DE861193C - Device for optical compensation when projecting moving images - Google Patents

Description

Device for optical compensation when projecting moving images The invention relates to a device for projecting moving images from continuously moving, endless strip of images that should make it possible to create an optical To bring about compensation in the image projection.

Facilities that serve the same purpose are already known in many versions. Some of them work with the use of vibrating Mirrors or prisms that dictate a certain path for your light beam and to be controlled with regard to their oscillating movements. Partially the same purpose is also pursued using circumferential polygonal prisms, which are switched into the light path, achieved in cooperation with lens systems. All such known institutions have one thing in common: the tracking of the target, which is fluent to illuminate moving individual images and to project them in such a way that a subsequent one Single image in the previous single image with different lighting. comes in.

In this way it should be achieved that the change of the previous one Single image is inconspicuous against the next one. The familiar one comes to him Sluggishness of the human eye - to compensate for the change in stimulus impressions not being able to follow the retina so quickly.

The invention is based on a number of solutions for bringing about this an optical compensation, in which one enters the projection staircase circumferential polygonal prism transversely to this Beam path switched on is that works with lens systems. So trained to be. knew devices to have. but so far not fully satisfactory results.

i To achieve a perfect visual balance in every respect to achieve, therefore, completely new paths are broken according to the invention and at the same time new knowledge has been put to good use.

It has been found that a particularly good optical According to the invention, compensation can then be achieved if: a polygonal prism interacts is brought into use with lens systems, which with any even number of edges in or position 36a °, divided by twice the number of edges, e.g. B. at one. Square prism thus 36o °: 8 = 45 °, a parallel offset of one image distance (for normal films = 19 mm). The glass path is twice as large as at Polygonal prisms of known application.

The lens systems intended to cooperate exist according to the invention from two lenses with parallel axes that are superimposed with such an axis spacing are attached that two consecutive images on the projection surface be brought to congruence. To achieve this coverage, the distance must be two parallel lens axes depending on the projection distance and the focal length of the lens can be slightly smaller than the center-to-center distance of the film either fixed for a projection distance or designed to be variable will.

Since for normal film the distance between the axes of the two lenses is less than If it has to be 9 mm, then normally only lenses with a diameter of about 8 mm could be used arrange on top of each other. However, these would be too faint for projection purposes.

According to the invention, two objectives with a larger diameter than the axis distance is, housed in a common lens tube, where Corresponding circular segments have been eliminated from the lens diameters, such that the lenses of the double lens in, the. required distance only are separated from each other by a thin wall. According to the invention, this is added a rotating screen with 180 ° light sector for use, which consists of a rotating Disc consists of two offset to one another, each extending over 180 ° has arranged recesses in the form of concentric cutouts.

The polygonal prism consists of a glass according to the invention, the Refractive index nd is less than 1.51. This is advantageous for the reason that in all. Positions of the polygon prism an equal sum of the reduced glass path plus the air gaps between the film and the first lens vertex of the lens to reach.

The drive of the polygonal prism is done by a gear with uneven Winkelgeschwin, speed, z. B. by an elliptical gear or gears with eccentric Axes, the dimensions being such that the greatest angular velocity with the zero position and the smallest, angular velocity with the position greatest Deflection of the polygonal prism coincides.

With a facility trained in this way, now. worked in the way that, the film transport by one frame distance through the rotation of the polygonal prism uni, 36o °, divided by twice the number of edges, is balanced, with the Deflection in this position and the zero deflection, i.e. with the beginning of the film transport and end, coincide. The diaphragm used in the device preferably works in such a way that - during the film transport, only one at a time of the two individual lenses is open, with the aperture alternating one or another lens releases, namely in the zero position of the polygonal prism. the lens closest to the image that appears first in the image window and in the position of greatest deflection that in the direction of the film by about one image height offset second lens.

In the. Drawings, the invention is for example with a square prism shown, namely Fig. i shows the steering of the projection beam path in the zero setting of a square prism, with simultaneous schematic representation the aperture, Fig. 2 the steering of the beam path during a rotation of the square prism by a2; 5 °, including the aperture position, Fig. 3 the steering of the projection beam with a rotation of the prism by 45o, at the moment the change from picture I to picture II, Fig. 4 the beam path deflection during a rotation of the square prism 'by 67.5 ° and Fig. 5 the beam path steering with a prism rotation by 90 ° at the moment of the change from image II to image III; Fig. 6 demonstrates the refractive index, specifying the relevant data; Fig. 7 shows the arrangement of the dual lens system in the. common lens tube; Fig. 8 shows the drive parts for moving the square prism and the diaphragm, and Fig. 9 8 is an end view of FIG. 8, which shows the design of the diaphragm itself; FIG. 10 is the front view of FIG. 7.

According to the illustrated example of a projection device, the film i runs off the roll 2 and comes onto the roll 3 at a constant speed. The roller 2 is driven by the wheel 4, the roller 3 is driven by the wheel 5. The bevel gear 6 sits on the axis of the roller 3 and meshes with the bevel gear 7, which is attached to the shaft 8 stands. On the shaft 8, the gear 9 is also attached, which drives the gear io on the shaft ii of the diaphragm 1'2. The disk-shaped diaphragm i2 has two recesses 12 'and i2 "which are offset from one another by i 80 °. In front of the film i, the square prism 13 is mounted, which starts from the gear 14 sitting on the shaft of the discharge roller 2, via the gear 15, a property in positive engagement ellipse gear pair 16,17 and the gears is set with non-uniform angular velocity in circulating i8 and i9 the ratio between the:. gear 14 and the gear 15 is chosen such that 9o ° revolution of the Ellipsenradpaares 16, 17 a film sequence corresponds to an image distance.

On the shaft of the square prism 13, the gear 2o sits loosely, which is in engagement with the gears 4 and 5.

The light source 21 and the condenser device are located behind the film i 22, which illuminates a film window for two individual images.

An objective tube is located between the prism 13 and the diaphragm 12 2.3, in which the double lens system consisting of lenses 24, 25, 26 and 24, 25 ', 26' is housed one above the other. Because the lens diameter of the lenses is larger are than the center distance, are of the. Lentil the places: which intersect would be removed in the form of segments of a circle. The lenses sit at this point with the interposition of a thin wall 27 flat on top of each other, like that in particular from Fig. io can be seen.

The double lens system 24, 25, 26 and 24, 25 ', 26' and the cutouts the orifice plate 12 'and 1i' are placed in relation to one another in such a way that they are in one plane lie, so that the upper or lower alternately as the diaphragm disc rotates Objective system is released for the passage of rays.

Claims (7)

PATENT CLAIMS: i. Device for optical compensation in the projection of running images using a polygonal prism in cooperation with lens systems, characterized by the use of a polygonal prism, which is in the position 360, ' divided by twice the number of edges, e.g. B.: with a square prism 3.6o °: 8 = 45 '°', a parallel offset of one image distance (with normal film = i9 mm) causes. 2. Device according to claim i, characterized by the connection of the polygonal prism with two Lenses optically parallel-axis arrangement, which is in such an axis distance are arranged one above the other that two consecutive images on the projection surface be brought to congruence. 3. Device according to claims i and 2, characterized through the use of a rotating aperture disk with iSo ° to each other staggered cutouts for light to pass through. 4. Device according to claims i and, 2, characterized by a. Lens tube in which two Lens systems with a larger diameter than the required axis distance is, with correspondingly eliminated circular segments, only through a thin wall separated from each other, are arranged. 5. Polygonal prism according to claims i and 2, characterized in that it consists of a glass whose. Refractive index (na) is less than 1; 51. 6. Drive for the device for projection according to the Claims i to 4, characterized by the use of a gear with uneven Angular velocity, e.g. B. elliptical gears or gears with eccentric axes, at which gear the greatest angular velocity with the zero position and the smallest angular velocity with the position of greatest deflection of the polygonal prism coincides. 7. Process for carrying out a continuous film transport in a device according to claims i to 6, characterized in that the Film transport by the amount of an image distance by rotating the polygonal prism by 36o ° divided by twice the number of edges. B. Procedure according to claim 7, characterized in that only one objective of the double objective system is opened during the film transport of an image, which is caused by that the aperture alternately releases one or the other lens, namely in the zero position of the polygon pri @ smas that which appears first in the image window The lens closest to the image and the in The second lens is offset from the direction of the film by about one image height.