SU1170415A1 - Optical system of split scan of rotary electrophotographic apparatus with variable scale of reproduction (versions) - Google Patents

Description

2. The system of claim 1, wherein the additional mirror is placed on the holder; hinged on an axis perpendicular to the optical axis.

3. A system according to PPL, 1, characterized in that the mechanism of input and output of an additional mirror from the optical path is made in the form of a flexible rod thrown over a roller placed between the first mirror and the lens.

4. A slit scan system of a rotating electrophotographic apparatus with a variable reproduction scale, comprising a lens with means for moving it along the optical axis in accordance with a selected scale, a fixed mirror located between the original and the lens along the optical rays, and a movable mirror located between the lens and the electrophotographic apparatus, characterized in that, in order to simplify the design, it has an additional movable mirror located between the lens and a cylinder, a movable mirror holder having a rotational drive around an axis, perpendicular to the optical for variable input and output of the movable mirror to the optical path associated with the means for moving the lens. 5. The system of claim 4. characterized in that the kinematic connection of the mirror holder with the means for moving the lens is made in the form of a connecting rod bar hinged to the lens holders and the movable mirrors.

The invention relates to rotary electrophotographic apparatuses, in particular, to an optical slit scanning system of a rotary electrophotographic apparatus with a variable reproduction scale and a moving original.

The purpose of the invention is to simplify the design of the optical system of a slit scan of a rotating electrophotographic apparatus with a variable reproduction scale.

FIG. 1 shows the first embodiment of the proposed optical system; in fig. 2 - the same, the second option.

The optical system contains originator 1, electrophotographic cylinder 2, lens 3, first 4, second 5 and third b of the mirror. The lens 3 is mounted for movement along the optical axis by means of a mechanism including the direction 1, 7 and the electric drive (not shown). Mirror 4 is fixed between the original and the lens along the optical rays. In the first embodiment (Fig. 1), the second mirror 5 is also mounted stationary between the lens 3 and the cylinder 2 (along the optical rays). The third mirror 6 is installed in front of the mirror 5 so that the longitudinal axes of these mirrors are parallel. The mechanism of input and output of the mirror 6 from the optical path when changing the playback scale includes a holder 8 of this mirror, pivotally mounted on an axis 9, a perpendicular optical axis, and also slung over the roller 10 placed between the mirror 4 and the lens 3, a flexible thread - thread 11, one end of which is attached to the lens 3, and the other to the holder 8. On axis 9 there is a spring 12, one end of which is attached to the holder 8 and the other is fixed on the base 13. The holder 8 has an adjusting screw 14 that abuts. and slave the mirror position 6 is in the base 13. The mirror 5 is fixed on the holder 15 mounted on the axis 9 with the possibility of fixing the required angle to the optical axis with the help of an adjusting screw 16 screwed into the base 13.

In the second variant (Fig. 2), mirrors 5 and 6 are fixed on a common holder 17, installed with the possibility of rotation around a fixed axis 18, perpendicular

the optical axis, and the mirrors are located at different distances from the axis 18. The rotation mechanism of the holder 17 has two fixed stops 19 and 20 and a cylindrical spring 21, one end of which is attached to the holder and the other fixedly, the axis of the spring intersects the axis rotation of the holder when it is rotated. The holder 17 is kinematically connected with the mechanism for moving the lens 3 by the connecting rod bar 22, on one side of which is hingedly attached to the lens holder 3, and on the other to the pin 23 entering the groove 24.

The device works as follows.

With a larger scale reproduction

elements of the optical system are located in

The position shown in FIG. 1 and 2 in solid lines, with this, the rays of light emanating from objective 3 are reflected onto electrophotographic cylinder 2 from mirror 6. To reduce the reproduction scale, objective 3 is displaced electrically in guides 7 to the position shown by dashed lines. In the first embodiment (FIG. 1), the lens rotates the holder 8 with the mirror 6 through the thread 11 to the position shown by the dotted line. At the same time, light rays emanating from lens 3 are reflected onto cylinder 2 from mirror 5. During lens return, the holder 8 returns to its original position with the help of spring 12 before the screw 14 contacts the base 13. In the second embodiment (Fig. 2) the lens 3, with the aid of the bar 22, rotates the holder 17 to the position shown by a dotted line. At the same time, the light rays emanating from the lens are reflected onto cylinder 2 from mirror 5. During the reverse course of the lens, the strip 22 returns the holder 17 to its original state. In the extreme positions, the holder 17 is pressed against the stops 19 and 20 by a spring 21. If necessary, to have more than two reproduction scales in the proposed optical system, additional mirrors can be installed: in the first embodiment, each on its holder on axis 9 (Fig. 1). in the second variant - on the holder 17 (Fig. 2). The advantage of the proposed optical system in comparison with the known one is that it eliminates the need for precise movement of the second mirror strictly parallel to itself while simultaneously accurately changing its inclination. This allows us to simplify the design of the optical system, reduce the requirements for the accuracy of manufacturing its parts, while maintaining high accuracy of reproduction scales.

Claims (5)

1. The optical system of a slit scan of a rotary electrophotographic apparatus with a variable reproduction scale, comprising a lens with means for moving it along the optical axis in accordance with the selected scale, a fixed mirror located between the original and the lens along the optical rays, and another mirror located between the lens and electrophotographic cylinder, characterized in that, in order to simplify the design, it has an additional mirror mounted between the lens and other mirror, and the mechanism of its optical input and output path when changing the scale of reproduction, wherein the other mirror is mounted fixedly. figure 1 2. The system by π. 1, characterized in that the additional mirror is placed on the holder; pivotally mounted on an axis perpendicular to the optical axis. 3. The system according to PP, characterized in that the input and output mechanism of the additional mirror from the optical path is made in the form of a flexible rod thrown over a roller located between the first mirror and the lens. 4. The slot scan system of a rotary electrophotographic apparatus with a variable reproduction scale, comprising a lens with means for moving it along the optical axis in accordance with the selected scale, a fixed mirror located between the original and the lens along the optical rays, and a movable mirror located between the lens and an electrophotographic apparatus, characterized in that, in order to simplify the design, it has an additional movable mirror located between the lens and the Indra holder movable mirrors having ^four pivot drive around an axis perpendicular to the optical input and output variable of the movable mirror in the optical path, associated with means for moving the lens. 5. The system according to claim 4. characterized in that the kinematic connection of the mirror holder with the lens moving means is made in the form of a connecting rod, pivotally connected to the lens holders and movable mirrors.