KR0118688Y1 - Projector lighting system - Google Patents

Abstract

The present invention relates to an illumination system of a liquid crystal projector that can improve the brightness and uniformity of brightness on the screen. In the configuration of the illumination system according to the present invention, in the configuration of the conventional liquid crystal projector (FIG. 1), an additional lens 12 having a local refractive power on the center of the optical axis is installed between the light source and the condenser lens or the projection target. Aspheric lens having a feature that the refractive power is converted to zero or positive while the curvature from the center increases according to the conditions of the illumination system, the diameter of the portion having a negative refractive power on the center of the lamp It is smaller than the diameter of the reflecting mirror and smaller than the height of the projection target.

According to the present invention, in the general illumination system structure of the projector, by inserting a negative refractive power lens having a spatially different refractive power between the light source and the condenser lens (or projection target), the brightness of the light projected on the screen and the brightness on the screen There is an effect that can improve the homogeneity of, and in this regard, it is possible to increase the design freedom of the optical system length, and also to reduce the central focusing speed of light at the projection target.

Description

Illumination system of the projector

1 is a view showing a basic optical system of a conventional liquid crystal projector.

2 is a view for explaining the distribution of light according to the direction of light rays and the distance from the light source when using a reflector of the arc light source.

3 is a view showing the direction of the light beam according to the light emitting position in the reflector.

4 is a view showing the change of light beam when the concave lens is inserted.

5 is a view showing the membership of the illumination system according to the present invention.

6 is a view showing an optical system of the liquid crystal projector according to the present invention.

* Explanation of symbols for main parts of the drawings

1: reflector 2: light source

4: condenser lens 5: liquid crystal panel

6: Projection lens 12: Lens having negative refractive power

The present invention relates to an illumination system of a projector, and more particularly, to an illumination system of a liquid crystal projector that can improve brightness and uniformity of brightness on a screen.

In general, a projector has a basic optical configuration of a white light source, an illumination system for enhancing light efficiency, a projection target, and a projection lens that projects the projection target on a screen.

A liquid crystal projector is an example of a projector in which the range of use is expanding in recent years.

The basic optical system configuration of the liquid crystal projector includes a light source 2 that is a white light emitter, a reflector 1 that directs light emitted from the light source to a projection target, and a filter that blocks ultraviolet rays and infrared rays, as shown in FIG. (3), a condenser lens 4 for condensing light, a liquid crystal panel 5 for converting image information of an electrical signal as a projection target to make an image, and an optical image obtained through the panel, on a screen 7 It consists of a projection lens (6) for projecting on.

Here, a near arc radiation metal halogen lamp is used as the light source 2, and a parabolic glass reflector is used as the reflector 1 for primary condensing of the light emitted therein as a projection target.

The optical operation principle of the liquid crystal projector is as follows. The light emitted from the near arc tube of about 5 mm is directed to the target in the form of primary condensing by the parabolic reflector 1, and the infrared and ultraviolet rays having double thermal characteristics are blocked by the filter 3 and visible light is emitted. Only the light is penetrated and directed to the target. This light is recondensed by the condensing lens 4 and transmitted to the liquid crystal panel 5 having the image information made by the electric image signal, so that it is converted into image information of the target and converged back into the projection lens. At this time, the main function of the condenser lens 4 is to focus the transmitted light to the projection lens (6). The transmitted optical image information is magnified and projected by the projection lens 6 to form an image on the screen 7.

Here, the operation state of the illumination system consisting of the arc light source 2 and the reflector 1 will be described with reference to FIG. 2.

The position of the light emitting portion, i.e., the reflector 1 of both electrodes of the light source 2, is located at the focal point F of the reflector 1, one end of which is larger than the focus point on the central axis line of the reflector 1; The reflection characteristic of the reflector 1 is that the light emitted from the focal point is reflected from the parabolic plane and proceeds parallel to the optical axis, and the light emitted from the position B larger than the focal point is reflected toward the center from the parabolic plane. Therefore, as can be seen in FIG. 2, the amount of light reflected by the reflector 1 has a greater amount of light at the center portion than a peripheral portion up to a certain distance from the end surface of the reflector 1. Meanwhile, referring to FIG. 3, it can be seen that the light emitted at the position A smaller than the focal point F travels in the direction emitted by the reflector 1. In this case, since the emitted light does not enter the projection target, the amount of light increases. Therefore, when considering the light efficiency, the lamp light emitting part position of the light source 2 is generally placed as shown in FIG. In this case, in order to satisfy the uniformity between the center and the periphery of the screen at a level undetectable by the human eye, the projection target (here, the liquid crystal panel) must be placed more than a predetermined distance from the lamp surface. As mentioned above, since the main function of the condenser lens 4 is to focus light onto the projection lens 6, the role of correcting the brightness ratio is not large.

As described above, in the conventional illumination system configuration, there is a limitation in increasing the degree of freedom of positioning with respect to the projection target while simultaneously improving the brightness on the screen and the uniformity of the brightness. Because the position from the light source 2 of the projection target is a large factor that influences the length of the entire optical system, it is important to expand its design freedom.

More specifically, in order to secure the brightness ratio, the position of the light emitting part of the light source or the position of the projection target should be changed. At this time, the loss of brightness or the size of the set generally appear. On the contrary, if the focus is on brightness or set size, it becomes difficult to secure a good brightness ratio.

On the other hand, when the central light collecting speed increases, the loss due to heat of the polarizing plate or LCD is likely to occur.

Accordingly, an object of the present invention is to partially concave around an optical axis between a light source and a condenser lens in an illumination system of a conventional projector so as to provide a degree of freedom in positioning a projection target while simultaneously improving brightness and brightness ratio on a screen of a liquid crystal projector. It is to provide a configuration of an illumination system for installing an additional lens having a lens shape.

The configuration of the illumination system according to the present invention is shown in FIG. 5 in the above-described configuration of the conventional liquid crystal projector (FIG. 1) above the center of the optical axis between the light source 2 and the condenser lens 4 or the projection target. As an aspherical lens having an additional lens 12 having negative refractive power, the main feature is that the curvature from the center is increased according to the illumination system conditions, and the refractive power is converted to positive (+). The diameter of the negative refractive portion on the center portion is smaller than the diameter of the lamp reflecting mirror and smaller than the height of the projection target.

Hereinafter, the operation of the lighting system according to the present invention in detail.

In general, the position of the light source with respect to the reflector 1 is conventionally positioned so that the projection target can be converged, so that the amount of light incident on the target is increased to an appropriate amount.

When the concave lens 10 is inserted between the lamp and the projection target as shown in FIG. 4, the light beam is refracted in the direction away from the optical axis with respect to the original traveling direction, and thus the negative refractive power is inserted into the lens. The light focused at the center spreads around. However, since the light incident on the edge of the target before insertion of the concave lens is also diffused out of the corner of the target by the insertion of the concave lens, loss of light follows.

Therefore, in the present invention, the shape of the lens 12 having negative refractive power, which is additionally inserted in FIG. 5, is provided with negative refractive power so as to have a diameter smaller than the diameter of the lamp reflector 1 and the target height in the optical axis portion. By not giving refractive power in a large area or giving a very small positive refractive power, the light in the center is diffused to the periphery and the light incident on the periphery proceeds or converges to the center. Act to secure.

In practice, the shape and position of the lens having the optimum negative refractive power may be found by the design of the optical system.

6 shows an optical system of the liquid crystal projector to which the illumination system configuration of the present invention is applied. The light emitted from the light source 2 of the 5 mm arc tube is first collected by the reflector 1 and passes through the filter 12 having a partially negative refractive power according to the present invention through the filter 3. In 4), the brightness uniformity of the light focused on the liquid crystal panel 5 and the projection lens 6 is corrected.

As described above, according to the present invention, in the general illumination system structure of the projector, by inserting a negative refractive power lens having a spatially different refractive power between the light source and the condenser lens (or projection target), the brightness of the light projected on the screen There is an effect that can increase and improve the homogeneity of the brightness on the screen.

In this regard, it is possible to increase the design freedom of the length of the optical system, and also to relax the central focusing speed of the light at the projection target, thereby facilitating cooling, thereby reducing the noise of the cooling fan, and reducing the components due to high temperature. There is an advantage that can prevent the burn out.

Claims (6)

A white light source, a reflector for first focusing the light emitted from the white light source as a target, a filter for transmitting or reflecting only the visible light region of the light reflected from the reflector, and a light condensing light for focusing the light passing through the filter again The projector is composed of a lens, the light passing through the condensing lens is projected to a film, a liquid crystal panel, or a target for converting an electrical signal into an optical image signal, and a projection machine for projecting the optical image obtained from the target to the screen through a projection lens In the illumination system of, the optical path between the reflector and the condenser lens has a negative refractive power at a radius smaller than the diameter of the reflector and a target around the optical axis, and has a negative refractive power or positive at other radii. An illumination system of a projector, characterized in that the aspherical lens of the shape having a refractive power is provided. The illumination system of claim 1, wherein the aspherical lens has a spatial shape having negative refractive power and zero refractive power from the center of the optical axis. 3. An illumination system according to claim 1 or 2, wherein the aspherical lens does not have circular symmetry with respect to the optical axis center. A white light source, a reflector for primarily focusing the light emitted from the white light source as a target, a filter for transmitting or reflecting only the visible light region of the light reflected by the reflector, and the light passing through the filter is a film or a liquid crystal panel. Or a condensing lens projected onto a target for converting an electrical signal into an optical image signal and condensing light having the optical image information obtained from the target with a projection lens, and converting the light converged by the condensing lens to the projection lens. An illumination system of a projector for expanding and projecting onto a screen, wherein the optical path between the reflector and the projection target has a negative refractive power at a radius smaller than the diameter of the reflector and the target about the optical axis and is zero at other radii. Assembling of the projector, characterized in that the aspherical lens of the shape having a refractive power or positive (+) refractive power is provided System. 5. The illumination system of a projector according to claim 4, wherein the aspherical lens has a spatial shape having negative refractive power and zero refractive power from the center of the optical axis. 6. The illumination system of a projector according to claim 4 or 5, wherein the aspherical lens does not have circular symmetry with respect to the optical axis center.