refracted by the reflector to offset the additional shortest viewing distance to the outside, thereby minimizing the occupied area to be installed on the floor or ceiling.

1 is a schematic view of the present invention

Figure 2 is a schematic cross-sectional view of the present invention

3 is an explanatory view of the operation of the present invention;

4 is an explanatory diagram of polarization direction setting

5 is an explanatory diagram of the occupied area of the present invention.

6 is an explanatory view of the shortest viewing distance of the present invention;

Figure 7 is an explanatory view of the vertical viewing position of the present invention

8 is an explanatory diagram when installing the present invention on the ceiling or floor

Brief description of the designations for the symbols in the drawings

1.Body case 2.Lower left video device 3.Lower right video device

4.Translucent mirror 4A.Top semitransparent mirror 4B.Bottom translucent mirror

5. Reflector 5A. Lower Reflector 5B. Upper Reflector

6.Upper left imager 7.Upper right imager 8.Light source lamp 9.Scattering plate

10.Polarizing plate 10A.Left polarizing plate 10B.Right polarizing plate

11.Image plate 11A. Left image plate 11B. Right image plate 12. Reflector plate

13.Operating window 13A.Front viewing window 13B.Rear viewing window 13C.Lower viewing window

14.polarized glasses

Of the reference numerals of the present invention, the translucent mirror 4 is classified into an upper translucent mirror 4A and a lower translucent mirror 4B according to the installation position.

Reflector (5) is also classified into lower reflector (5A) and upper reflector (5B).

The polarizer 10 is also classified into a left polarizing plate 10A and a right polarizing plate 10B.

The image plate 11 is also classified into a left image plate 11A and a right image plate 11B, but all are classified for convenience of explanation and have the same function and configuration.

As shown in Fig. 1, Fig. 2, and Fig. 3, the lower left imager device 2 and the lower right imager device 3 are configured at a right angle of 90 ° from the lower end of the main body case 1, and the lower left and right images The translucent mirror 4 is constituted by an upward 45 ° square between the devices 2, 3.

The translucent mirror 4 is composed of a reflector having 50% of transmission and 50% of reflection, that is, a reflection and transmission ratio of 50%: 50%.

The upper reflector 5A is formed at a 45 ° square, and a front observation window 13A is formed on the front of which a viewer can observe an image.

Similarly, the upper left imager 6 and the upper right imager 7 are configured at a right angle of 90 ° from the inside of the main body case 1, and a translucent mirror 4 is installed at a 45 ° downward square therebetween. .

The upper reflector 5B is formed at a 45 ° square at the lower end thereof, and the rear observation window 13B is formed at the front thereof.

Therefore, the upper and lower reflectors 5A and 5B are formed in the same square as the double-sided reflector.

The structure of the lower left image device 2, the lower right image device 3, the upper left image 6, and the upper right image device 7 have the same configuration.

That is, as shown in Figs. 2 and 3, the light source lamp 8 uses the fluorescent lamp or the like as the light source from the rear plate to the reflector plate 12 on the front surface thereof.

A scattering plate 9 capable of uniformly distributing light of the light source lamp 8 on its front surface and a polarizing plate 10 on its front surface,

In front of it, the left image plate 11A photographed from the left angle and the right image plate 11B photographed from the right angle are respectively constituted.

The polarization direction of the lower left imager 2, the lower right imager 3, and the upper left imager 6 and the upper right imager 7 is a polarization direction structure of FIG. 4. And a mutually symmetric square structure such as "b".

In addition, as shown in FIG. 5, a separate lower observation window 13C is formed below the main body case 1 to enable a stereoscopic image even at a low viewing position such as a child.

As shown in FIG. 8, the structure of the present invention may be installed on a ceiling, and the plane may be three-dimensionally expressed in a sky plane or on a floor as shown in FIG. 8, such as a cliff or a cliff.

In the present invention, as shown in FIGS. 1 and 2 and 3, the lower left imaging apparatus 3 configured on the bottom surface of the main body case 1 has a left polarizing plate through which the light of the light source lamp 8 passes through the scattering plate 9. After passing through 10A and irradiating the left image plate 11A, the brightness of 50% in the translucent mirror 4 enters the lower reflector 5A installed on the upper side after passing straight through, and then again A 90 degree orthogonal refracting reflection is performed on the reflecting mirror 5A and reflected on the front observation window 13A.

The lower right imager 4 at the same bottom passes through the right-side polarizing plate 10B through the scattering plate 9, and then irradiates the right image plate 11B with a semi-transparent mirror. Brightness of 50% is refracted and reflected at a 90 degree angle, and is 90 degrees orthogonal refracted reflection from the lower reflector 5A to observe the front left window 13A as shown in the image of the lower left image plate 11B.

That is, the image of the right image plate 11B polarized to the right by the right polarizing plate 10B in the front observation window 13A and the image of the left image plate 11A polarized to the left by the left polarizing plate 10A in the image form. Observed.

Since the left image plate 11A is polarized to the left by the left polarizing plate 10A as shown in FIG. 4, the left image plate 11A is polarized to the left eye by the left polarizing plate of the viewer's polarizing glasses 14.

Since the right image plate 11B is polarized in the right direction by the right side polarizer 10B, the right eye plate is observed by the observer's polarizing glasses 14 and the right polarizer 10B. It becomes possible.

The operation of the upper left image device 6 and the upper right image device 7 is also the same as above.

However, since the reflection direction is reflected back by the upper reflector 5B, the rear observation window 13B is observed.

However, in the stereoscopic image, the brightness is reduced to 1/4 when using polarized light, and thus the polarization degree is also lowered, thereby reducing the stereoscopic sensitivity.

However, since the present invention does not enlarge the small image, there is no reduction in the light source and no reduction in the resolution, so that a very sharp image can be displayed.

The present invention is intended to be able to install a three-dimensional image to dozens or hundreds of scenes and to view a variety of three-dimensional images, so if the occupied area is excessive when the main body case 1 is installed, the practicality is lost.

Therefore, as shown in FIG. 5, the front and rear observation images are formed vertically and vertically within the thickness of one main body case 1, and thus, the front and rear surfaces of the main body case 1 according to the present invention are different from the front and rear surfaces. It is possible to construct a video viewing structure.

That is, as shown in Fig. 5, the front and rear projection methods of the conventional slide projector have to be installed at the front and rear, so the thickness E2 is the area occupancy ratio of the thickness E of the main body case 1 of the present invention. Doubled.

In addition, as shown in FIG. 6, the shortest viewing distance of the conventional slide projector 15 projection method requires stereoscopic images when the screen length is more than twice the screen length, so that the installation occupancy area is increased by the shortest viewing distance (ABCD). On the other hand,

As shown in FIG. 6, the present invention exhausts the shortest viewing distances A, B, C, and D by the translucent mirror 4 and the reflector 5 in the main body case 1, and thus the main body case 1 ) The viewing area can be reduced without the separation distance by the shortest viewing distance from the front, so the installation occupied area can be reduced accordingly.

In the structure of the conventional projector as shown in Fig. 7A, the image is imaged by the screen 11, so the observation position by eye level is one or the lower half translucent mirror 4B, respectively, of the lower left and right image devices 2.3. Since 50% of the images are directly observed by the lower observation window (l3C), stereoscopic images can be observed even at the low eye level at the bottom of the main body case (1), so children with low eye level can see simultaneously.

Therefore, the present invention enables clear stereoscopic image display by matching left and right images without a separate device such as a projector.

By aligning the left and right images up and down inside one main body case 1 to observe the front and rear stereoscopic images by the upper and lower reflectors 5A and 5B, the actual occupied area is 1/2 as compared with the conventional case. Decrease,

The transmissive mirror 4 inside the main body case 1 and the upper and lower reflectors 5A and 5B reduce the installation viewing area by reducing the minimum viewing distance, thereby reducing the installation area by 1/2 or more, compared with the conventional projector type. Significantly reduce the footprint of the installation.

In addition, as shown in Fig. 8, when the present invention is installed on the ceiling, a scene of a flying bird or a falling stone can be demonstrated in three-dimensional pictures.

When installed on the floor as shown in the "b" of Figure 8 can be expressed in a three-dimensional image, such as a valley shape or the scene looking down from the plane.

As described above, the present invention can be installed on the ceiling or the floor so that the shortest viewing distance is reduced in the reflector 5 and the translucent mirror 4 in the main body case 1, so that stereoscopic image observation is possible at a short distance.

Therefore, the present invention can be installed in a large amount of the dozens or more of the present invention in a predetermined area in the interior space, and can also be viewed before and after and up and down, so that viewers wear only polarized glasses 14, three-dimensional tourism such as Grand Canyon or Niagara Falls It is possible to see various three-dimensional photographs such as three-dimensional photographs of products that are difficult to exhibit in real life, such as photographs, cars and motorcycles, and three-dimensional exhibitions of large structures in exhibition museums.

Claims (3)

In the structure of the stereoscopic image display device In the lower part of the main body case 1, the lower left imager 2 constituting the light source lamp 9 and the polarizing plate 10 is configured. Comprising a lower right image device (3) consisting of a light source lamp (8) and a polarizing plate 10 in a 90 ° perpendicular direction with respect to the lower left image device (2), The translucent mirror 4 is configured at a 45 ° angle between the lower left imager 2 and the lower right imager 3, Inserting the left image plate 11A and the right image plate 11B into the lower left image device 2 and the lower right image device 3, respectively; The observation reflector 5 is formed in a square on the upper end, so that a clear three-dimensional image can be provided and the shortest viewing distance (A, B, C, D,) is shortened into the main body case (1). Stereoscopic image display device with minimized area The method of claim 1 The upper and lower mirrors 5A and 5B are configured as double-sided reflectors, and the squares are installed in the same body casing (1). 3D image display device characterized in that it is possible to observe 3D images later on The method of claim 1 Stereoscopic image display device characterized in that the three-dimensional image observation is possible by installing the structure of claim 1 on the floor or ceiling