JP2002182305A - Projection type display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a projection type display device which does not increase in scale more than needed, is easy to handle, has high visibility, consumes less electric power, is compact and is suitable for displaying images visible from a specific direction. SOLUTION: This device has a projection device 4 which emits image display light L and a screen 5 to which this image display light L is projected. This screen has a reflection layer of the image display light L and a retroreflective material to be disposed on this reflection layer.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is mounted on a vehicle such as an aircraft, a ship, a vehicle running on the ground, a construction machine, an agricultural machine, or the like, or an outdoor work machine, and provides information to a specific viewer. The present invention relates to a projection-type display device suitable for:

[0002]

2. Description of the Related Art Display devices for vehicles and outdoor working machines are used for various purposes such as providing operation information to drivers and operators, providing incidental information to other crew members, and providing service information to passengers. It is used for These display devices are in an environment where the amount of incident external light, including sunlight, changes every moment in accordance with the operating conditions such as changes in the direction of the vehicle and changes in the surroundings of the road when traveling on the ground.

[0003] Among these display devices, display devices for providing services to passengers and providing related information to crew members have a relatively high degree of freedom in mounting positions, so that they are located in an area that is not affected by changes in external light quantity. Can be installed.

[0004] Further, in the case of a display device for a driver or a driver, which is always checked at the time of operation, such as a speedometer, for example, an instrument of a car is designed so that external light does not enter as directly as possible. It is installed at least in an area that blocks direct sunlight, such as on a panel. In addition, a display device typified by a head-up display (HUD) that changes the display luminance in accordance with the external light amount is employed to provide a display image that is visible even when the external light amount changes.

[0005] In working devices such as various vehicles and outdoor working machines, it is necessary for a viewer who is an operator of the working device to visually recognize in a specific direction for driving or operation in accordance with the operation and working conditions. There are display devices that display images. For example, in aircraft, for the purpose of dropping supplies and tracking target objects, as a display device that displays a ground map or infrared image below the area in flight,
A drop position display device and the like arranged below and in front of the operator are provided. In an aircraft such as a helicopter that can be stopped in the air, a lower visual field display device that is arranged at the lower right or lower left of the pilot as a display device for displaying images taken by a visible light or infrared light camera that photographs the takeoff and landing area. Will be useful. For vehicles and ships, as a display device for displaying images taken by left, right and rear cameras, an auxiliary visual field display device or the like arranged in that direction is being studied. For vehicles that need to be handled by passengers, use a camera that is located at a position where you can look over the vehicle and getting on and off the ground to overlook the cabin door, so that the display image can be viewed at the same time as the direct view, so that the blind spot is eliminated in the part of the passenger handling As a display device for displaying a captured image, a railway platform image display device or the like is provided. In an outdoor work machine, a display device for displaying an image captured by a camera installed at a position overlooking the work target on the machine or on the ground side so as to eliminate a blind spot of the work target, for example, a camera attached to a crane boom tip Is provided at a position where a work object such as a cargo object suspended by the boom can be viewed directly and simultaneously.

[0006]

The above-described display devices that require a viewer to view in a specific direction are described below.
Although it is not necessary to always display the information during operation, in a specific situation, the information obtained from the image is important in determining the success or failure of the work and the safety aspect. For this reason, the ability to reliably view the displayed image when required is required.
However, when the display device is arranged at a position suitable for a viewer to view in a specific direction, there is a problem that visibility of the display device is reduced due to external light such as sunlight or illumination light. Conventionally, in order to secure good visibility even under the influence of such external light, a large-scale self-luminous display device has been provided. Therefore, there is a problem that the installation space increases and the manufacturing cost increases. To solve this problem, it is conceivable to use a head-mounted display device, but it is necessary to attach and detach the display device, and in a narrow space, the members attached to the head may interfere with moving the body. However, there is a problem that the restriction is added.

An object of the present invention is to provide a projection display device which can solve the above problems.

[0008]

The present invention is applied to a projection type display device having a projection device for emitting image display light and a screen on which the image display light is projected. A first feature of the present invention is that the screen has a reflective layer for the image display light and a retroreflective material provided on the reflective layer, and is reflected on the reflective layer via the retroreflective material. That is, the image display light is guided to the eyes of the viewer. According to this configuration, the image display light incident on the screen is reflected by the screen, and then emitted from the screen so as to be distributed in a narrow range centered on the optical path incident on the screen. As a result, the utilization efficiency of the image display light emitted from the projection device is improved, and by placing the viewpoint near the optical path of the incident light of the image display light to the screen, the utilization efficiency of the light is increased even at a low light source luminance, and the viewer can use the screen. The above clear display image can be visually recognized. As a result, the projection display device of the present invention allows a viewer who is an operator of the working device to visually recognize the operating device such as a vehicle or an outdoor working machine in a specific direction for driving or operation in accordance with the operation or work situation. This is the most suitable for displaying an image that needs to be performed.

Preferably, a large number of transparent fine particles are arranged on the reflective layer as the retroreflective material. The screen can have a retroreflective function by refracting the image display light at the time of entering and exiting the fine particles. In order to obtain a clear image, the maximum cross-sectional area of each microparticle is preferably set to be equal to or less than the pixel area of a display image formed by image display light on a screen, and further,
It is preferable that the distance between the centers of the adjacent fine particles be equal to or less than the distance between the centers of the adjacent pixels.

A second feature of the present invention is that the screen has a reflective layer for the image display light and a light absorbing material provided on the reflective layer, and the angle of incidence of the image display light on the screen. When the difference between the light absorbing material and the incident angle of the light other than the image display light is large, the amount of light other than the image display light absorbed by the light absorbing material is larger than when the difference is small. Thereby, light other than the image display light incident on the screen can be reduced, and the contrast of the displayed image can be improved.

The light absorbing material preferably covers the reflective layer and has a large number of minute through holes formed therein, and the inner peripheral surface of each minute through hole is preferably a light absorbing surface. Thereby, the image display light incident on the screen along the inner peripheral surface of the minute through hole is reflected by the reflective layer, and the light having an incident angle larger than the incident angle of the image display light on the screen is absorbed by the light absorbing surface. be able to. In order to obtain a clear image, the maximum cross-sectional area of each minute through hole is preferably set to be equal to or less than the pixel area of a display image formed by image display light on a screen, and further, adjacent minute through holes. Is preferably equal to or less than the center-to-center distance between adjacent pixels. Also, in order to effectively utilize the image display light without being absorbed by the light absorbing material, the incident angle of the image display light with respect to the surface of the reflective layer is set to be approximately a right angle, and the light absorbing surface is raised substantially at a right angle from the surface of the reflective layer. Is preferred.

It is preferable that both of the first feature and the second feature of the present invention are provided. In this case, transparent fine particles are used as the retroreflective material in each fine through hole formed in the light absorbing material. It is preferable to be arranged on the reflective layer by being inserted into the inside. Thereby, effective use of the image display light and absorption of light other than the image display light can be effectively performed.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A lower display device 1 of an aircraft shown in FIG. For example, when an object is dropped from an aircraft, a drop target area below the fuselage is displayed during a mission, and in an aircraft hovering during takeoff and landing such as a helicopter, an image of the lower body area is displayed during takeoff and landing. Conventionally, a window for securing a field of view below the fuselage was provided on the fuselage, but by adopting the lower display device 1 instead of the window,
The degree of freedom in fuselage design has been increased.

The lower display device 1 is constituted by a projection type display device, and is mounted on a ceiling surface of the fuselage near the upper part of the operator's head 2.
And a screen 5 arranged at a position where the operator in the cockpit looks downward when looking downward. In the figure, the dashed line indicates the image display light L. The projection device 4 and the screen 5 are stored in a case 6 when not needed.

As shown in FIG. 2, the projection device 4 removes infrared light from a light source having a reflector 13 and a halogen bulb 14 in a frame 11 by using a cold mirror 15 to remove the visible light wavelength. Is reflected to the condensing lens 16, and the light condensed by the condensing lens 16 illuminates the transmissive liquid crystal display panel 17. The liquid crystal display panel 17 displays the photographed image when an image signal S sent from a camera (not shown) that photographs the lower part of the body is input via a liquid crystal drive circuit 18. As a result, the light transmitted through the liquid crystal display panel 17 becomes the image display light L. The image display light L is emitted through the lenses 19, 20, and 21. The image display light L emitted from the projection device 4 passes through the vicinity of the viewpoint of the operator 2 and is projected on the screen 5.

As shown in FIG. 3, the screen 5 is
It comprises a reflective layer 31 for the image display light L, a refraction / absorption layer 32 covering the reflection layer 31, and a transparent protective material 33 covering the reflection layer 31 and the refraction / absorption layer 32. Thus, the image display light L is projected from the projection device 4 onto the screen 5, whereby a real image serving as a display image is formed on the diffuse reflection surface of the reflection layer 31. The viewpoint of the pilot 2 who visually recognizes the image on the screen 5 is located near the optical path of the image display light L incident on the screen 5.

The reflection layer 31 is formed by applying an adhesive 31b containing a white pigment such as titanium oxide on a base material 31a, and the surface side thereof is a diffuse reflection surface.
As a material of the base material 31a, for example, an aluminum alloy can be adopted from the viewpoint of weight reduction and dimensional stability.

The refraction / absorption layer 32 is composed of a light absorption material 32a and a retroreflection material 32b provided on the reflection layer 31. The light absorbing material 32a covers the reflection layer 31 and is provided so that a large number of minute through holes 32a 'are regularly arranged by laser processing or the like. As a material of the light absorbing material 32a, for example, a stainless steel plate or black acrylic resin can be adopted, and its thickness can be about 0.05 mm to 0.3 mm if it is a stainless steel plate, and if it is black acrylic resin. It can be about 0.5 mm. The maximum cross-sectional area of each minute through hole 32a 'is:
It is set to be equal to or less than the pixel area of a display image formed by the image display light L on the screen 5. The distance between the centers of the adjacent minute through holes 32a 'is set to be equal to or less than the distance between the centers of the adjacent pixels. The area of the portion where the reflection layer 31 is covered with the light absorbing material 32a is preferably as small as possible in order to effectively use the image display light L. Therefore, the center of the adjacent minute through-holes 32a 'is preferable. The smaller the distance, the better. The light absorbing material 32a has a high light absorptivity. For example, when the material of the light absorbing material 32a is a stainless steel plate, a black film treatment is performed, and a surface treatment is performed so that the entire surface becomes a black matte state. In this case, the light absorption rate is increased by using a black acrylic resin, and the light absorption rate is increased by setting the material itself to black. This light absorbing material 32a is adhered to the reflective layer 31 via an adhesive 31b. The inner peripheral surface of each minute through hole 32a '
A light absorbing surface is formed substantially along the incident direction of the image display light L.
In this embodiment, the projection device 4 is configured such that the image display light L is incident on the surface of the reflective layer 31 from a direction substantially perpendicular to the surface.
Are disposed, and the light absorbing surface is substantially perpendicular to the surface of the reflective layer 31.

The retroreflective material 32b is composed of another number of transparent fine particles 32b 'arranged on the reflective layer 31, and is inserted into each minute through hole 32a' one by one. It is adhered via an adhesive 31b. The maximum sectional area of each fine particle 32b 'is set to be equal to or less than the pixel area of a display image formed by the image display light L projected on the screen 5 by the projection device 4. Also,
The distance between the centers of the adjacent fine particles 32b 'is set to be equal to or less than the distance between the centers of the adjacent pixels. In order to enhance the retroreflective function, it is preferable that each microparticle 32b 'is a spherical glass bead having a high refractive index such as titanium-barium glass. The diameter of each fine particle 32b 'may be determined according to the pixel area of the display image, for example, 100 μm.
m.

The transparent protective material 33 is made of a material having a low refractive index such as, for example, a fluorine-based resin.
b 'is filled in a flow state into each of the inserted minute through holes 32a', and is cured after being applied to the refractive absorption layer 32.

According to the above configuration, most of the image display light L emitted from the projection device 4 and reaching the screen 5 is, as shown by arrows in FIG.
The light is refracted at the time of incidence into and out of b ′, is reflected by the reflective layer 31, and is refracted again at the time of incidence into and out of the fine particles 32b ′. As a result, the screen 5 has a retroreflective function, and the image display light L is retroreflected and emitted from the screen 5 so as to be distributed in a narrow range centered on the optical path incident on the screen 5. Further, when the difference between the incident angle of the image display light L to the screen 5 and the incident angle of the light other than the image display light L indicated by the dashed arrow in the drawing is large, the light absorbing surface of the light absorbing material 32a is smaller than when the difference is small. The amount of absorption of the light La other than the image display light L at the step S is increased.
Thereby, the utilization efficiency of the image display light L emitted from the projection device 4 is increased, and the pilot 2 can visually recognize a bright display image even with a low light source luminance. Further, light La other than the image display light L incident on the screen 5 can be reduced, the contrast of the displayed image can be improved, and a good visual recognition state can be obtained even with a low light source luminance. Therefore,
The pilot 2 can visually recognize a high-contrast clear image projected on the screen 5. In addition, the power consumption of the projection device 4 can be reduced, heat radiation measures can be easily made, and the size can be reduced.

The present invention is not limited to the above embodiment. For example, the direction in which the image display light L is incident on the screen is not limited to a direction substantially perpendicular to the surface of the reflective layer, and may be incident from a direction inclined with respect to the perpendicular direction.
It is preferable that the light absorbing surface also be along a direction inclined with respect to a substantially perpendicular direction of the surface of the reflective layer so as to be along the incident direction of the image display light L. Alternatively, only the retroreflective material 32b may be provided on the reflective layer 31 without providing the light absorbing material 32a. Alternatively, only the light absorbing material 32a may be provided on the reflective layer 31 without providing the retroreflective material 32b. Also,
As the retroreflective material 32b, instead of the fine particles 32b ',
For example, a known retroreflective paint may be applied on the reflective layer 31.

[0023]

According to the present invention, a projection type suitable for displaying an image viewed from a specific direction, which is easy to handle without being unnecessarily large, has high visibility, consumes little power, and is compact. A display device can be provided.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a use state of a projection display device according to an embodiment of the present invention.

FIG. 2 is a configuration explanatory view of a projection device according to an embodiment of the present invention.

FIG. 3 is a diagram illustrating a configuration of a screen according to the embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Lower display device (projection display device) 4 Projection device 5 Screen 31 Reflective layer 32a Light absorbing material 32a 'Micro through-hole 32b Retroreflective material 32b' Fine particles

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G03B 21/10 G03B 21/10 Z 21/60 21/60 Z H04N 5/74 H04N 5/74 CF term (Reference) 2H021 BA02 BA09 2H088 EA13 EA23 HA21 HA28 MA01 MA02 MA20 3D044 BA24 BA26 BA27 BB01 BB03 BB04 BB07 BC25 BD01 5C058 BA23 BA35 EA33

Claims (6)

[Claims] 1. A projection display device comprising: a projection device for emitting image display light; and a screen on which the image display light is projected, wherein the screen includes a reflective layer for the image display light, and a reflective layer on the reflective layer. Wherein the image display light reflected on the reflective layer via the retroreflective material is guided to the eyes of a viewer. 2. The projection display device according to claim 1, wherein a large number of transparent fine particles are arranged on the reflective layer as the retroreflective material. 3. The screen has a light absorbing material provided on the reflective layer, and when the difference between the incident angle of image display light and the incident angle of light other than image display light on the screen is large. 3. The projection display device according to claim 1, wherein the amount of light other than the image display light absorbed by the light absorbing material is larger than that of a small case. 4. The light-absorbing material covers the reflective layer and has a large number of minute through-holes formed therein. 4. The projection display device according to claim 3, wherein a material is inserted. 5. A projection type display device comprising: a projection device for emitting image display light; and a screen onto which the image display light is projected, wherein the screen has a reflective layer for the image display light, and a reflective layer on the reflective layer. A light absorbing material provided on the screen, and when the difference between the incident angle of the image display light to the screen and the incident angle of light other than the image display light is large, the image display by the light absorbing material is smaller than when the difference is small A projection display device characterized in that the amount of light other than light absorbed is increased. 6. The projection type according to claim 5, wherein the light absorbing material covers the reflection layer and has a large number of minute through holes, and the inner peripheral surface of each minute through hole is a light absorbing surface. Display device.