KR100786065B1 - Light source of LCD projector - Google Patents

Abstract

The present invention relates to a light source of a liquid crystal projector capable of minimizing light loss.

The liquid crystal projector light source of the present invention includes a lamp for generating a light beam; A parabolic reflector configured to totally reflect the light beam from the lamp in one direction; The light is emitted from the center point of the horizontal center axis of the lamp to an area including an angle (θ) formed by a straight line extending from the end point of the parabolic reflector, the light emitted from the lamp and proceeds to an angle outside the parabolic reflector the parabolic reflector And a reflective surface for reflecting back.

Accordingly, by using the reflective surface formed on a portion of the discharge lamp tube, the light rays which will be out of the parabolic reflector are reflected back toward the parabolic reflector, thereby minimizing the lost light.

Description

Optical Source in Liquid Crystal Projector             

1 is a diagram showing a configuration of an illumination system of a conventional liquid crystal projector.

2 is a view for explaining a light loss phenomenon in the light source shown in FIG.

3 is a view showing a light source of the liquid crystal projector according to an embodiment of the present invention.

4 is an enlarged view illustrating a phenomenon in which reflection is caused by the reflective surface of the lamp illustrated in FIG. 3.

<Brief description of symbols for the main parts of the drawings>

12 lamp 14 parabolic reflector

16: reflective surface

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The present invention relates to a light source of a liquid crystal projector, and more particularly, to a light source of a liquid crystal projector capable of minimizing light loss.                         

Recently, a projector that has a limited screen size and replaces a cathode ray tube display having a large size and has a thin screen and can realize a large screen has been in the spotlight. The projector adopts a cathode ray tube or an LCD (Liquid Crystal Display) as a display for realizing a small screen image, but a liquid crystal projector using an LCD has emerged in response to the trend of thinning. In the liquid crystal projector, a transmissive or reflective LCD is usually used. Liquid crystal projectors are developing on the basis of small size, light weight and high brightness, and LCD panels are developing on the basis of high opening ratio and high resolution. In order to meet the liquid crystal projector flow of high resolution, miniaturization and low price, there is a trend to use a reflective LCD panel in recent years. Liquid crystal projectors have been improved to overcome a lot of problems that can not see a clear screen in a bright environment. For example, a lamp used as a light source has been improved to have a small light emission size, and a polarization conversion system for converting light generated from the light source into one linearly polarized light and a liquid crystal panel having a high open rate are employed to improve the light efficiency. In addition, the microlenses in pixel units are attached to the inside of the liquid crystal panel to improve the effective aperture ratio through which the optical path passes rather than the geometric aperture ratio of the liquid crystal panel pixels, thereby improving light efficiency. Despite these developments, projectors still do not provide clear images like cathode ray tubes, which presents a challenge to further improve the light efficiency.

Referring to FIG. 1, a configuration of an illumination system of a conventional high efficiency liquid crystal projector is shown. The liquid crystal projector illumination system of FIG. 1 includes first and second fly eye lenses 4 and 6 arranged side by side on an optical path between the light source 2 and the condenser lens 10, and a polarization separation array. Polarizing Beam Spriter Array (hereinafter referred to as 'PBS array') 8). The light source 2 includes an arc light emitting lamp having a small emission size and a parabolic reflector installed in a form surrounding the lamp. The white light generated by the arc emission from the lamp is totally reflected by the parabolic reflector to move toward the first fly's eye lens 4 in a quasi-parallel form. The first and second fly's eye lenses 4 and 6 are composed of a plurality of micro lens cells arranged in a matrix. The first fly's eye lens 4 divides the incident light from the light source 2 into lens cells so as to focus on each lens cell of the second fly's eye lens 6. The second fly's eye lens 6 refracts the incident light from the first fly's eye lens 4 into parallel light so as to proceed to the PBS array 8. The PBS array 8 separates incident light from the second fly's eye lens 6 into linearly polarized light having one optical axis, that is, vertically polarized light (hereinafter referred to as P-polarized light) and horizontally polarized light (hereinafter referred to as S-polarized light). do. For this polarization separation, the PBS array 8 is composed of a plurality of PBS prism bars having a polarization separation surface inclined between the entrance and exit surfaces. The incident light is separated into the P-polarized light and the S-polarized light on the inclined plane of polarization of the PBS prism rod, so that the S-polarized light is emitted as it is, while the P-polarized light is partially attached to the rear surface of the PBS array 10 (not shown). To be converted into S-polarized light and emitted. The incident light is converted into S-polarized light, which is all linearly polarized light, by the PBS array 8, so that most of the light emitted from the light source 2 can be used for image realization of a liquid crystal panel (not shown) using linearly polarized light. do. The condenser lens 10 focuses the S-polarized light from the PBS array 8 on a liquid crystal panel (not shown) at a minimum angle of incidence, thereby preventing light loss and improving light efficiency passing through the liquid crystal panel.

In such a light source of the liquid crystal projector illumination system, a large amount of light cannot be used for image realization of the liquid crystal display and is lost. The light consumed by the light source is one of the biggest obstacles to the improvement of the light efficiency in the liquid crystal projector. The phenomenon in which light is lost in the light source is shown in FIG. 2 in detail. In FIG. 2, the effective lights L1 emitted from the lamp 2A and reach the parabolic reflector 2B are reflected by the parabolic reflector 2B and proceed to the first fly's eye lens in a quasi-parallel form. However, the invalid lights L2 emitted from the lamp 2A and emitted to the area where the parabolic reflector 2B is not formed are lost for image realization of the liquid crystal display. As described above, in the conventional liquid crystal projector, the light efficiency is lowered by the invalid light lost from the light source 2.

Accordingly, it is an object of the present invention to provide an illumination system of a liquid crystal projector that can improve light efficiency by effectively using light lost from a light source.

In order to achieve the above object, the light source of the liquid crystal projector according to the present invention includes a lamp for generating a light beam; A parabolic reflector configured to totally reflect the light beam from the lamp in one direction; The light is emitted from the center point of the horizontal center axis of the lamp to an area including an angle (θ) formed by a straight line extending from the end point of the parabolic reflector, the light emitted from the lamp and proceeds to an angle outside the parabolic reflector the parabolic reflector And a reflective surface for reflecting back.

Other objects and features of the present invention in addition to the above objects will be apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 3 and 4.

3 illustrates a light source of a liquid crystal projector according to an exemplary embodiment of the present invention. The light source shown in FIG. 3 includes an arc light emitting lamp 12 having a small emission size and a parabolic reflector 14 installed in such a manner as to surround the lamp 12, and the light exiting the parabolic reflector 14 toward the parabolic reflector 14. It has a reflecting surface 16 partially formed in the lamp 12 for reflecting back. The lamp 12 is formed in an arc shape and has a discharge lamp tube (not shown) for emitting light by discharge, and a lead portion (not shown) having electrodes for applying a voltage to both sides of the discharge lamp tube (not shown). Is composed of The lamp 12 emits white light by arc emission generated by a voltage difference supplied through an electrode of the lead unit (not shown). Light emitted from the lamp 12 and reaching the parabolic reflector 14 is totally reflected by the parabolic reflector 14 to travel forward in the form of quasi-parallel light. In addition, the light emitted from the lamp 12 and out of the effective angle reaching the parabolic reflector 14 is also reflected by the reflecting surface 16 partially formed in the lamp 12 to reach the parabolic reflector 14 Then, the parabolic reflector 14 is totally reflected and proceeds forward. The formation position of the reflective surface 16 is as shown in FIG. Referring to FIG. 4, the reflective surface 16 is partially formed on an outer surface of a discharge lamp tube (not shown) provided in the lamp 12. The reflecting surface 16 is for reflecting back light toward the parabolic reflector 14 out of the effective angle reaching the parabolic reflector 14 among the light emitted from the discharge lamp tube (not shown). It is determined by Equation 1.

Here, θ is an angle between the horizontal center axis Ox of the parabolic reflector 14 and a straight line extending from the center point of the lamp 12 to the end point of the parabolic reflector, that is, radiated from the lamp 12 and the parabolic reflector 14 The angle formed by the horizontal axis (Ox) and the light rays starting to deviate from. X is the length of the lamp 12 from the contact of the parabolic reflector 14 and the lamp 12, f is the focal length f of the parabolic reflector 14, Y is the horizontal center axis of the parabolic reflector 14 ) Shows the maximum radius of the parabolic reflector 14. The lamp 12 is usually installed at the point of focus f of the parabolic reflector 14. As shown in Equation 1, the reflecting surface 12 is applied from the horizontal center axis (0x) to the region forming a maximum θ. The reflective surface 12 reflects the light emitted and emitted from the lamp 12 back toward the parabolic reflector 14 as shown in FIG. 4, and is reflected back from the parabolic reflector 14 to travel forward. By doing so, it is possible to reduce the lost light.

As described above, the liquid crystal projector light source according to the present invention can minimize the lost light by reflecting the light rays, which will be out of the parabolic reflector, toward the parabolic reflector using the reflection surface formed on a portion of the discharge lamp tube. Accordingly, the liquid crystal projector light source according to the present invention can improve the light efficiency.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (3)

A lamp for generating a light beam; A parabolic reflector that totally reflects the light beam from the lamp in one direction; And The light is emitted from the center point of the horizontal center axis of the lamp to an area including an angle (θ) formed by a straight line extending from the end point of the parabolic reflector, the light emitted from the lamp and proceeds to an angle outside the parabolic reflector the parabolic reflector A light source of a liquid crystal projector comprising a reflective surface for reflecting back toward. delete The method of claim 1, [Theta] is the length of the lamp from the contact point of the parabolic reflector and the lamp as X, the focal length of the parabolic reflector as f, and the maximum radius from the horizontal central axis of the parabolic reflector as Y

Light source of the liquid crystal projector, characterized in that determined by.

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