SU1269082A1 - Blue-printing system of additive motion-picture film printer - Google Patents

Abstract

The invention relates to optical instrumentation and improves the uniformity of illumination of a printed window. The base of the reflector 3, embodied in the form of a circular truncated cone with a right angle at the apex, faces the same ko nus 4, which forms a right-angled light guide with a continuous round cone 5 with the right angle at the apex. The cones 3, 4 and 5 form parallel light beams with an optical axis coinciding with the axis of the spiral of the lamp 1 from the luminous flux from the lamp 1 and the capacitor 2. The interference optical filters 6 perform spectrozonal division, and the light valves 7 regulate the zonal illumination. A collective lens 8 gives an image of a pamp 1 thread in a printed window 9, rotated by with 90 °. The cross section of the light beam at the diaphragmatic porosity is (a uniformly illuminated circle, which allows to increase the uniformity of illumination of the printed window, 5, or ill. V

Description

The invention relates to the design of light-optical systems of photocopiers, in which a incandescent lamp with a spiral filament is used as a light source, oriented in a certain way relative to the printed window.

The purpose of the invention is to improve the uniformity of illumination of the printed window.

FIG. 1 shows a diagram A15 of the proposed device with a lamp filament in a printed window; FIG. 2 is a section A-A in FIG. 1; in fig. 3 - lamp filament in the printing window for sections 1-1. and 11-1.1 i in FIG. 4 is a variant of the device with the exit pupil of the condenser in the printed oKHej of FIG. 5 is a variation of a film projection device.

The device contains an incandescent lamp 1 with a cylindrical spiral thread located coaxially with the lamp bulb, the condenser 2 is mounted coaxially with the bulb 1 and the reflector 3, the working surface of which is made in the form of a round truncated cone. The base of the conical reflector 3 faces the base of another round truncated hollow cone 4 with an internal reflecting surface, inside which there is a continuous round cone 5 with an external reflecting surface. The bases of elements 3 and 4 are equal. The cones 4 and 5 are a mirror light guide and are mutually arranged so that the planes of their bases are aligned with each other, and their geometric axes are aligned with the axis of the spiral of the lamp 1. The cones 3-5 have right angles at the vertices, and the height of the cones 4 and 5 the same.

Thus, inside one hollow cone 3 is installed; lamp 1 and condenser 2, and inside another solid cone 5. The conical surfaces of the cones 3-5 have reflective coatings.

Condenser 2 is made of toric lenses, its front focus is aligned with the center of the filament of the lamp 1. Accordingly, the cones 3-5 are illuminated by parallel beams of rays going from the condenser 2. After the drop, the keny from the cones 3-5 form parallel beams of rays with. the optical axis OjOi coinciding with the axis of the spiral of the lamp 1. In the parachneal beam path, additive interference filters 6 are installed, which perform spectrozonal division, and light valves 7, which control the zonal illumination. Collective lens 8 is located on the optical axis, the back focus of which is aligned with the plane of the printing window 9. Collective lens 8 depicts the thread of the lamp 1 in the printing window 9 rotated 90 as a result of reflecting rays from the cones 3-5.

In the proposed device section

5 light beam in the plane of aperture represents a uniformly illuminated circle, rather than a ring, which makes it possible to increase the uniformity of illumination of the printed window and use the device in intermittent printing machines, i.e. expand the functionality of the optical system. This also makes it possible to use in the device a regulator of exposure, calculated according to the generally accepted method, and significantly simplify the design and calculation of the reflector. The feature of the device is

0 TOj, that in different sections passing through the optical axis 0.0, the image of the spiral of the lamp 1 occupies different positions. For example, in sections I-I and II-II (Fig. 2), the images of the helix in the printed window are rotated relative to each other by 90 (Fig. 3). Since an infinite number of sections pass through the optical axis O, O, an unstructured light spot will be observed in the printed window 9. The distribution of brightness inside this light spot is the same as in the light spot formed when the image of the spiral of lamp 1 is rotated in the printed window 9

around the optical axis.

. The best distribution of illumination in the light spot will be provided that the diameter of the spiral of the lamp

approximately equal to its length. In this case, a high level of illumination can be ensured, since the spatial angle of coverage of the condenser is significantly increased in the device.

Claims (1)

in existing optical-optical systems using a spherical condenser with an angle of coverage not exceeding 70-80, the beam of rays directed to the condenser has a cone shape with a spatial angle of coverage of 1.13-1.47 cpi. In the proposed device, a beam of rays guiding into a toric condenser, has the shape of a spherical balloon, which allows, with the above-mentioned flat angle of coverage, to increase the spatial angle of coverage to 7.2-8 sr. The principle of operation of the device does not change if the condenser, made of toric lenses, is replaced with condensers of spherical lenses arranged concentrically with the flask so that their front focuses are located with the center of the lamp filament. The principle of operation of the device also does not change if the solid cone 5 is replaced by a cylinder with a conical hole with a reflective coating. A widely used lamp with a spiral thread, the axis of which is oriented perpendicular to the axis of the lamp bulb, can be used in the device. In this case, the printed window will also be illuminated with a structureless light spot. However, the cross section of the light beam in the aperture plane will be an irregularly illuminated circle, which must be taken into account when calculating the exposure control. . On the basis of the proposed device, a light-optical system can also be built according to the widely accepted principle, according to which the exit pupil of a condenser is depicted in a printed window, and the diaphragm is made in the image plane of the lamp filament (Fig. 4). In this optical-optical system, uniformly illuminated plane II is sequentially depicted by lenses 10-t1 near collective lens 12 (Il plane) and lens 13 in the printing window 9. The lamp thread. 1 is sequentially depicted by lenses 10-12 near lens 13. The image of the lamp strand 0824 represents unstructured light spot. A light-optic system for a mobile or lightweight film projector can also be built on the basis of the device. By approximate calculations, this will allow to increase the luminous flux of the film projector by 1.52 times. The proposed light-optical system, in addition to the optical elements 1-5 listed above, must include a collective lens 14, a projection window 15 and a projection lens 16 (Fig. 5). The invention The optical-optical system of the additive printing machine containing an incandescent lamp with a cylindrical spiral thread, a coaxial lamp bulb, a condenser and a reflector, a coaxialyo lamp bulb with the front focus of the condenser combined with the center of the lamp filament, as well as the compact light filter and the collective lens. the back focus of which is aligned with the plane of the printed window, which is characterized in that, in order to increase the uniformity of illumination of the printed window, a specular light is introduced into it water, made in the form of a circular truncated hollow cone with an inner reflecting surface and a right angle at the apex, inside which there is another circular cone with an external reflecting surface, a right angle at the apex and a height equal to the height of the truncated cone, the geometric axes of the cones are aligned coaxially with the flask the lamps, the planes of their bases are aligned with each other, and the working surface of the reflector is made in the form of a circular truncated cone with a right angle at the apex, the base of which is facing the base of the truncated cone mirror light guide and equal in size to this base.