JPH06230313A - Projection type display device - Google Patents

Abstract

PURPOSE:To obtain the projection type display device which projects an image on a screen and is not limited in installation position. CONSTITUTION:This projection type display device is equipped with a swing and tilt optical system where a transmission type liquid crystal panel 7 is fixed by displacing it together with a light source l from on the optical axis Lx of a projection lens 8 in a housing 11 while its parallel relation with the projection lens 8 is maintained and a reflecting means 38 which refracts image light projected from the projection lens 8 by 90 deg. through a reflecting mirror 36 arranged nearby the projection side of the projection lens 8 on the optical axis L1 and also reflects the light selectively in two reflection directions by rotating the reflecting mirror 36 around the optical axis L1 of the projection lens 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a projection type display device, and more particularly to a projection type display device capable of enlarging and projecting onto a screen from an installation position deviated from the center in front of the screen to the left or right.

[0002]

2. Description of the Related Art FIG. 6 is a conventional example 1 of a projection type display device 15.
FIG. In the figure, 1 is a light source such as a halogen lamp having a reflecting mirror 2, 4a and 4b are condenser lenses, and an infrared filter 3 is installed between them. Reference numeral 6 is a deflecting panel, which is followed by dichroic mirrors 5a and 5b for color separation, dichroic mirrors 5c and 5d for color combination, and total reflection mirrors 10a and 10b.
Are arranged at a predetermined angle. on the other hand,
Transmission type liquid crystal panels 7a, 7b and 7c are arranged on the optical paths separated by the color separation dichroic mirrors 5a and 5b, respectively, so as to receive the respective lights. 8 is a projection lens, and 9 is this projection type display device 15.
Is a screen that is outside the object and that projects an image that is enlarged and projected, and a screen that displays an image that is enlarged and projected from the projection lens 8.

Next, the operation will be described. A monochrome image is formed on each transmissive liquid crystal panel 7a, 7b, 7c by an electric signal. Now, the white light emitted from the light source 1 is reflected by the reflecting mirror 2 directly or after passing through the condenser lens 4a to remove the heat ray portion of the white light by the infrared filter 3, and then passes through the condenser lens 4b and the deflection panel 6. It is incident on the first dichroic mirror 5a for separation.

Here, only red light is reflected and blue light,
Although the green light is transmitted and enters the second dichroic mirror 5b, only the blue light is reflected here and the green light is transmitted.
The transmitted green light is incident on the transmissive liquid crystal panel 7c, the monochrome image formed on the transmissive liquid crystal panel 7c is obtained as green image information, and is advanced to be further reflected at a right angle by the total reflection mirror 10a. Then, this time, the light is reflected by the dichroic mirror 5d for color combination again at a right angle and enters the projection lens 8.

On the other hand, the red light reflected by the color separation dichroic mirror 5a is totally reflected by the total reflection mirror 10.
The direction of travel is deflected at a right angle by b to enter the transmissive liquid crystal panel 7a, and the monochrome image formed on the transmissive liquid crystal panel 7a is obtained as red image information to be further advanced, and the dichroic for color synthesis is advanced. The light passes through the mirrors 5c and 5d and enters the projection lens 8. Similarly, the blue light reflected by the color separation dichroic mirror 5b is also incident on the transmissive liquid crystal panel 7b like red light and green light, and as the blue image information, the dichroic mirror 5 for color combination is used.
The light is reflected at a right angle by c, passes through the color combining dichroic mirror 5d, and enters the projection lens 8.

In this way, the red light incident on the projection lens 8
The image information of the three primary colors of blue and green is combined at the destination after being transmitted or reflected by the dichroic mirrors 5c and 5d for color combination to form a color image, which is enlarged by the projection lens 8 and displayed on the screen 9. Be issued.

Ideally, the projection type display device 15 of the conventional example 1 having such a configuration is installed and projected at a position where the projection optical axis and a virtual normal line from the center of the screen substantially coincide with each other. However, when the projection optical axis is installed at a position inclined with respect to the virtual normal and projected, a trapezoidal distortion occurs in which the image projected on the screen becomes a trapezoid. Therefore, in that case, the mounting bases of appropriate heights are stacked in the front center of the screen 9 so that the projection optical axis of the projection type display device 15 and the virtual normal line substantially coincide with each other, and the projection type display device 15 is mounted thereon. Must be installed.

Therefore, as a conventional example 2 which solves these troubles, there is a projection type display device 20 disclosed in, for example, Japanese Patent Laid-Open No. 4-181938.

FIG. 7 is a principle diagram showing a projection type display device 20 of the second conventional example. In the figure, the same components as those of FIG. 6 are designated by the same reference numerals. The constituent members 1 to 11 of the projection type display device 20 are exactly the same as those of the projection type display device 15 of the conventional example 1 described above. 12 is a total reflection fixed projection mirror, 13 is a variable projection mirror,
Both are installed inside the housing 11 in front of the projection lens 8. The variable projection mirror 13 includes an angle adjusting unit that adjusts the installation angle from the outside of the housing 11.

Next, the operation of the conventional example 2 will be described.

The image information obtained by combining the images of the three primary colors of red, blue, and green, which have entered the projection lens 8 through the same path as the projection type display device 15 of the above-mentioned conventional example 1, after exiting the projection lens 8. A color image can be projected on the screen 9 by being reflected at a right angle by a fixed projection mirror 12 located further ahead, being further changed in direction by a variable projection mirror 13 and emitted from a projection port of a housing 11. At this time, the projection image on the screen 9 can be moved by adjusting the installation angle of the variable projection mirror 13 by the angle adjusting means.

[0012]

However, in the projection type display device 20 of the above-mentioned conventional example 2, the installation angle between the projection lens 8 and the screen 9 inside the housing 11 can be adjusted with respect to the optical axis. It is configured to include a rotatable variable projection mirror 13 so that the projection angle on the screen 9 can be adjusted.
Even with this structure, the problem that trapezoidal distortion occurs in the image projected on the screen still remains.

[0013]

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and a transmissive liquid crystal panel parallel to the projection lens is provided on the optical axis of the projection lens inside the apparatus housing. A projection type display device comprising a light source, which transmits light emitted from the light source through the transmissive liquid crystal panel to form image light, and then enlarges and projects the image light on a screen installed outside the device housing via the projection lens. The tilting optical system in which the transmissive liquid crystal panel is displaced and fixed together with the light source while maintaining the parallel relationship with the projection lens, and is provided on the optical axis and close to the exit side of the projection lens. The image light emitted from the projection lens is refracted by 90 degrees by the reflection mirror, and the reflection mirror is rotated about the optical axis of the projection lens to selectively reflect the reflection optical axis in two directions. It There is provided a projection display device characterized by comprising a reflection means that.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A projection type display device of the present invention comprises at least a light source, a transmissive liquid crystal panel, a projection lens and a reflection mirror. The system is provided with a tilting optical system, which is the first feature that gives the system a tilt, and a reflecting unit, which is the second feature, in which the image light emitted from the projection lens is reflected by a reflecting mirror. The projection type display device of the present invention having the tilting optical system having the first characteristic and the reflecting means having the second characteristic can be projected from the left and right positions or the upper and lower positions of the room regardless of the position of the screen. The image projected on the screen has no trapezoidal distortion and can satisfy the viewer sufficiently.

First, the tilting optical system, which is the first feature of the projection type display device of the present invention, will be described in comparison with the optical system of a conventional single plate type projection type display device for ease of explanation.

FIG. 1A is a principle diagram for explaining the tilt of a single plate type optical system 30 according to the present invention, and FIG. 1B is a principle diagram of a conventional single plate type optical system 25. As shown in the figure, the constituent members 1 to 8 of both single-plate optical systems 25 and 30 are exactly the same, but the arrangement of these constituent members is different.

That is, as shown in FIG. 1B, in the conventional single-plate optical system 25, the central optical axis L _{2 of the} light source 1 having the reflecting mirror 2 and the optical axis L ₁ of the projection lens 8 are aligned with each other. Between the two,
The transmission type liquid crystal panel 7, the deflection panel 6, the condenser lens 4b, the infrared filter 3 and the condenser lens 4a are connected from the projection lens 8 side so that the optical axes L ₁ and L ₂ pass through the respective centers. However, they are arranged so as to be in parallel relationship with each other. The conventional single-plate type optical system 25 configured as described above is for enlarging and projecting on the screen 9 from the central position in front of the screen 9.

The single-plate optical system 30 according to the present invention is a conventional single-plate optical system 25 described above with a tilt.

As shown in FIG. 1A, the tilt of the single-plate optical system 30 according to the present invention displaces the transmissive liquid crystal panel 7 in a predetermined direction described later while maintaining the parallel relationship with the projection lens 8. Further, the center optical axis L ₂ of the light source 1 is displaced while the transmissive liquid crystal panel 7 is displaced while maintaining the conventional positional relationship among the deflection panel 6, the condenser lens 4b, the infrared filter 3, the condenser lens 4a, and the light source 1. And the central optical axis L _{2 of the} light source 1 is tilted in the direction.
The projection lens 8 is fixed so as to pass through the center thereof. The predetermined direction for displacing the transmissive liquid crystal panel 7 means displacing the transmissive liquid crystal panel 7 to the left when the projection screen is in the projection right direction, and transmissive when displacing the projection screen in the projection left direction. The mold liquid crystal panel 7 is displaced to the right.

That is, the tilt of the single-plate optical system 30 according to the present invention is provided in the direction opposite to the desired tilt direction of the projection screen.

However, the tilt of the single-plate type optical system 30 according to the present invention is assembled with high precision, and as described above, it is preferable in terms of accuracy to raise the optical system in the desired tilt direction of the projection screen. Not something
Also, it is mechanically difficult.

Therefore, a reflecting mirror is provided between the projection lens 8 and the screen 9 on the exit side on the optical axis of the projection lens,
The image light emitted from the projection lens 8 is reflected by the reflection mirror 90.
The reflecting means, which is the second feature of the present invention, is refracted once and the reflecting mirror is rotated about the optical axis of the projection lens 8 as a rotation axis to selectively reflect the reflected optical axis in two directions. 38 was obtained.

FIG. 2 is a side sectional view of the projection type display device 35 of the present invention having the tilt optical system having the first characteristic and the reflecting means 38 having the second characteristic. As shown in the figure, in the projection type display device 35 of the present invention, the single plate optical system 30 described above is vertically housed inside the housing 11 with its projection direction facing upward. Further, above the projection lens 8, a reflection mirror 36 is provided as a reflection means 38 for refracting the image light emitted from the projection lens 8 by 90 degrees. Therefore, the image light emitted from the single plate optical system 30 is refracted by the reflection mirror 36 and is projected through the projection window 11a of the housing.
The image is enlarged and projected on the screen 9. At this time, the projection image magnified and projected on the screen 9 according to the tilt direction applied to the single-plate optical system 30 is magnified and projected in either the left or right direction with respect to the optical axis of the projection lens 8. Incidentally, FIG. 2, in order to tilt direction is fanned parallel to the screen 9 surface, the optical axis L ₂ of the optical system fueled with the optical axis L ₁ of the projection lens 8 is superposed.

FIG. 3 shows the projection type display device 3 of the present invention shown in FIG.
5 is a front sectional view of FIG. In the figure, the single-plate optical system 30 is placed in the direction A parallel to the surface of the screen 9, so that the enlarged projection screen to be projected can be placed in the left direction and projected.

If the tilting direction of the single-plate optical system 30 is fixed as described above and the reflection mirror 36 is rotated 180 degrees about the optical axis L ₁ as a rotation axis and projected, the enlarged projection screen projected is It can be projected on the right side.
Thus, the reflecting means 38, which is the second feature of the present invention,
The reflection mirror 36 is fixed to 180
By rotating the projection screen by one degree, the tilted direction of the tilted projection screen can be easily switched to the left or right to project.

Subsequently, a concrete example of reversing the reflection direction by 180 degrees with the optical axis L ₁ as the rotation axis will be briefly described.

FIG. 4 is a perspective view showing a first embodiment of the reflecting means 38 according to the present invention. Projection windows 11a and 11b are provided on the projection side of the housing 11 and its facing side, and further the housing is provided. 1
The slits 11 for inserting the reflection mirrors 36 on the both side surfaces of 1
c and 11d are provided. This slit 11c,
11d intersect with each other at an angle of 45 degrees, and regardless of which slit the reflection mirror 36 is inserted, the optical axis L ₁ of the projection lens 8 is reflected by 90 degrees, and the corresponding projection windows 11a, 1 are provided.
It is designed so that it can be emitted from 1b, and depending on the desired tilt direction of the projection screen, slits 11c,
Any one of 11d may be selected.

FIG. 5 is a perspective view showing a second embodiment of the reflecting means 38 according to the present invention, and 37 is a rotary reflecting unit attached to the housing 11 on the emitting side of the projection lens 8, the inside of which is shown. A reflection mirror 36 for reflecting the optical axis L ₁ of the projection lens 8 by 90 degrees is fixed to the projection mirror 37, and a projection window 37a for emitting the optical axis L ₁ of the projection lens 8 reflected by 90 degrees.
Is provided. The rotary reflection unit 37 can be selected by rotating the unit 180 degrees depending on the desired tilting direction of the projection screen.

The projection type display device 3 of the present invention described in detail above.
5, the tilt projection screen, which is enlarged and projected on the screen by the reflecting means 38, can be easily switched to either the left or right direction, and the tilt projection screen is not distorted. Can be sufficiently satisfied.

Although the projection type display device 35 of the present invention has been described above using the single plate type optical system 30, it is not limited to the single plate type, and the projection screen enlarged and projected on the screen is tilted. The direction is not limited to left, right, up, or down. Also, the amount of deviation that displaces the transmissive liquid crystal panel while maintaining the parallel relationship with the projection lens is
It is not sufficient to look through the transmissive liquid crystal panel through the projection lens in the opposite direction to the projection direction and to locate the image surface of the transmissive liquid crystal panel within the image circle of the projection lens without any damage.

[0031]

As described above, the projection type display device of the present invention is provided with the transmission type liquid crystal panel parallel to the projection lens and the light source on the optical axis of the projection lens inside the device housing. In the projection type display device, after the emitted light of is transmitted through the transmissive liquid crystal panel to become image light, and then enlarged and projected on the screen installed outside the device housing through the projection lens,
From the projection lens, a tilting optical system that displaces and fixes the transmissive liquid crystal panel together with the light source while maintaining the parallel relationship with the projection lens, and a reflection mirror that is placed on the optical axis and close to the exit side of the projection lens The image light emitted by is refracted by 90 degrees, and the reflection mirror is rotated around the optical axis of the projection lens as a rotation axis to selectively reflect the reflection optical axis in two directions. By switching the reflection mirror, the projection screen enlarged and projected on the screen can be easily placed in either the left or right direction, and the projection screen will not be distorted, so that the viewer can be fully satisfied. It is possible.

[Brief description of drawings]

FIG. 1A is a principle diagram illustrating a tilt of a single-plate optical system according to the present invention.

FIG. 1B is a principle diagram of a conventional single-plate optical system.

FIG. 2 is a side sectional view of the projection type display device of the present invention.

FIG. 3 is a front sectional view of a projection type display device of the present invention.

FIG. 4 is a first embodiment of the reflection means of the projection type display device of the present invention.
FIG.

FIG. 5 is a second embodiment of the reflection means of the projection type display device of the present invention.
FIG.

FIG. 6 is a principle diagram showing a conventional projection display device.

FIG. 7 is a principle diagram showing a conventional projection display device.

[Explanation of symbols]

 1 Light Source 2 Reflector 3 Infrared Filter 4a Condenser Lens 4b Condenser Lens 6 Deflection Filter 7 Transmissive Liquid Crystal Panel 8 Projection Lens 9 Screen 11 Case 11a Projection Window 30 Single Plate Optical System 36 Reflection Mirror 38 Reflector

Claims (1)

[Claims] 1. A transmission type liquid crystal panel parallel to the projection lens and a light source are provided on an optical axis of a projection lens inside an apparatus casing, and light emitted from the light source is transmitted through the transmission type liquid crystal panel. In a projection type display device that enlarges and projects on a screen installed outside the device housing through the projection lens after forming the image light, the light source while maintaining the parallel relationship between the transmissive liquid crystal panel and the projection lens. With the tilt optical system displaced and fixed together, and the reflection mirror provided on the optical axis and close to the exit side of the projection lens, the image light emitted from the projection lens is refracted by 90 degrees, and A projection-type display device comprising: a reflection unit that rotates the reflection mirror about an optical axis of a projection lens as a rotation axis to selectively reflect the reflection optical axis in two directions.