JP2003255467A - Optical unit and video display device using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide excellent color sense and image quality in the state of suppressing the increase of power and to improve the brightness of a screen in a video display technique using a reflection mirror. <P>SOLUTION: The reflection mirror for which a reflection surface is formed of the film of silver or a silver alloy is provided inside an irradiation light path. Also, the reflection mirror for reflecting a video light emitted from the projection lens or projection tube of an optical unit is provided with the reflection surface formed of the film of the silver or the silver alloy. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of a reflecting mirror in an optical system of an image display device.

[0002]

2. Description of the Related Art Conventionally, as a reflecting mirror for changing an optical path in an image display device, for example, an aluminum (Al) film is vapor-deposited on the surface of a base material such as glass and the surface of the aluminum film is used as a reflecting surface. An aluminum (Al) film is vapor-deposited on the surface of the object or the base material, and silicon oxide (Si
For example, there is one in which a film of O ₂ ) and a film of titanium oxide (TiO ₂ ) are provided in a laminated form and the surface of the titanium oxide film is used as a reflecting surface. FIG. 8 (a) is a reflecting mirror having an aluminum film 2'formed by vapor deposition on the surface of a substrate 1'such as glass, (b).
Is an example of a reflecting mirror in which an aluminum film 2'is formed on the surface of a substrate 1'of glass or the like by vapor deposition, and a silicon oxide film 5 and a titanium oxide film 6 are further laminated thereon. is there. These reflecting mirrors are provided in a portion for changing the optical path of the illumination optical system in the optical unit of the image display device and for changing the optical path in the screen direction outside the optical unit.

[0003]

FIG. 9 shows an example of the light reflectance characteristic of the conventional reflecting mirror described above. In the figure, the reflectance characteristic of the reflecting mirror having the configuration of FIG.
9 is a reflectance characteristic of the reflecting mirror having the configuration of FIG. According to the characteristics, the reflectance is 95% or less in the wavelength range of 400 nm to 700 nm, and the reflectance decreases as the wavelength increases. According to the characteristics, the wavelength is 550n.
In the range of m to 700 nm, the reflectance gradually decreases as the wavelength increases, and becomes 95% or less in the range of wavelength 600 nm or more. On the other hand, the energy distribution characteristics of the light incident on the reflecting mirror are as shown in FIGS. Figure 10
Is the energy distribution characteristic of the light emitted from the projection tube,
(A) is an energy distribution characteristic of light emitted from a B light (blue light) projection tube, (b) is energy distribution characteristic of light emitted from a G light (green light) projection tube, and (c) is It is an energy characteristic of the light emitted from the R light (red light) projection tube. FIG. 11 is an energy distribution characteristic of light emitted from a high pressure mercury lamp as a light source when an image is formed using a display element. As a result, even in the case of the projection tube system,
Also in the case of the display element method using a high-pressure mercury lamp, the reflectance of R light (wavelength near 650 nm) on the reflecting mirror is lower than that of B light or G light (FIG. 9). Particularly, in a high-pressure mercury lamp, the energy of R light emitted from the lamp is low (FIG. 11), and therefore the energy of R light reflected by the reflecting mirror is further reduced. In order for the image to have a good color and image quality, it is necessary to combine R light, G light, and B light at a predetermined ratio. The increase in the energy of the R light has been dealt with by increasing the power supplied to the light projection tube. Further, in the case of a display element system using a high-pressure mercury lamp, the brightness of the screen tends to decrease in order to obtain good color and image quality. In view of the situation of the above-mentioned conventional technique, the problems of the present invention are (1) in the image display technique, to obtain good color and image quality while suppressing an increase in power, and (2) to display a screen. It is possible to improve the brightness, and (3) it is easy to manufacture the reflecting mirror and suitable for mass production. The purpose of the present invention is to
It is to provide a technique capable of solving such problems.

[0004]

In order to solve the above-mentioned problems, in the present invention, basically, a reflecting mirror having a reflecting surface formed of a film of silver or a silver alloy is provided in an irradiation optical path. To do. In addition, the reflecting mirror that reflects the image light emitted from the projection lens or the projection tube of the optical unit is configured to have a reflecting surface formed of a silver or silver alloy film. Specifically, (1) a projection lens or a projection tube of an optical unit (corresponding embodiment: reference numeral 11) (corresponding embodiment: reference numerals 61, 62,
63) is used as an image display device that reflects the image light emitted from the reflection mirror by a reflection mirror and displays the image on the screen. The reflection mirror (corresponding embodiments: reference numerals 12, 31, 34, 46, 47, 4
8, 49) has a reflecting surface formed of a silver or silver alloy film, and the reflectance of the red light component and the green light component of the light incident on the reflecting mirror is higher than that of the blue light component. The structure is designed so that it can be raised. As an optical unit of an image display device for irradiating light from a light source side to a display element to form an optical image according to an image signal, (2) a reflecting mirror whose reflecting surface is formed of a silver or silver alloy film (corresponding implementation) Example: Codes 31, 34,
46, 47, 48, 49) in the irradiation optical path, and the optical path direction is changed by the reflecting mirror. (3) The illumination optical system separates the light from the light source side into red, green, and blue color lights (corresponding examples: reference numerals 33, 50a, and 50b).
And a reflecting mirror formed of a silver or silver alloy film and disposed between the light source and the color separation section or between the color separation section and the display element (corresponding embodiment: reference numeral 31, 3
4, 46, 47, 48, 49), and the reflectance of the red light component and the green light component of the light incident on the reflecting mirror can be made higher than the reflectance of the blue light component. . (4) A polarization conversion element (corresponding embodiment: reference numeral 43) that aligns the polarization direction of light from the light source side with the illumination optical system, and separates the polarized light whose polarization directions are aligned into red, green, and blue light. And a color separation part (corresponding embodiment: reference numerals 50a and 50b) and a reflection surface formed of a silver or silver alloy film, and is disposed between the polarization conversion element and the color separation part. A reflecting mirror that reflects light and makes it enter the color separation unit (corresponding embodiment: reference numeral 4
6) is provided, and the reflectance of the red light component and the green light component in the polarized light can be increased more than the reflectance of the blue light component. (5) A polarization conversion element that aligns the polarization direction of light from the light source side with the illumination optical system (corresponding embodiment: reference numeral 4
3) and a color separation unit that separates polarized light whose polarization directions are aligned into red, green and blue lights (corresponding embodiments: reference numerals 50a, 5
0b) and a reflecting surface formed of a film of silver or a silver alloy, which is arranged in the subsequent stage of the color separation section and reflects each color light to change the direction of each optical path (corresponding embodiment: code Four
7, 48, 49) and the color-separated red light,
The reflectance of green light can be made higher than the reflectance of blue light, and the reflected color lights are applied to the display element. (6) A polarization conversion element that aligns the polarization direction of light from the light source side with the illumination optical system (corresponding embodiment: reference numeral 4
3) and a color separation unit that separates polarized light whose polarization directions are aligned into red, green and blue lights (corresponding embodiments: reference numerals 50a, 5
0b) and a reflecting surface formed of a film of silver or a silver alloy, which is disposed between the polarization conversion element and the color separation section and reflects polarized light to enter the color separation section. It has a reflecting mirror No. 1 (corresponding embodiment: reference numeral 46) and a reflecting surface formed of a silver or silver alloy film, and is arranged in the subsequent stage of the color separation section to reflect the respective color lights to change their optical path directions. A second reflecting mirror (corresponding embodiment: reference numerals 47, 4) for converting and entering the display element.
8 and 49), the reflectance of the red light component and the green light component in the polarized light can be increased by the first reflecting mirror more than the reflectance of the blue light component. With the use of a reflecting mirror, the reflectance of the above-described color-separated red light and green light can be increased more than the reflectance of blue light.
(7) In any one of (2) to (5) above, the reflecting mirror is provided so that the wavelength of incident light is approximately 550 nm to 700 nm.
In this range, the light reflectance is 95% or more. (8) In (6) above, one or both of the first and second reflecting mirrors has an incident light wavelength of about 55.
The reflectance of light in the range of 0 nm to 700 nm is 95
% Or more. As a video display device for irradiating light from a light source side to a display element to form an optical image according to a video signal, (9) has a reflecting surface formed of a silver or silver alloy film and is disposed in an irradiation optical path. And a reflecting mirror for converting the optical path direction (corresponding embodiments: reference numerals 31, 34, 46, 47, 48,
49), a drive circuit (corresponding embodiment: reference numeral 72) that drives the display element based on a video signal, and a power supply circuit (corresponding embodiment: reference numeral 70) that supplies power to the light source and the drive circuit. It is configured as follows. (10) The color separation unit (corresponding embodiment: reference numeral 33) that separates light from the light source side into red, green, and blue light, and a reflecting surface formed of a silver or silver alloy film, Arranged between the light source and the color separation section or between the color separation section and the display element, the reflectance of the red light component and the green light component of the white light or the color-separated color lights,
A reflecting mirror (corresponding embodiment: reference numerals 31 and 34) capable of increasing the reflectance of the blue light component, a motor (corresponding embodiment: reference numeral 32) for driving the color separation unit, and the above display based on a video signal. A drive circuit (corresponding embodiment: reference numeral 72) that drives the element and drives the motor, and a power supply circuit that supplies power to the light source and the drive circuit (corresponding embodiment:
And reference numeral 70). (11) A polarization conversion element (corresponding embodiment: reference numeral 43) that aligns the polarization directions of light from the light source side, and a color separation unit that separates the polarized light whose polarization directions are aligned into red, green, and blue light ( Applicable embodiment: Reference numeral 50
a, 50b) and a reflecting surface formed of a film of silver or a silver alloy, and is disposed between the polarization conversion element and the color separation section, and reflects polarized light to enter the color separation section. A reflecting mirror (corresponding embodiment: reference numeral 46) and a drive circuit (corresponding embodiment: reference numeral 72) for driving the display element based on a video signal.
And a power supply circuit (corresponding embodiment: reference numeral 70) for supplying electric power to the light source and the drive circuit, the reflectance of the red light component and the green light component in the polarized light is calculated from the reflectance of the blue light component. Also, the configuration is such that the image is displayed in a state in which it can be increased.
(12) A polarization conversion element (corresponding embodiment: reference numeral 43) that aligns the polarization directions of light from the light source side, and a color separation unit that separates the polarized light having the aligned polarization directions into red, green, and blue color lights ( Corresponding embodiment: Reference numerals 50a and 50b) and a reflecting surface formed of a silver or silver alloy film are provided in the subsequent stage of the color separation section to reflect the respective color lights to convert the respective optical path directions. A reflector for irradiating the display element (corresponding embodiment: reference numerals 47, 48,
49), a drive circuit (corresponding embodiment: reference numeral 72) that drives the display element based on a video signal, and a power supply circuit (corresponding embodiment: reference numeral 70) that supplies power to the light source and the drive circuit. The image display is performed in a state in which the reflectances of the color-separated red light and green light can be increased more than the reflectance of blue light. (13) Polarization conversion element that aligns the polarization directions of light from the light source side (corresponding embodiment: reference numeral 43)
And a color separation unit that separates polarized light whose polarization directions are aligned into red, green, and blue light (corresponding embodiments: reference numerals 50a, 50).
b) and a reflecting surface formed of a silver or silver alloy film, which is disposed between the polarization conversion element and the color separation section and reflects polarized light to enter the color separation section. It has a reflecting mirror No. 1 (corresponding embodiment: reference numeral 46) and a reflecting surface formed of a silver or silver alloy film, and is arranged in the subsequent stage of the color separation section to reflect the respective color lights to change their optical path directions. A second reflecting mirror (corresponding embodiment: reference numerals 47, 48,
49), a drive circuit (corresponding embodiment: reference numeral 72) that drives the display element based on a video signal, and a power supply circuit (corresponding embodiment: reference numeral 70) that supplies power to the light source and the drive circuit. , The reflectance of the red light component and the green light component in the polarized light can be made higher than the reflectance of the blue light component by the first reflecting mirror, and the color separation is performed by the second reflecting mirror. The reflectance of red and green light
The image is displayed in a state where the reflectance of blue light can be increased. Moreover, as an optical unit,
(14) In any one of (2) to (5) above, the reflecting mirror is formed on a base material (corresponding embodiment: reference numeral 1) and a film thickness of about 0.5 μm to 5 μm on the base material. Undercoat film (corresponding example: reference numeral 2), the silver or silver alloy film (corresponding embodiment: reference numeral 3) provided on the undercoat film to form a reflection surface, and the silver or silver alloy A protective film which is provided on the film and contains at least one of a ceramic material and a vaporizable rust preventive agent (corresponding embodiment:
And 4). (15) Above (14)
In the above, the undercoat film of the reflecting mirror is made of a material containing at least one of an ultraviolet curable acrylic resin, an ultraviolet curable epoxy resin, an ultraviolet curable polyurethane resin, and a polyester resin. Further, as a video display device, (16) above (1), (9), (1
0), (11) or (12), the reflecting mirror is provided with a base material (corresponding embodiment: reference numeral 1) and about 0.
An undercoat film (corresponding example: reference numeral 2) formed to have a film thickness of 5 μm to 5 μm, and the above-mentioned silver or silver alloy film provided on the undercoat film to form a reflecting surface (corresponding example: reference numeral) 3) and a protective film provided on the silver or silver alloy film and containing at least one of a ceramic material and a vaporizable rust preventive agent (corresponding embodiment: reference numeral 4).
And the configuration.

[0005]

Embodiments of the present invention will be described below with reference to the drawings. 1 to 4 are explanatory views of the first embodiment of the present invention. FIG. 1 is a sectional view showing a first configuration example of a reflecting mirror, FIG. 2 is a sectional view showing a second configuration example of a reflecting mirror, FIG. 3 is a reflectance characteristic example diagram of a reflecting surface of the reflecting mirror, and FIG. It is a structural example figure of the video display apparatus as a 1st Example. In FIG. 1, 1 is a substrate made of glass or the like, 2 is an undercoat film, 3 is a film of silver or a silver alloy formed by electroless plating, 4 is a surface of the film 3 of silver or a silver alloy, It is a top coat film as a protective film for preventing the film 3 from corrosion, dirt, scratches and the like. The silver or silver alloy film 3 is formed, for example, by a silver mirror reaction in electroless plating.
It is formed with a film thickness of about 100 to 200 nm. The crystal of the silver or silver alloy film 3 has, for example, a crystal size of about 100 nm or less, or a substantially amorphous crystal. Such a crystal structure improves corrosion resistance. The undercoat film 2 is made of, for example, a material containing at least one of an ultraviolet curable acrylic resin, an ultraviolet curable epoxy resin, an ultraviolet curable polyurethane resin, and a polyester resin, or at least titanium oxide (T
iO ₂ ), silicon oxide (SiO ₂ ), alumina (Al ₂ O ₃ ).
Is formed on the surface of the base material 1 with a film thickness of about 0.5 to 5 μm using a ceramic material containing any of the above as a main component,
The adhesion of the silver or silver alloy film 3 to the substrate 1 is improved. The top coat film 4 as a protective film is made of, for example, silicon oxide (SiO ₂ ) or silicon oxide (SiO ₂ ).
And / or a ceramic material such as titanium oxide (TiO ₂ ) or a vaporizable rust preventive agent, or both, and is formed on the surface of the silver or silver alloy film 3 to have an optically determined film thickness. To be done. In such a configuration, the surface of the silver or silver alloy film 3 constitutes a light reflecting surface. In the image display device of the first embodiment, the reflecting mirror 12 has such a configuration.

FIG. 2 shows an example of a structure in which the undercoat film 2 having the structure shown in FIG. 1 is not provided. In FIG. 2, 1
Is a substrate made of glass or the like, 3 is a silver or silver alloy film formed by electroless plating, and 4 is a top coat film as a protective film that covers the surface of the silver or silver alloy film 3. The silver or silver alloy film 3 forming the light reflecting surface is formed by the silver mirror reaction as in the case of FIG. 1 and has the same structure as that of FIG. The top coat film 4 as a protective film is also formed in the same manner as in the case of FIG. 1 and has the same configuration as that in the case of FIG. In the image display device of the first embodiment, the reflecting mirror 12 is replaced by the one shown in FIG.
Instead of the reflecting mirror having the above structure, the reflecting mirror having the structure shown in FIG. 2 may be used.

FIG. 3 is a diagram showing the reflectance characteristic of the reflecting mirror having the structure shown in FIGS. 1 and 2. In FIG.
Is a characteristic when the thickness of the silver or silver alloy film 3 is about 3 μm or less in the reflecting mirror having the configuration shown in FIGS.
Also has a thickness of the silver or silver alloy film 3 of about 10 μm.
The following characteristics are reference values for comparison, and are the values listed in the science chronology as the reflectance of silver.
According to this characteristic, (1) the reflectance of the silver or silver alloy film 3 is such that at least the wavelength of incident light is 400 nm to 700 nm.
In the range of, the value increases as the wavelength of the incident light increases.
(2) The reflectance of the silver or silver alloy film 3 tends to increase as the thickness of the silver or silver alloy film decreases. That is, among the characteristics, the characteristics have a higher reflectance than the characteristics. (3) When the film thickness of the silver or silver alloy film 3 is about 10 μm or less (characteristic), the reflectance of light in the wavelength range of 550 nm to 700 nm of incident light is about 98% to 99%, and at least any of Even at the wavelength, the reflectance is 95% or more. In the case of (4) characteristics, the reflectance is about 95% to 97% in the blue light wavelength band (near 450 nm), about 97% to 98% in the green light wavelength band (near 550 nm), and the red light wavelength band (near 650 nm). ) Is about 99%, and the characteristics are green light wavelength band (near 550 nm) and red light wavelength band (650 nm).
The reflectivity in the vicinity thereof is increased by about 2% to 7% as compared with the case of the reflection surface of the conventional aluminum film (FIG. 9).

FIG. 4 is a diagram showing a configuration example of a video display device as a first embodiment. The present embodiment is a configuration example of a rear projection type image display device. In FIG. 4, 11 is an optical unit that emits image light, 12 is a reflecting mirror that reflects the emitted image light as combined light, 13 is a screen that is irradiated with the combined light to display an image, and 14 is a case. Is.
As the reflecting mirror 12, one having a reflecting surface made of a silver or silver alloy film as shown in FIG. 1 or 2 is used. The reflecting mirror 12 has reflectance characteristics such as the characteristics and characteristics shown in FIG. 3, and the image light from the optical unit 11 has a red light component and a green light component whose reflectance is higher than that of the blue light component. The light is reflected toward the screen 13 in a state of being raised. The reflectance of the red light component on the reflecting mirror 12 is about 9
The reflectance of the green light component is 8% or more and about 97% or more.

According to the configuration of the first embodiment, the reflectance of the red light component and the green light component is significantly increased (the red light component is about 7% or more) while the increase in the number of parts and the increase in cost are suppressed. The green light component can be improved by about 2 to 7% or more). Therefore, good color and image quality can be obtained while suppressing an increase in power. The screen brightness can also be improved. A reflector can also be easily manufactured.

FIG. 5 is a diagram showing a configuration example of the second embodiment of the present invention. The present embodiment is an example of the configuration of a rear projection type image display device using the red, green and blue image light projection tubes. In FIG. 5, 61 is a projection tube for red image light projection, 62 is a projection tube for green image light projection, 63 is a projection tube for blue image light projection, and 12 is as shown in FIG. 1 or FIG. A reflecting mirror 14 having a reflecting surface formed of a silver or silver alloy film is a case. The projection tubes 61, 62,
From 63, red image light, green image light, and blue image light are projected on the reflecting mirror 12, and the image light reflected by the reflecting mirror 12 is projected on the screen. The reflecting mirror 12 is
The characteristics of FIG. 3 and reflectance characteristics such as the characteristics are provided, and the image light from each of the projection tubes 61, 62, 63 is reflected according to the characteristics, and the reflectance of red image light and green image light is blue image light. Higher than the reflectance of. Each projection tube 61, 6
2, 63 may have characteristics as shown in FIG.

According to the structure of the second embodiment, as in the case of the first embodiment, the reflectance of red light and green light is greatly increased while the increase in the number of parts and the increase in cost are suppressed. Therefore, it is possible to obtain good color and image quality while suppressing an increase in electric power. The screen brightness can also be improved. The reflecting mirror 12 can also be easily manufactured.

FIG. 6 shows a third embodiment of the present invention. The present embodiment is an example of the configuration of an image display device that forms an image using a reflective display element such as a micromirror. In FIG. 6, 30 is a light source unit, 30a is a reflector that has a reflecting surface such as an elliptical surface, a parabolic surface or an aspherical surface and reflects the light of the light source in a predetermined direction, 30b is a light source such as a high pressure mercury lamp,
As shown in FIG. 1 or 2, 31 is a reflecting mirror having a reflecting surface formed of a silver or silver alloy film and having reflectance characteristics as shown in FIG. 3, and 32 is a rotating color for color light separation. A motor for rotationally driving the disc, 33 is a rotary color disc as a color separation unit, and 34 is an inner reflecting surface formed of a silver or silver alloy film, like the reflecting mirror 31, as shown in FIG. A light pipe configured to have reflectance characteristics such as
Is a first field lens, 36 is a second field lens, 37 is a reflective display element such as a micromirror, 38 is a total reflection prism, 39 is a projection lens unit, 70 is a power supply circuit, and 71 is input from the outside. A signal processing circuit for processing a video signal according to the reference numeral 72 is a drive circuit for driving each of the liquid crystal panels based on the output signal from the signal processing circuit 71. In the above configuration, the light of the light source 30b (white light)
Is reflected by the reflector 30a in a predetermined direction, the reflected light is incident on the reflecting mirror 31, and is reflected by the reflecting surface of the silver film of the reflecting mirror 31 according to the reflectance characteristic as shown in FIG. 33. The rotating color disc 33 is provided with the motor 32.
The light that is rotatably driven by and is sequentially transmitted through the red light transmission region, the green light transmission region, and the blue light transmission region in the disc to be separated into red light, green light, and blue light. The separated color lights travel on the reflecting surface of the silver or silver alloy film on the inner wall of the light pipe 34 while reflecting according to the reflectance characteristics as shown in FIG. 3, and the first and second field lenses 3
After passing through 5, 36, the light enters the total reflection prism 38. Each color light incident on the total reflection prism 38 is reflected by the reflection surface and is applied to the display element 37. In the display element 37, each of the irradiated color lights is emitted with its reflection angle changed based on the video signal, and again enters the total reflection prism 38 as reflected light containing video information. The incident light is emitted to the projection lens unit 39 side as combined light. The projection lens unit 39 magnifies the combined light as image light and projects it on a screen (not shown) to display an image. The reflective display element 37 is driven by the drive circuit 72 based on the video signal from the signal processing circuit 71, and reflects each color light at an angle corresponding to the video signal. The light source 30b, the signal processing circuit 71, and the drive circuit 72 are supplied with power from a power supply circuit 70. In the configuration of this embodiment, the optical system from the light source 30b to the projection lens unit 39 forms an optical unit, and the optical system from the reflection mirror 31 to the total reflection prism 38 forms an illumination optical system.

According to the third embodiment, the reflecting mirror 31,
Since the incident light is reflected by each of the light pipes 34 with the reflectance characteristic as shown in FIG. 3, the reflected light amount of the red light and the green light can be increased, and the display element 37 is irradiated with the reflected light. The amounts of red light and green light that are modulated and are incident on the total reflection prism 38 can be increased. Therefore, it is possible to obtain good color and image quality while suppressing an increase in power of the light source. The screen brightness can also be improved. In the illumination optical system, the optical unit, and the entire image display device, the above performance can be improved without increasing the number of parts. It is possible to suppress an increase in size and cost.

FIG. 7 shows a fourth embodiment of the present invention. This embodiment is also an example of a video display device that forms a video using a display element. In FIG. 7, 40 is a light source unit, 40
a is a reflector having a reflecting surface such as an ellipsoidal surface, parabolic surface or aspherical surface for reflecting the light of the light source in a predetermined direction, 40b is a light source such as a high pressure mercury lamp, and 41 is a plurality of condenser lenses, A first array lens for forming a plurality of secondary light sources so that the illuminance distribution in the light flux cross section is uniform, and 42 is composed of a plurality of condensing lenses, and a lens image of the first array lens 41 is formed. A second array lens for imaging, 43 is a polarization beam splitter (not shown) and 1
1/2 wavelength phase difference plate (not shown), separates the light from the second array lens 42 side into P-polarized light and S-polarized light, and after separating, either one of the both polarized light A polarization conversion element for rotating the polarization direction of the polarized light of the above and aligning it with the other polarized light, 44a, 44b are relay lenses, 45a, 4
5b and 45c are condenser lenses, 46, 47 and 48,
Reference numeral 49 denotes a reflecting mirror having a reflecting surface formed of a silver or silver alloy film as shown in FIG. 1 and having reflectance characteristics as shown in FIG. 3, and 50a denotes a blue / green reflecting dichroic as a color separating section. Mirror, 50b is also a green reflective dichroic mirror, 51a is a transmissive liquid crystal panel for red light as a display element, 51b is a transmissive liquid crystal panel for green light,
Reference numeral 51c is also a transmissive liquid crystal panel for blue light, 52 is a prism, 53 is a projection lens unit for projecting light emitted from the prism 52, 70 is a power supply circuit, and 71 is signal processing for processing a video signal input from the outside. The circuit 72 is a drive circuit for driving each of the liquid crystal panels based on the output signal from the signal processing circuit 71. In the above configuration,
The light (white light) from the light source 40b is reflected by the reflector 40a in a predetermined direction, a plurality of secondary light source images are formed by the first lens array 41, and then the secondary light source image is formed by the second lens array 42. Then, the image forming light enters the polarization conversion element 43. In the polarization conversion element 43, a P-polarized light and an S-polarized light are separated by a polarization beam splitter (not shown), and the P-polarized light is polarized by a ½ wavelength phase difference plate (not shown). The direction is rotated to be S-polarized light, which is emitted from the polarization conversion element 43 together with the S-polarized light separated by the polarization beam splitter. The S-polarized light of the white light emitted from the polarization conversion element 43 is reflected by a reflecting mirror 46 having a reflecting surface formed of a silver or silver alloy film to change its optical path, passes through a relay lens 44a, and is reflected in blue / green. It is incident on the dichroic mirror 50a. In the blue / green reflective dichroic mirror 50a, the blue and green S-polarized light is reflected by the dichroic film, and the red S-polarized light is transmitted through the dichroic film.
The S-polarized light of the red light transmitted through the blue / green reflective dichroic mirror 50a is reflected by the reflecting mirror 47 having a reflecting surface formed of a silver or silver alloy film, the optical path is changed, and the red light passes through the condenser lens 45a. It is incident (irradiated) on the transmissive liquid crystal panel 51a for light. On the other hand, the S-polarized light of blue light and green light reflected by the blue / green reflective dichroic mirror 50a is reflected by the green reflective dichroic mirror 50b.
In the green reflection dichroic mirror 50b, the green S-polarized light is reflected by the dichroic film, and the blue S-polarized light is transmitted through the dichroic film.
The S-polarized light of the green light reflected by the green reflective dichroic mirror 50b enters (irradiates) the transmissive liquid crystal panel 51b for green light through the condenser lens 45b. On the other hand, the S-polarized light of the blue light transmitted through the green reflective dichroic mirror 50b is reflected by the reflective mirrors 48 and 49 having reflective surfaces formed of a silver or silver alloy film to change the optical path,
It enters (irradiates) the transmission type liquid crystal panel 51c for blue light through the condenser lens 45c. In the transmissive liquid crystal panel 51a for red light, the S of the red light emitted from the liquid crystal panel 51a, which is modulated based on the video signal and includes video information.
The transmission type liquid crystal panel 51b for polarized light and green light is modulated based on a video signal and includes video information, and the liquid crystal panel 5
1b, the liquid crystal panel 51b and the prism 52 are emitted.
P polarized light of green light which is polarized from S polarized light by a half-wave retarder (not shown) provided between
Also, the liquid crystal panel 51 including the video information modulated on the basis of the video signal in the transmission type liquid crystal panel 51c for blue light.
The blue S-polarized light emitted from c is incident on the prism 52, is photosynthesized in the prism 52, and is emitted to the projection lens unit 53 side. The projection lens unit 53 magnifies the combined light as image light and projects it on a screen (not shown) to display an image. Each of the liquid crystal panels 51a, 51b and 51c includes a signal processing circuit 7
It is driven by the drive circuit 72 based on the video signal from No. 1, and the corresponding color lights are transmitted in a modulated state.
The light source 40b, the signal processing circuit 71, and the drive circuit 72 are supplied with power from a power supply circuit 70. In the configuration of this embodiment, the optical system from the light source 40b to the projection lens unit 53 forms an optical unit, and the optical system from the first array lens 41 to the condenser lenses 45a, 45b, 45c is illumination optical. Form a system.

According to the fourth embodiment, the reflecting mirror 46,
Since the incident light is reflected by each of 47, 48, 49 with the reflectance characteristic as shown in FIG. 3, the amount of reflected light of red light and green light can be increased, and the transmissive liquid crystal panel 5 for red light can be obtained.
The transmissive liquid crystal panel 51b for red light, which is irradiated to the 1a, is modulated by the panel, and is incident on the prism 53, and the green light.
And the amount of green light that is modulated by the panel and is incident on the prism 53 can be increased. Therefore, it is possible to obtain good color and image quality while suppressing an increase in power of the light source. The screen brightness can also be improved. In the illumination optical system, the optical unit, and the entire image display device, the above performance can be improved without increasing the number of parts. It is possible to suppress an increase in size and cost.

In the third and fourth embodiments described above, all of the reflecting mirrors in the optical unit have a reflecting surface of a silver or silver alloy film. However, the configuration is not limited to this, and a part of the reflecting mirror in the optical unit may have a reflecting surface of a silver film. Further, in the fourth embodiment, the transmissive liquid crystal panel is used as the display element, but the present invention is not limited to this, and a reflective liquid crystal panel may be used, or a micro mirror type or the like may be used. Alternatively, another type may be used. Further, as the optical unit 11 of the rear projection type image display device of the first embodiment, the optical unit of the image display device shown in FIG. 6 and FIG. 7 may be used, or an optical unit having another configuration may be used. You may use. In these cases, the reflecting surface of the silver or silver alloy film may be formed only on the reflecting mirror 12, or the reflecting mirror 12 and a part of the reflecting mirror in the optical unit may be made of silver or a silver alloy. The reflecting surface of the film may be formed, or the reflecting surface of the film of silver or silver alloy may not be formed on the reflecting mirror 12, and silver or silver may be formed on all or part of the reflecting mirror in the optical unit. You may make it form the reflective surface of the film of a silver alloy. Further, the reflecting mirror used in the present invention including each of the above-mentioned embodiments is not limited to the one whose reflecting surface is manufactured by the silver mirror reaction.

[0017]

According to the present invention, it is possible to obtain good color and image quality while suppressing an increase in power of the light source.
The screen brightness can also be improved.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration example of a reflecting mirror used in the present invention.

FIG. 2 is a diagram showing another configuration example of a reflecting mirror used in the present invention.

FIG. 3 is a diagram showing an example of reflectance characteristics of a reflecting mirror used in the present invention.

FIG. 4 is a diagram showing a first embodiment of the present invention.

FIG. 5 is a diagram showing a second embodiment of the present invention.

FIG. 6 is a diagram showing a third embodiment of the present invention.

FIG. 7 is a diagram showing a fourth embodiment of the present invention.

FIG. 8 is a diagram showing a configuration example of a conventional reflecting mirror.

FIG. 9 is a diagram showing an example of reflectance characteristics of a conventional reflecting mirror.

FIG. 10 is a diagram showing an example of energy distribution characteristics of a projection tube.

FIG. 11 is a diagram showing an example of energy distribution characteristics of a high pressure mercury lamp.

[Explanation of symbols]

1, 1 '... Base material, 2 ... Undercoat film, 2' ... Aluminum vapor deposition film, 3 ... Silver or silver alloy film, 4 ... Topcoat film, 5 ... Silicon oxide film, 6 ... Titanium oxide film , 11 ... Optical unit, 12, 31, 46, 4
7, 48, 49 ... Reflector, 13 ... Screen, 14
... case, 30, 40 ... light source unit, 30a, 4
0a ... reflector, 30b, 40b ... light source, 32 ...
Motor, 33 ... Rotating color disc, 34 ... Light pipe,
35, 36 ... Field lens, 37 reflective display element, 38 ... Total reflection prism, 39, 53 ... Projection lens unit, 41 ... First array lens, 42 ...
Second array lens, 43 ... Polarization conversion element, 44a,
44b ... Relay lens, 45a, 45b, 45c ... Condenser lens, 50a ... Blue / green reflective dichroic mirror, 50b ... Green reflective dichroic mirror,
51a ... Transmissive liquid crystal panel for red light, 51b ... Transmissive liquid crystal panel for green light, 51c ... Transmissive liquid crystal panel for blue light, 52 ... Prism, 61 ... Projection tube for projecting red image light, 62 ... Green image light Projection tube for projection 63 ... Projection tube for blue image light projection 70 ... Power supply circuit 71 ...
Signal processing circuit, 72 ... Driving circuit.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Nobuo Masuoka             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media System             Within the business division (72) Inventor Kie Kodera             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media System             Within the business division (72) Inventor Kenji Yamane             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media System             Within the business division (72) Inventor Nakamura Shige             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media System             Within the business division (72) Inventor Sadayuki Nishimura             292 Yoshida-cho, Totsuka-ku, Yokohama-shi, Kanagawa             Ceremony Hitachi Digital Media System             Within the business division F-term (reference) 2H042 DA04 DA12 DA14 DA15 DA18                       DB02 DC01 DE00                 2H099 AA11 BA09 CA00 DA00                 2K103 AA14 AA17 BC03 BC16 CA60

Claims (16)

[Claims] 1. An image display device for displaying image light on a screen by reflecting image light emitted from a projection lens or a projection tube of an optical unit with a reflecting mirror, wherein the reflecting mirror is formed of a silver or silver alloy film. An image display device having a reflecting surface, wherein the reflectance of the red light component and the green light component of the light incident on the reflecting mirror can be made higher than the reflectance of the blue light component. 2. An optical unit for a video display device, which irradiates a display element with light from a light source side to form an optical image according to a video signal, wherein a reflecting surface has a reflecting surface formed of a silver or silver alloy film. Is provided in the optical path, and the optical path direction is converted by the reflecting mirror. 3. An optical unit for a video display device, wherein light from a light source side is applied to a display element by an illumination optical system to form an optical image according to a video signal, wherein the illumination optical system is a light source side. Having a color separating portion for separating light into red, green, and blue light, and a reflecting surface made of a film of silver or a silver alloy, between the light source and the color separating portion or between the color separating portion and the display element. And a reflection mirror disposed between the reflection mirror and the reflection mirror, and is configured so that the reflectance of the red light component and the green light component of the light incident on the reflection mirror can be made higher than the reflectance of the blue light component. And optical unit. 4. An optical unit for a video display device, wherein a light from a light source side is applied to a display element by an illumination optical system to form an optical image according to a video signal, wherein the illumination optical system is a light source side light. It has a polarization conversion element that aligns the polarization direction of, a color separation unit that separates the polarized light that has the aligned polarization direction into red, green, and blue color lights, and a reflective surface formed of a silver or silver alloy film. A reflection mirror that is disposed between the polarization conversion element and the color separation unit and reflects polarized light to enter the color separation unit, and reflects the red light component and the green light component in the polarized light. An optical unit characterized by a structure capable of increasing the reflectance higher than the reflectance of a blue light component. 5. An optical unit for a video display device, wherein a light from the light source side is applied to a display element by an illumination optical system to form an optical image according to a video signal, wherein the illumination optical system is a light from the light source side. It has a polarization conversion element that aligns the polarization direction of, a color separation unit that separates the polarized light that has the aligned polarization direction into red, green, and blue color lights, and a reflective surface formed of a silver or silver alloy film. A reflecting mirror that is arranged in the subsequent stage of the color separation unit and that reflects the respective color lights to convert the respective optical path directions, and the reflectance of the color-separated red light and green light,
An optical unit characterized in that the reflectance of blue light can be increased and each of the reflected color lights is applied to the display element. 6. An optical unit for a video display device, wherein light from a light source side is applied to a display element by an illumination optical system to form an optical image according to a video signal, wherein the illumination optical system comprises light from the light source side. It has a polarization conversion element that aligns the polarization direction of, a color separation unit that separates the polarized light that has the aligned polarization direction into red, green, and blue color lights, and a reflective surface formed of a silver or silver alloy film. A first reflecting mirror disposed between the polarization conversion element and the color separation section for reflecting polarized light to enter the color separation section; and a reflecting surface formed of a silver or silver alloy film. A second reflecting mirror which is arranged at a subsequent stage of the color separating section, reflects the respective color lights, converts the respective optical path directions, and makes the light incident on the display element; and Increase the reflectance of red light component and green light component in light more than the reflectance of blue light component As well as the ability, by the second reflecting mirror,
An optical unit having a configuration capable of increasing the reflectance of the color-separated red light and green light above the reflectance of blue light. 7. The reflector has an incident light wavelength of about 550 n.
The optical unit according to claim 2, wherein the reflectance of light in the range of m to 700 nm is 95% or more. 8. Either or both of the first and second reflecting mirrors have an incident light wavelength of about 550 nm to 700 n.
The optical unit according to claim 6, wherein the reflectance of light in the range of m is 95% or more. 9. An image display apparatus for irradiating light from a light source side to a display element to form an optical image according to an image signal, having a reflection surface formed of a silver or silver alloy film, and in an irradiation optical path. And a drive circuit for driving the display element based on a video signal, and a power supply circuit for supplying power to the light source and the drive circuit. Video display device. 10. A video display device for irradiating a display element with light from a light source side to form an optical image according to a video signal, wherein the light from the light source side is separated into red, green and blue color lights. Section and a reflecting surface formed of a silver or silver alloy film, and is disposed between the light source and the color separation section or between the color separation section and the display element, and white light or color separation is performed. A reflecting mirror capable of increasing the reflectance of the red light component and the green light component of each of the color lights thus produced to a level higher than the reflectance of the blue light component, a motor for driving the color separation unit, and the display element based on a video signal. An image display device comprising: a drive circuit for driving the motor and a drive circuit for driving the motor; and a power supply circuit for supplying electric power to the light source and the drive circuit. 11. A video display device for irradiating light from a light source side to a display element to form an optical image according to a video signal, wherein a polarization conversion element for aligning the polarization direction of light from the light source side and a polarization direction are aligned. Between the polarized light conversion element and the color separation section, a color separation section for separating the polarized light thus obtained into red, green, and blue color lights, and a reflection surface formed of a silver or silver alloy film are provided. A reflecting mirror arranged to reflect polarized light to enter the color separation unit; a drive circuit for driving the display element based on a video signal; and a power supply circuit for supplying power to the light source and the drive circuit. An image display device, comprising: a structure for displaying an image in a state in which the reflectance of a red light component and a green light component of polarized light can be increased more than the reflectance of a blue light component. 12. In a video display device for irradiating light from a light source side to a display element to form an optical image according to a video signal, a polarization conversion element for aligning the polarization direction of light from the light source side and a polarization direction for the polarization direction are aligned. It has a color separation part that separates the polarized light into red, green, and blue color lights, and a reflection surface formed of a silver or silver alloy film. And a drive circuit that drives the display element based on a video signal, and a power supply circuit that supplies power to the light source and the drive circuit. , The reflectance of red light and green light separated by the above color,
An image display device characterized by being configured to display an image in a state where the reflectance of blue light can be increased. 13. A video display device for irradiating light from a light source side to a display element to form an optical image according to a video signal, wherein a polarization conversion element for aligning the polarization direction of light from the light source side and a polarization direction are aligned. Between the polarized light conversion element and the color separation section, a color separation section for separating the polarized light thus obtained into red, green, and blue color lights, and a reflection surface formed of a silver or silver alloy film are provided. A first reflecting mirror arranged to reflect polarized light to be incident on the color separation section; and a reflection surface formed of a silver film, arranged at a rear stage of the color separation section to reflect each color light. A second reflecting mirror that changes the direction of each optical path to enter the display element; a drive circuit that drives the display element based on a video signal; and a power supply circuit that supplies power to the light source and the drive circuit. And a red light component and a green light component in the polarized light by the first reflecting mirror. And the reflectance of the blue light component can be increased, and by the second reflecting mirror,
An image display device characterized in that it displays an image in a state in which the reflectance of the red light and the green light separated by the color can be increased more than the reflectance of blue light. 14. The reflector comprises a base material, an undercoat film formed on the base material to a thickness of about 0.5 μm to 5 μm, and a reflective surface provided on the undercoat film. And a protective film which is provided on the silver or silver alloy film and which contains at least one of a ceramic material and a vaporizable rust preventive agent. Item 6. The optical unit according to any one of items 2 to 5. 15. The undercoat film of the reflecting mirror is made of a material containing at least one of an ultraviolet curable acrylic resin, an ultraviolet curable epoxy resin, an ultraviolet curable polyurethane resin, and a polyester resin. 14. The optical unit according to 14. 16. The reflector comprises a base material, an undercoat film having a thickness of about 0.5 μm to 5 μm formed on the base material, and a reflection surface provided on the undercoat film. And a protective film which is provided on the silver or silver alloy film and which contains at least one of a ceramic material and a vaporizable rust preventive agent. 13. The video display device according to item 1, 9, 10, 11 or 12.