DE1079945B - Honeycomb condenser for use in a cinema mirror lamp - Google Patents

Description

GERMAN

The invention relates to a honeycomb condenser for use in a cinema mirror lamp, each with one Lens surface on the non-rastered side of the luminous field and image field raster.

It is known, in the beam path of a projection light source, for. B. a cinema mirror lamp, a so-called To arrange honeycomb condenser, which consists of grid plates.

These grid plates are designed in such a way that the individual lenses of the concave mirror first grid plate are adapted in their shape to the image window and have such a focal length, that they each have an image of the light source in the corresponding lenses of the second seen from the concave mirror Map the grid plate and the individual lenses of this second grid plate, which in their shape of the shape of the Light source are adapted to have such a focal length that they the lenses of the first 'grid, themselves overlapping each other, map them in the image window. The first grid is in the. following as field raster and the second grid is called the luminous field grid. It is evident that those from the centers of the Lenses of the image field raster after the centers of the luminous field raster rays running in Must intersect the center of the image window so that the images can overlap. Even a certain distance between the grid plates must be maintained so that with a given focal length the Individual lenses the type of mutual imaging described above is guaranteed. With a certain The arrangement, size and focal length of the individual lenses of the grid plates is the honeycomb condenser for a certain distance from the image window, for a certain image window format and a certain aperture of the entire illuminating beam is determined. So far it was common to use the Honeycomb condenser has the normal image window 15.2 x 20.9 mm and an aperture ratio of the lens from 1: 1.9 to be adjusted. The distance between the two grid plates and the size of the two grid networks were chosen so that the course of the center points of the Bildfeldliäsen with the centers of the associated luminous field lenses connecting rays the course of the radiation angle of the usual Mirror lamps of 300 or 350mm mirror diameter was adapted. On the luminous field lens grid plate Another convex lens surface was arranged through which the envelope aperture of the illumination beam path increased to 1: 1.9 and was therefore adapted to the usual lens apertures.

With the introduction of the wide-wall process, a change to the honeycomb condenser is now necessary. In a known wide screen method (Cinemascope), the image format is 18.16 × 23.16 mm

Honeycomb condenser for use
In a cinema mirror lamp

Applicant:

VEB Feinmeß Dresden,
Dresden-N23, Kleiststr. 10

Dr. Helmuth Schering, Dresden,
has been named as the inventor

elevated. In order to achieve greater luminous fluxes to illuminate the wide screen walls, one is also ' endeavors to achieve higher lens aperture ratios, e.g. -1: 1.6, to pass over. An illumination of the larger picture window formats and the larger aperture ratios but is no longer possible with the previously common honeycomb condenser.

The invention now envisages an adaptation (of the honeycomb condenser to the different film formats, to different Lens aperture ratios as well as different mirror sizes before, without the lenticular lenses even something! is changed. This has the advantage that with one and the same costly Press tool pressed grid plates are used for the different operating conditions can.

^; According to the invention, this is achieved in that the focal length of the lens surface on the luminous field grid is chosen so that the honeycomb condenser is adapted to a specific image window format, and the focal length of the lens surface on the image field grid is selected so that the honeycomb condenser also has a specific lens aperture ratio , a certain mirror size and a certain mirror spacing is adapted.

In this way it is possible to create a honeycomb

"- condenser of certain grid by attaching it of two simple lens surfaces on the non-rasterized Areas of the grid plates to adapt to a specific image window size, ■ a specific lens aperture ratio illuminate it and place it in the '' beam path of a certain mirror lamp.

Immediately. It is also easily possible to have two different ones Honeycomb condensers, for example for normal format or widescreen format, to have ready and to use them as required to replace. All honeycomb condensers have the same grid, the same plate spacing and

909 770/153

I 079

thus also the same version. The adaptability goes so far that plates with the same Screening for normal film and also for narrow film can be used. One only becomes the for Select the grid plates of smaller diameter used for the cine film screening.

One form of solution is described in more detail below. Let it be B. given a honeycomb condenser with a distance between the two grids L ₁ and L ₂ = a _t and with the distance of the convergence point B _{1 of} the central _{rays from the luminous field grid L 2} = a ₂ . The magnification of the overlapping imaging of the image field raster lenses by the luminous field raster lenses in the plane of the convergence point in the case of flat raster plates is then the result of the diameter of the light cone at L ₁ :

Ci ₁ + a ₂ O ₁ + a ₂ U ₁ -V

If the light cone emanating from the concave mirror S is to have the diameter _{d t at L 1,} the rays B i Ab emanating from the crater center point K intersect

len in B ₂ at a distance b ₂ from L ₁ on the optical i Lih f L ß

_{2 2 1} p

Axis. The lens surface on L ₂ must now deflect the rays so that they intersect in B ₁ .

If the mirror diameter = d and the distance between the edge of the mirror and the image window = e , the result is:

-O ₁ (V + I)] -O ₁

b ₂ -

d -

The first requirement of the honeycomb condenser is to adapt the magnification to the image window format. Let this magnification be V. Then the distance of the image window B from the luminous field raster

b = (Z ₁ * V

and the focal length of the lens surface on the luminous field grid plate L ₂ results

away

and the focal length of the lens surface becomes _{L 1}

As an example, a honeycomb condenser is again chosen with O ₁ = 65 mm, a ₂ , = 180 mm. V is 2.4 for wide-screen format and 2.1 for normal format. The mirror diameter is 350 mm and the distance between the edge of the mirror and the image window is 852 mm. For lenses 1: 1.9 this then results in d _v b ₂ and f _Ll

a ₂ - 6

For example, let C ₁ = 65 mm, a ₂ = 180 mm and the size of the image field raster lens = 8.5 x 11 mm on the honeycomb condenser, then for the widescreen format of 18.16 x 23.16 and the size of the light spot on the image field raster of 20.2 x 25.2 the magnification F ~ 2.4.

With a normal film format of 15.2 × 20.4 and a light spot of 17.5-23.0, the magnification is F ~ 2, l.

The distance b of the picture window from the luminous field grid is then 156 mm for wide screen format and 136 mm for normal film format.

The focal length of the convex lens surface on the luminous field grid plate is f _L2 - ^{1170 mm for the widescreen format and / i2 ==} 555 mm for the normal film format.

The second requirement of the honeycomb condenser is that for a certain concave mirror size and a certain distance of the concave mirror from the image window a certain lens aperture ratio, z. B. 1: 1.9 or 1: 1.6, illuminated wind, with im Waibenkondensor the correct course of the center rays must be preserved.

If a lens aperture ratio l: x is to be illuminated, the diameter of the light cone at L _{2 must} be:

* δ O ₁ -V

the following values
for wide screen format:
<£, = 112 mm

b ₂ = 297 mm
Zi ₁ = 1400 mm

For lenses 1
for wide screen format:
d _t = 133 mm
b ₂ = 387 mm
Zi ₁ = 667 mm

for normal format:
d ₁ = 97.5 mm
b ₂ = 252 mm
Zi ₁ = 8850 mm

1.6 result

for normal format:
d _t = 116 mm
b ₂ = 322 mm
Zi ₁ = 1015 mm

Claims (1)

Claim: Waibenkondensor for use in a cinema mirror lamp, each with a lens surface on the unscreened side of the luminous field and the image field raster, characterized in that the focal length the lens surface on the luminous field grid is chosen so that the honeycomb condenser a specific image window format is adapted, and the focal length of the lens surface on the image field raster is chosen so that the honeycomb condenser also has a certain lens aperture ratio, a certain mirror size and a certain mirror spacing is adapted. In the honeycomb condenser, the rays must run in such a way that the connecting lines of the lenticular lens centers intersect at a distance d ₂ from L ₂ at point B ₁ . 60 Publications considered: Swiss patent specification No. 229 645,
388; French Patent No. 831,786; U.S. Patent No. 2,326,970; Journal: "Kino-Technik", 9, 1955, issue 8 (August), p. 281, especially Fig. 7; »Picture and sound«, cinematic center, the Zeiss Ikon AG, Stuttgart, 40, 1955 (March), p. 23, especially Fig. 12. 1 sheet of drawings © 905 770/153 4.60