JP2016062063A - Light source device for projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light source device for a projector, comprising: a high pressure mercury lamp in which mercury is sealed in a luminous tube, and a pair of electrodes are arranged to face each other; and a concave reflection mirror surrounding the high pressure mercury lamp, in which a tube axis of the high pressure mercury lamp and an optical axis of the concave reflection mirror match, in which light emitted form the lamp is not viewed as wobble at a projection destination, and which can be used as an installation type and a suspension type.SOLUTION: A diffusion face is formed on a projection area corresponding to a lower part of a luminous tube of a high pressure mercury lamp, on a light transmission window or a concave reflection mirror.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a light source device that combines a short arc type high-pressure mercury lamp and a reflecting mirror, and more particularly to a light source device used as a light source of a projector.

Conventionally, a combination of a short arc type discharge lamp and a concave reflecting mirror is used as a light source device for a projector. Since a light source with good color rendering properties is required for a projector, conventionally, a high-pressure mercury lamp having a high mercury vapor pressure is suitably used as a discharge lamp.
The general structure of such a light source device for a projector is disclosed in Japanese Patent Application Laid-Open No. 2004-342446 (Patent Document 1) and Japanese Patent Application Laid-Open No. 2008-010384 (Patent Document 2).

The structure is shown in FIG. 7, and the light source device 31 includes a short arc type high-pressure mercury lamp 32 and a concave reflecting mirror 33 that condenses light from the lamp 32. The high-pressure mercury lamp 32 includes an arc tube 34 in which a pair of electrodes are disposed facing each other, and a rear sealing tube 35 and a front sealing tube 36 at both ends thereof.
The high-pressure mercury lamp 32 is horizontally arranged such that the tube axis direction thereof coincides with the optical axis of the reflecting mirror 33. That is, the rear sealing tube 36 is fixed in a state of being inserted into the rear neck portion 33 a of the reflecting mirror 33, and the front sealing tube 35 is positioned on the front opening 33 b side of the reflecting mirror 33.
A light transmission window is disposed in front of the optical axis on the light emission side of the reflection mirror 33. In Patent Document 2, the light transmission window 37 is provided in the front opening 33b of the reflection mirror 33. It is shown. As another structure for attaching the light transmission window, there is also known a structure for attaching to a projector casing without attaching to a reflecting mirror.

By the way, in a projector using a high-pressure mercury lamp, the convection of mercury vapor in the arc tube of the lamp may be projected on the projection screen as image fluctuation.
As shown in FIG. 8A, in the arc tube 34 of the lamp that is lit horizontally, mercury vapor convects from the bottom of the arc to the top starting from the arc, and therefore the mercury concentration around the arc. However, depending on the temperature gradient, the upper portion has a low concentration and the lower portion has a high concentration.
Therefore, as shown in FIG. 8B, the light generated in the arc tube is affected by the mercury vapor, and the light L2 emitted from below with a high mercury concentration is more than the light L1 emitted from above with a low mercury concentration. Is greatly affected, and this is visually recognized as a fluctuation at the projection destination.
Particularly in recent years, there has been a demand for a discharge lamp with higher brightness, and the lamp power and the amount of enclosed mercury are increasing. Along with this, there are often cases where fluctuations due to mercury vapor are visually recognized.

JP 2004-342446 A JP 2008-010384 A

  In view of the above-described problems of the prior art, the present invention includes a high-pressure mercury lamp in which mercury is sealed in an arc tube and a pair of electrodes are arranged to face each other, and a concave reflecting mirror surrounding the high-pressure mercury lamp, In the projector light source device arranged so that the tube axis of the high-pressure mercury lamp and the optical axis of the reflecting mirror coincide with each other, the light from the lamp is not visually recognized as fluctuations at the projection destination, and is stationary. The present invention provides a light source device for a projector that can be used for both a mold and a ceiling type.

In order to solve the above-described problems, a projector light source device according to the present invention has a projection region corresponding to a lower portion of the arc tube on a light transmission window disposed on an emission side on an optical axis of the concave reflecting mirror. A diffusion surface is formed.
The light source device for a projector is used in either a stationary state or a suspended ceiling state, and the light transmission window diffuses into a projection region corresponding to an upper portion of the arc tube in the stationary state. A surface is formed.
The diffusing surface is a lens diffusing surface in which a number of minute spherical convex shapes are formed on the surface.

Further, the concave reflecting mirror is characterized in that a diffusing surface is formed in a reflecting region corresponding to a lower portion of the arc tube.
The projector light source device can be used in either a stationary state or a suspended state, and the reflecting mirror has a diffusing surface in a reflecting region corresponding to an upper portion of the arc tube in the stationary state. Is formed.
Further, the diffusion surface is characterized in that a large number of minute spherical convex shapes or concave shapes are formed on the surface.

According to the light source device for a projector of the present invention, a diffusing surface is formed in a light transmission window arranged on the exit side on the optical axis of the concave reflecting mirror or in the projection area corresponding to the lower portion of the arc tube on the reflecting mirror. Therefore, the light emitted from the lower part of the arc tube, which is strongly affected by the convection of mercury vapor in the arc tube of the lamp, is diffused by the diffusion surface, so that the fluctuation itself is blurred and strongly visible. It will not be.
In addition, the vertical relationship of the lamps is reversed between when the projector is suspended and when it is suspended from the ceiling. However, in a projector that is both stationary and suspended, projections corresponding to the upper and lower portions of the arc tube in the stationary state are used. By forming a diffusion surface in the area, no matter which method is used, the diffusion surface exists in the projection area corresponding to the lower part of the arc tube in the lighting method, and the fluctuation of the lamp is blurred. And will not be visible.

Sectional drawing (A), front view (B), (C) of the light source device for projectors of this invention. The expanded sectional view of the diffusion surface in the present invention. Sectional drawing (A) of another Example of this invention, and a front view (B). FIG. 4 is a diagram illustrating the relationship between the stationary type (A) and the ceiling type (B) and the light source device of FIG. Sectional drawing (A) of the further another Example of this invention, and a front view (B). Sectional drawing (A) of the further another Example of this invention, and a front view (B). Sectional drawing of the light source device of a prior art. Sectional drawing explaining the malfunction of a prior art.

1A is a cross-sectional view of the projector light source device of the present invention, FIG. 1B is a front view thereof, and FIG. 1C is a front view of another embodiment.
The structure of the discharge lamp and the concave reflecting mirror is the same as that of the prior art of FIG. 7, and the light source device 1 includes a high-pressure mercury lamp 2 in which mercury is enclosed in an arc tube 3 and a concave reflecting mirror 4 surrounding the high-pressure mercury lamp 2. The lamp 2 is lit in a horizontal state.
A light transmission window 5 is provided in front of the reflecting mirror 4 on the optical axis, that is, on the emission side. As shown in FIG. 1A, the light transmission window 5 is attached to the front opening of the reflecting mirror 4 and to the case (not shown) of the projector in which the light source device 1 is incorporated. is there.

The light transmission window 4 has a diffusion surface 6 in a projection area corresponding to the lower part of the arc tube 3 of the lamp 2, that is, an area where light emitted from the lower part of the arc tube 3 of the lamp 2 is projected. Is formed.
The surface shape of the diffusing surface 6 is arbitrary, and may be, for example, a quadrangular shape as shown in FIG. 1 (B) or a semicircular shape as shown in FIG. 1 (C). .
The diffusing surface 6 is, for example, a concavo-convex processed surface, and is preferably a lens diffusing surface in which a large number of minute spherical concavo-convex shapes are formed on the surface as shown in FIG.
That is, it is preferable that the protrusion 6a formed on the diffusion surface 6 is not an acute angle but has a rounded uneven shape. Furthermore, it is preferable that the curvature is uniform. Thereby, the transmitted light X becomes diffused light, and the diffusion range is narrowed down to a certain range, so that a significant drop in the amount of light can be prevented.
When the specific example is described, it is uneven | corrugated of width 10-500 micrometers, height (or depth) 5-250 micrometers, and a shape is a hemisphere shape.

By the way, when the projector is used by being installed on a desk or the like, it may be used by being hung on the ceiling, and when specified and used in advance, as shown in FIG. The diffusing surface of the light transmission window may be formed in a projection region corresponding to the lower part of the arc tube of the lamp in the usage state.
By the way, in a projector that is used for both stationary and ceiling suspension, the projector body is usually used by being inverted. In this case, of course, since the lamp is also inverted, the vertical relationship of the arc tube of the lamp is reversed, and the area which was the lower part when installed is the upper part when suspended.
An embodiment corresponding to this is shown in FIG. 3, and the light transmission window 4 is formed with a diffusion surface 6 in a region corresponding to the lower part of the arc tube 3 of the lamp 2 in the stationary state, and the upper part. A diffusion surface 7 is also formed in a region corresponding to the above.

The relationship between the projector P and the light source device 1 is shown in FIG.
FIG. 4 (A) shows a mode of being placed on a desk or the like, and FIG. 4 (B) shows a mode of being suspended from the ceiling. When hanging from the ceiling, the projector P is inverted. used.
In the light transmission window 5 in the light source device 1 used for such a projector, a diffusing surface 6 is formed in a projection region corresponding to a lower part A of the arc tube 3 of the lamp 2 in a stationary state, and an upper part B A diffusion surface 7 is also formed in the projection region corresponding to the above.
In the case of the stationary shown in FIG. 4A, the light from the lower part of the arc tube 3 of the lamp 2 is diffused and emitted by the diffusion surface 6 of the light transmission window 5.

On the other hand, when the projector P shown in FIG. 4B is inverted and suspended from the ceiling, the vertical relationship of the arc tube 3 of the lamp 2 is also inverted, and the upper part B when installed is changed to the lower part when suspended. Become.
At this time, the light emitted from the lower part B of the arc tube 3 of the lamp 2 passes through another diffusion surface 7 formed in the projection region corresponding to the upper part at the time of installation, and is diffused and emitted. .
Thus, in either case of stationary or ceiling suspension, the light emitted from the lower part of the arc tube 3 of the lamp 2 is diffused by the diffusion surface 6 or the diffusion surface 7 and emitted.

The diffusing surface described above is formed on the light transmission window 5, but another embodiment is shown in FIGS. 5A and 5B, and the diffusing surface 8 is formed on the concave reflecting mirror 4. This is an example.
That is, the diffusing surface 8 is formed in a region of the reflecting mirror 4 where the light emitted from the lower part of the arc tube 3 is projected.
Further, FIGS. 5A and 5B are examples in the case where the projector is a stationary / ceiling type, similar to the embodiment of FIG. In addition to the diffusing surface 8 of the embodiment, a diffusing surface 9 is also formed in the projection region corresponding to the upper part of the arc tube 3 of the lamp 2 in the stationary state. Of course, in this embodiment, the lamp 2 is also reversed and the vertical relationship of the arc tube 3 is reversed and used in the case of stationary and ceiling suspension.

The diffusing surfaces 8 and 9 formed on the reflecting mirror 4 are, for example, concavo-convex processed surfaces, and, as shown in FIG. It is preferable that the shape is formed in large numbers. When the specific example is described, it is an unevenness | corrugation of width 10-500 micrometers and height 5-250 micrometers, and a shape is a hemisphere shape.
Such a concavo-convex shape can be formed by forming a concavo-convex shape in a mold when a substrate (for example, a glass material) for forming a concave reflecting mirror is molded with a mold.
As shown in FIG. 2B, due to the uneven shape of the diffusing surface 8, the reflected light Y becomes diffused light, and lamp fluctuation is reduced.

As described above, in the projector light source device of the present invention, the mercury vapor is formed by forming the diffusion surface in the projection region corresponding to the lower part of the arc tube of the high-pressure mercury lamp in the light transmission window or the concave reflecting mirror. Because the light from the lower part of the arc tube that is strongly affected by the convection of the light is diffused, the influence of the fluctuation of the radiated light is reduced, the fluctuation at the projection destination is blurred, and it is not strongly observed This is an effect.
In addition, since the diffusion surface is formed not only in the lower part of the arc tube in the stationary state but also in the projection area corresponding to the upper part, the projector can be used for both stationary and ceiling hanging. In this case, the diffusion surface is present in the projection region corresponding to the lower part of the arc tube, and the influence of fluctuation due to light from the lower part can be reduced.

DESCRIPTION OF SYMBOLS 1 Light source device for projectors 2 High pressure mercury lamp 3 Light emission tube 4 Concave reflector 5 Light transmission window 6, 7, 8, 9 Diffusion surface X Diffuse light

Claims (6)

A high-pressure mercury lamp in which mercury is sealed in an arc tube and a pair of electrodes are arranged opposite to each other, and a concave reflecting mirror that surrounds the high-pressure mercury lamp, and the tube axis of the high-pressure mercury lamp and the light from the concave reflecting mirror In the projector light source device arranged so that the axes coincide,
A light transmission window is disposed on the exit side on the optical axis of the concave reflecting mirror;
A light source device for a projector, wherein the light transmission window has a diffusion surface formed in a projection region corresponding to a lower portion of the arc tube. The projector light source device is used in either a stationary state or a suspended state,
The light source device for a projector according to claim 1, wherein a diffusion surface is also formed in the light transmission window in a projection region corresponding to an upper portion of the arc tube in a stationary state.   3. The light source device for a projector according to claim 1, wherein the diffusion surface is a lens diffusion surface having a number of minute spherical convex shapes formed on the surface. A high-pressure mercury lamp in which mercury is enclosed in an arc tube and a pair of electrodes are arranged opposite to each other, and a concave reflecting mirror surrounding the high-pressure mercury lamp, and a tube axis of the high-pressure mercury lamp and an optical axis of the reflecting mirror In the projector light source device arranged so as to match,
A light source device for a projector, wherein the concave reflecting mirror is formed with a diffusing surface in a reflecting region corresponding to a lower portion of the arc tube. The projector light source device is used in either a stationary state or a suspended state,
The light source device for a projector according to claim 4, wherein the concave reflecting mirror is also formed with a diffusing surface in a reflecting region corresponding to an upper portion of the arc tube in a stationary state. 6. The projector light source device according to claim 4, wherein the diffusing surface has a large number of minute spherical convex shapes or concave shapes formed on the surface.

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