KR200164933Y1 - Reflecting screen - Google Patents

Abstract

The present invention relates to a reflective screen

Part of the image of the projector incident on the screen surface is scattered on the surface by forming a scattering surface having a suitable scattering and a suitable transmittance on the surface, forming a transmission surface of a suitable thickness on the rear surface, and then forming a reflective surface on the rear surface. Some of them are transmitted and then reflected from the reflecting surface, scattering again from the screen surface to increase the brightness more than twice and reflect the incident light source at the same angle, thereby improving the resolution of the projector depending on the brightness and angle of the screen. will be.

Description

Reflective Screen {REFLECTING SCREEN}

According to the present invention, a scattering material is formed on the backside of a part of the scattering surface which partially transmits a part of the screen, and scattering and reflection are made possible in the city, so that the brightness of the incident image is the position of the audience. It is effective to remarkably increase the resolution of the screen by making it reflect.

The present invention relates to a projection screen, and more particularly, to a projection screen in which a reflection screen and a scattering function are combined to increase resolution and increase brightness against external light.

A general screen is a scattering screen having only a scattering function, such as 'a' in FIG. 1, and incident light scatters in all directions.

Therefore, such a screen has a very low efficiency other than the amount of light of a projector such as a projector, and the brightness is sharply reduced in any external light.

In order to improve this, there is a glass glass screen produced by Izumi Chemical Co., Ltd. of Japan recently, but the brightness is improved, but the reflection characteristic of glass glass is a regression property in which light is reflected back to the incident direction. When the projector 3 is installed on the ceiling as described above, the main light source of the projector 3 projected from the ceiling returns to the ceiling, and the main light source of the projector 3 projected from the bottom as shown by 'I' in FIG. 2 returns to the bottom. do.

In this way, since the regression direction returns to the incident direction irrespective of the adjustment of the angle of the screen, the brightness of the observer 4 is returned to the observer 4 as it is. The disadvantage arises.

In order to solve the above problem, the incident light incident from the projector 3 is partially scattered at the screen surface, is reflected at the reflective surface of the back surface, and is scattered again at the screen surface. Reflect the light at the opposite angle and raise the screen brightness by 25 gain over 2 gain (known as screen brightness = Gain) so that the main light source of the projector is reflected toward the viewer's position and external light is By reflecting this, the brightness of the screen can be increased and the resolution can be increased.

As mentioned above, the reason why the screen brightness is 2-25 gain is that it is a normal scattering screen (normal brightness 0.8-1 gain) when the gain is 2 gain or less, and the reflective screen is impossible, and when the gain is 25 gain or higher, the reflectance is too high. This is because the left and right viewing angles of the screen become too narrow

1 is an explanatory diagram of a conventional screen

2 is a diagram illustrating the operation of a conventional screen

3 is a screen configuration diagram of the present invention

4 is an explanatory view of the screen operation of the present invention

Brief description of symbols for names in the drawings

3. Projector 5. Reflective Screen 51. Scattering Surface 52. Transmissive Surface

53. Reflective surface 54. Support surface

Hereinafter, the configuration of the present invention will be described with reference to FIG. 3.

3 is a reflection surface 53 formed of a scattering surface 51 on the surface of the construction of the screen 5 according to the present invention and a transmissive surface 52 on the back surface thereof, and then formed by aluminum deposition on the back surface thereof. ) And a support surface 54 for protecting and supporting the reflective surface 53 on the back surface thereof.

The scattering surface 51 particle size at this time is comprised between 0,05 micrometers and 300 micrometers.

The reason for this is that when the scattering surface 51 is 300 µm or more, there is no room for light to pass through, so it is difficult to display the reflectance of the screen surface by more than 2 gains. This is because formation scattering function is deteriorated to 25 gain or more.

The surface particles of the reflecting surface 53 also have the same logic.

The thickness of the transmissive surface 52 is 2 μm or more and 500 μm or less, but when the thickness is 2 μm or less, the surface particles also have no room for composition, and when the thickness is set to 500 μm or more, the reflection surface 53 is reflected. The difference between the image and the image scattered from the surface is large, resulting in an afterimage of the image, thereby degrading the resolution.

The present invention configured as described above

As shown in FIG. 3, part of the incident light is scattered on the surface, and part of the light is transmitted and reflected on the reflecting surface, and then scattered on the surface, resulting in more than two times the brightness of the conventional screen. .

As such, the present invention reflects the main light source of the incident projector 3 as shown in FIG. 4 at the same angle as the incident angle with respect to the horizontal angle of the screen 5.

Therefore, the reflection angle of the projector can be adjusted in any direction according to the adjustment of the screen angle as shown in FIG.

As shown in the diagram 'B' of FIG. 4, the light source of the projector 5 projected from below may also adjust the reflection angle by the same method.

In particular, the present invention, such as 'd' 'ma' of FIG. 4, the illumination light source at the viewer's position to the outside, the main light source of the projector can be adjusted to the viewer's position, so that a clear image can be displayed even in a bright place.

The present invention can be used in various ways in combination with the structure of a roll (roll) screen, a motorized screen or a flat fixed screen, which is a structure of a known conventional scattering screen.

Therefore, the present invention, unlike the conventional scattering screen or regression screen, by properly adjusting the reflection angle of the external light and the main light source, it is possible to display a clear image even in a bright place.

Claims (2)

In projection screen The screen surface constitutes a scattering surface 51 formed with a particle size of 0.05 μm to 300 μm On the back side, a transparent surface 52 having a thickness of 2 μm to 500 μm was formed. The reflective surface 53 is formed on the back surface of the transmission surface 52 The reflective surface of the screen is formed by 2-25 gain (GAIN) Part of the image incident on the screen surface is scattered and part is transmitted to reflect on the reflective surface 53 Reflective screen characterized in that the viewing direction of the incident light source can be arbitrarily adjusted according to the screen angle The reflective screen of claim 1 Reflective screen combined with conventional known roll or motorized structures