KR200164631Y1 - 3-d o.h.p - Google Patents

Abstract

The present invention is in the projection object (O.H.P = Over Head Projector)

The left and right polarizing lens, the left and right condenser lens, the left and right projection lens, and the left and right reflecting mirrors are composed of two identical optical axis lines on the top of the light source, respectively. When placed on the right condenser lens, the left and right images are projected on the screen by the left and right projection lenses, but the left and right polarized images are respectively superimposed on one screen in the form of images. It is designed to display a stereoscopic image by polarizing glasses composed of a right polarizing plate.

Description

Stereoscopic Projection Projector {3-D O.H.P}

The present invention relates to a stereoscopic perspective projector capable of projecting a stereoscopic image, in particular in an O.H.P = Over Head Projector.

O.H.P is used in many fields such as conference, education, and presentation, but there is no structure of stereoscopic projection projector for projecting stereoscopic screen.

The present invention is for viewing a stereoscopic image in a perspective projector, and the present invention is a condenser lens having a polarizing plate structure that forms a left and right symmetrical deflection at the lower body stop and a left and right two-layer optical axis capable of dividing the light source into two. The left and right images formed on one film are polarized by left and right symmetry, and then the left and right condensing lenses are respectively polarized by the left and right condensing lenses. The left and right projection lenses are split into two left and right beams, and the left and right polarized images are formed on the screen, and then the left and right polarized glasses can be used to observe stereoscopic images. Is achieved.

1 is a schematic diagram illustrating the external structure of the present invention

2 is a structural explanatory diagram for each structural part of the present invention

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

4 is an explanatory diagram of a light source separation operation

5 is an explanatory diagram of the projection interval adjustment.

Figure 6 is a schematic diagram of the structure of the present invention application

Brief description of the designations for the symbols in the drawings

1. Lower body 2. Light source 3. Reflector 4. Polarizer

5. Condenser lens 6. Projection lens 7. Reflector 9. Image film

Hereinafter, a preferred embodiment of a stereoscopic perspective projector according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 and 2, a single or multiple light sources 2 are provided in the lower main body 1, and reflectors 3 are formed at the front end of the upper and lower polarizing plates 4A and 4B, respectively. The condenser lens 5 section composed of the left and right double condenser lenses 5A and 5B, and the projection lens 6 composed of the left and right projection lenses 6A and 6B on the upper side and the left and right reflectors 7A and 7B. The reflector 7 composed of) is configured on the upper end of the support 8.

If this is described in more detail by sector in FIG.

In the configuration of the polarizing plate 4 section, the polarization directions of the left and right polarizing plates 4A and 4B are rectangular in left and right symmetry, or in the vertical and horizontal directions of the X and Y axes.

The condenser lens 5 is composed of a condenser lens like the Fresnel lens, but is composed of two left and right condenser lenses 5A and 5B having different left and right optical axes.

The projection lens 6 is composed of the left and right projection lenses 6A and 6B of the same source having the same focal length.

The reflector 7 also includes left and right reflectors 7A and 7B.

The configuration of the optical specifications as described above

For example, as shown in Figs. 3 and 4, the left optical path is formed on the same optical axis line by using the left condenser lens 5A, the left projection lens 6A, and the left reflector 7A.

The right optical path also consists of the same logic.

In the present invention configured as described above, the left and right images (9A, 9B) are divided into two films on a single film as shown in FIG. 2 by the upper and lower condenser lenses 5A.5B as shown in FIG. The image film 9 is placed on the left and right condenser lenses 5A and 5B. In this case, the light path of the light source 2 is divided into two left and right polarizers 4A and 4B, and is deflected symmetrically to the left and right. Then, the left and right condenser lenses 5A and 5B are divided into two left and right optical paths, and the left and right images 9A and 9B placed on the left and right condenser lenses 5A and 5B, respectively. After passing through, the left and right projection lenses 6A and 6B are divided into left and right sides to be incident.

The incident left and right images 9A and 9B are projected onto the screen by the left and right reflectors 7A and 7B, respectively, and the matched left and right images are respectively polarized by the polarization lens. Thus, the left eye is observed in the left eye and the right eye in the right eye.

Such a three-dimensional projection apparatus by O.H.P is capable of projecting large slides because of the characteristics of O.H.P, so that a large amount of light can be projected and a stereoscopic image of a large screen can be displayed.

Therefore, such a three-dimensional projection device by O.H.P is particularly effective in displaying a large three-dimensional screen, such as a stereoscopic image of a large building that can replace the real, large-scale landscape of a famous tourist destination, since it is possible to display a large screen.

The present invention can reduce the distance between the left and right projection lenses 6A and 6B by eccentricizing the light-side center A of the left and right condenser lenses 5A and 5B, as shown in FIG. 4.

Such an effect has the advantage of reducing the distance between the left and right images projected in the near-field projection.

As shown in FIG. 5, the left and right reflectors 7C and 7D are formed in symmetrical squares in the first half of the left and right reflectors 7A and 7B to reduce the left and right projection angles. By adjusting the left and right reflectors (7C, 7D) between the left and right reflectors (7C, 7D) by adjusting the distance between the left and right reflectors can be adjusted.

The present invention can be configured to position the light source (2) at the top, as shown in Figure 6 'A', and in the present invention can be composed of two light sources (2), if necessary, the left and right projection lens (6A) 6B) and the support 8 can be folded inside the lower main body 1 to form a bag when carrying.

6, the light source 2, the left and right polarizing plates 4A and 4B, and the left and right condenser lenses 5A 5B and the left and right projection lenses 6A and 6B may be configured in a straight line.

Therefore, the present invention is a three-dimensional perspective projection machine which is very useful for a three-dimensional bird's eye view of a large building, a large three-dimensional landscape picture of a scenic spot, a large three-dimensional billboard.

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Claims (2)

In the stereoscopic projection device Inside the lower body 1, the light source 2 is formed in front of the left and right polarizing plates 4A and 4B, and the left and right condensing lenses 5A and 5B at the upper end thereof. The left and right projection lenses 6A and 6B and the left and right reflectors 7A and 7B are configured on the left and right condenser lenses 5A and 5B. The left and right condenser lenses 5A and 5B, the left and right projection lenses 6A and 6B, and the left and right reflectors 7A and 7B are arranged on the same optical axis line. The polarized left and right images 9A and 9B are divided into two from the left and right condensing lenses 5A and 5B, and then projected onto the screen by the left and right projection lenses 6A and 6B to display a stereoscopic image. Stereoscopic perspective projector characterized by being possible According to claim 1, wherein the left and right reflectors (7A, 7B) in front of the structure of the left and right reflectors (7C, 7D) and the adjusting device 10 in a rectangular deflection can be configured to adjust the left and right projection angle Perspective projector