DE747917C - Optical lighting system for projector - Google Patents

Description

Projector Optical Illumination System The invention relates to an optical lighting system for projector with two with the hollow surfaces against each other directed reflectors and - a light guide body arranged on the side of the picture window, that delivers a light beam with an opening angle significantly different from zero, in particular a lighting system for narrow film projectors, the optical Axis essentially. parallel beam path from the first to the second reflector the main direction of light in the light guide is opposite.

In such a lighting system, according to the invention the reflectors designed as parabolic mirrors have moved so close to each other that that the focal point of the opposite reflector is closer to each reflector as one's own focal point, and in one of the focal points should the light source, im other the entry surface of the light through multiple reflection, in particular Total reflection, the light guide element leading to the picture window.

In a further embodiment of the invention, the concave mirrors earth close moved together, and their focal lengths are such that the light source completely or partially outside of the space enclosed by the concave mirror is located. The parabolic mirror surfaces can be parts of the outer boundary surfaces form a mirrored glass body in the area of the parabolic surfaces. the The radiation entrance surface of this glass body can be flat or spherical be. In the case of a concave design of the radiation entrance surface, the can. Focus this hollow surface coincide with the focal point of the opposite mirror surface.

Deviating from this, however, even with a plane beam entrance or exit surface of the vitreous or with spherical entry and exit surface whose 'center point does not coincide with your focal point of the opposite Mirror coincides, one or both mirror surfaces one of a paraboloid received so far different shape that through the entrance: - or exit surface caused spherical deviations are corrected. It is also advisable to the light guide body in optical contact with the one carrying the parabolic mirror surfaces Bring vitreous.

The features of the invention mentioned bring about compared to those specified at the beginning known lighting optics have the following advantages: Each zone of the parabolic mirror provides when using a particularly large aperture of the light rays an image of the Light source, the size of which is essentially the same as that of the light source. The sine condition is fulfilled, and an aberration-free image of the light source is also reached for the off-axis points of the light source. Furthermore, when applying the teaching according to the invention, embodiments can easily be found find where as a result of the arrangement of the light source outside of the concave mirrors the enclosed space, the heat generated by the light source is easily dissipated «-Can earth. When the parabolic mirror surfaces are designed as parts of the outer boundary surfaces a mirrored glass body results, especially if also the light guide body is brought into optical contact with this glass body, a closed one, only low optical losses and against displacement of the optically effective Surface resistant structure.

% A except. The known lighting optics specified at the beginning also an optical system for generating a narrow bundle of rays that only carries parallel rays became known, which consists essentially of three parabolic mirrors. Of these two coinciding with the hollow surfaces are taught to each other. The distance between these mirrors is so great that each mirror is its own Focal point is significantly closer than the focal point of the mirror opposite. Between them there is a light source at the focal point of the first parabolic mirror, near the focal point of the second the third, much smaller parabolic mirror, which turns its hollow surface to that of the second mirror and its focal point with that of the second mirror coincides. Which reflected off all three mirrors Radiation passes through a central opening of the second parabolic mirror and through one tubular diaphragm with a finite coating on the inside to prevent reflection (for the purpose of holding back any divergent rays that may occur) through. This arrangement however, they are not suitable as lighting optics for projectors and could also do that Those skilled in the art do not provide any stimulus in the direction of the invention explained above.

A high-pressure mercury vapor lamp can expediently be used as the light source Find use; however, the lighting system according to the invention is suitable also for the common light sources, i.e. incandescent lamps, arc lamps, etc.

The drawing shows two exemplary embodiments of the subject matter of the invention shown. FIG. 1 shows a vertical longitudinal section through the lighting system, whereby a high-pressure mercury vapor lamp serves as the light source. Fig. 2 in one Another longitudinal section of a similar lighting system with an arc lamp as Light source and a .pyramidetistuiiipftörinig designed light guide body. With i is the outer bell jar and with 2 the discharge path emitting light rays a mercury vapor high pressure lamp. This discharge path 2 lies at the focal point of a parabolic mirror 3, to which an identical mirror q. so facing that the hollow sides are converted to one another. The mirror . «Is an opening 5 through which the light rays enter the lighting optics and those of the Lichtduelle offers space. hn mirror 3 is an opening C, in which a Glass block 7 of rectangular cross-section, serving for light guide body, protrudes. the The radiation entrance surface S of this glass block is located at the focal point of the mirror 4. With this arrangement, the rays emitted by the light source - hit first on the hollow surface of the mirror 3 and are reflected by this, wherein all rays 1111 are directed essentially parallel. You mirror .I collects then all of the "rays" return to its focal point, so that they are in the glass block 7 enter. In this, the forwarding of those entering at a steep incline takes place Rays through single or melirinal total reflection at the lateral boundary surfaces of the vitreous. Finally, the light rays pass through the surface 9 of the glass body off again and illuminate here a picture of the in the immediate vicinity of the end face g directed film io.

In the event that the aperture of the exiting through the surface g If the light beam should be coarse, the glass body 7 can have the shape of a truncated pyramid, # s obtained whose larger end surface serves as the exit surface. By this measure becomes a Aperture reduction of the light beam entering at 8 achieved.

This case is shown in Fig. 2. With i i and 12 are here again denotes two parabolic mirrors, the hollow sides of which are turned towards each other: Through an opening of the mirror i i protrudes the positive carbon 13 of an arc lamp so far into the cavity between the two mirrors that their front focal surface 14 is in the focal point of the opposite mirror 12. Through an opening of the Mirror 12, however, the truncated pyramid-shaped light guide body 15 is so far in inserted the same cavity that the light entry surface 16 in the focal point of the mirror i i lies. The negative carbon 17 of the arc lamp can through an opening 18 of the mirror 12, or the mirrors i i and 12 can also go so far are moved apart so that the holder of this coal will find space between them. The mirrors 3, 4 or i i and 12 can be designed as glass mirrors in a known manner be. However, if the light source used emits significant amounts of heat, the use of metal mirrors may be more appropriate. As the base metal for this comes z. B. Brass into consideration, the one after the shaping and polishing I_Tberzug made of a highly reflective metal, e.g. B. silver, chromium, Al, uminium o. The like., In many cases it will be. be possible the reflective Surfaces of the two parabolic mirrors through outer surfaces of a single glass body to build. These surfaces are mirrored so far that none of them get into the glass body incoming light is lost.

In the case of using a common beam entry surface The glass body for both parabolic mirrors is expediently flat or spherically hollow, in particular so, @ that - the - center of this hollow surface with the focal point of the. opposite mirror surface Here, however, spherical aberrations, especially for the rays that occur from points outside the optical axis come. According to a further embodiment of the invention, this fact can thereby be achieved Take into account that with a flat entry or exit surface or with concave spherical entry or exit area, the center of which does not coincide with the focal point the opposite mirror surface coincides, to correct the or exit surface caused spherical aberrations one or both 'mirror surfaces received a shape slightly different from a paraboloid.

Furthermore, in the case of using a common glass body for Both reflective parabolic surfaces can largely avoid light losses Light guide body in optical contact with the glass body carrying the reflective surfaces to be brought. This can be done by means of Rufkitten, blasting open or the like.

For the optical components described, instead of glass another material with similar properties, e.g. B. quartz or plastic, Find use.

Claims (1)

PATENT CLAIMS: i. Optical lighting system for projector with two reflectors facing each other with the hollow surfaces and a light guide body arranged on the side of the picture window, which supplies a light bundle with an opening angle essentially deviating from zero, in particular lighting system for narrow film projectors, the beam path, which is essentially parallel to the optical axis, from the first on the second reflector is directed opposite the main light direction in the light guide body, characterized in that the reflectors designed as parabolic mirrors are moved so close to each other that the focal point of the opposite reflector is closer to each reflector than its own focal point and that in one focal point the 'light source, im on the other hand, the entry surface of the light guide element leading the light to the picture window by multiple reflection, in particular total reflection, is located. z. Illumination system according to claim i, characterized in that the concave mirrors are moved close to one another and their focal lengths are dimensioned such that the light source is wholly or partly outside the space enclosed by the concave mirror. 3. Lighting system according to claim i, characterized in that the parabolic mirror surfaces form parts of the outer boundary surfaces of a glass body mirrored in the region of the parabolic surfaces. 4. Lighting system according to claim i and 3, characterized in that the beam entrance surface of the glass body having the Par abolspiegelflächen is flat or spherical and that when the beam entrance surface is concave, the center of this hollow surface coincides with the focal point of the opposite mirror surface. 5. Modification of the lighting system according to claim 1 and 4, characterized in that in the case of a flat beam entrance or exit surface of the glass body or in the case of a concave spherical entrance or exit surface, the center of which does not coincide with the focal point of the opposite mirror, one or both mirror surfaces are one of The shape of a paraboloid is so different that spherical deviations caused by the entrance or exit surface are corrected. 6. Lighting system according to claim 1 and 3, characterized in that the light guide body is in optical contact with the glass body carrying the parabolic mirror surfaces. To distinguish the subject matter of the application from the state of the art, the following publications were taken into account in the grant procedure: British patents ... No. 128 240, 320 019; French patent specification,. - 643 364; Kinotechnik, Vol. 14, 1932, Issue 17, p. 317.