DE3047813A1 - Photo sensitive printing process - uses modulated laser beam with signals directed via fibre optic elements onto material - Google Patents

Abstract

The photo printing process uses a modulated laser beam that is directed onto the surface of photosensitive material designed for high quality reproduction. The output of a laser (23) is focussed (24) onto a modulator (25) and is then directed onto short focal length lens (26) and mirror (27). A rotating mirror (11) causes the laser beam to scan a meniscus lens (16). Located directly in front of the photosensitive material is a block containing an array of fibre optic elements (22). The fibre optic elements provide high resolution definition on the material.

Description

The invention relates to an optical light spot scanning

Device for a photosensitive web material, electrostatic Drums or the like. With a modulated laser, an imaging optics and a the rotating mirror arrangement acted upon by the laser beam, which periodically generates the laser beam across the path moving in its longitudinal direction, with suitable modulation of the laser and line-by-line scanning of the web on a desired latent pattern the path is generated.

Such optical light spot scanning devices are used in light setting devices used to print on the photosensitive material, especially a film To set print text.

The laser is modulated by a computer in such a way that the line-by-line scanning creates a latent print pattern on the film, so that after the development of the film, there is legible text on the film, which can then be used to produce a printing form.

well known such optical spot scanning devices a polygon mirror wheel with 12 or 16 mirror surfaces is generally used, to use the laser beam as often as possible during a Rotation of the mirror wheel across the surface of the photosensitive sheet material to run. As far as possible to avoid the errors associated with larger scanning angles to keep it low is limited to the known scanning devices Mirror wheel on using only scanning angles of about 4 to 100 for the projection. In order to obtain sufficient scanning widths with such small scanning angles, the known optical light spot scanners between the mirror wheel and the photosensitive sheet material have a relatively long length. Since now with increasing Lengthening the optical system decreases the light intensity of the laser accordingly and a clear focus and elimination of the angle error is not possible, one already has correction lenses between the rotating mirror arrangement and the projection plane used. However, these can only be either the focusing plane or the angle error correct, because there is no lens system with which both errors are eliminated at the same time can be.

Another difficulty with known optical spot scanners consists in the sources of error inevitably associated with the polygon mirror wheel. On the one hand, there is the angular inaccuracy of adjacent surfaces of the mirror wheel to mention, which, however, are reduced to two to five seconds can. Much more uncomfortable are those caused by the wobbling of the axis of rotation and the inadequate adjustment of the mirror wheel to the axis of rotation occurring errors.

The aim of the present invention is thus to provide an optical To create light spot scanning device of the type mentioned, with the a modulated laser beam in a simple manner with high precision on the photosensitive Material, electrostatic drums or the like. Can be transferred.

To solve this problem, the invention initially provides that the Rotating mirror assembly is formed by a rotary mirror that its axis of rotation runs in the reflective surface and that the laser beam on the axis of rotation hits the reflective surface. According to the invention, instead of the multiple mirror, in which the mirror surfaces are outside of the pivot point, which is an additional Difficulty in focusing means using a single high-speed rotating mirror whose mirror surface runs through the axis of rotation. This makes it unnecessary a difficult adjustment because the laser beam behaves congruently. It always falls on the same spot on the mirror surface. This is very important because with halftone projection the eye is extremely sensitive to irregularities finest lines in gray areas. Since only one mirror is used, prepare there is no difficulty in placing the point of deflection in the axis of rotation, so that the plane of projection not changed despite rotation and focusing is accordingly facilitated. As a mono mirror, the mirror always projects the same laser. This is with polygon mirror wheels not guaranteed due to different surface properties.

The same also applies to the intensity of the laser beam.

There is also such optical light spot scanning devices the problem that the light spot projected on the photosensitive material becomes does not move linearly as a function of the increase in angle of the rotating mirror. To the Eliminating the angular error caused by this provides a further advantageous feature Embodiment of the invention that between the rotating mirror and the web a Cylindrical lens curved essentially in accordance with the circular path of the scanning light beam is arranged with perpendicular to the scanning plane cylinder axis, the Refractive power is chosen so that the scanning light spot on the path is a linear from Carries out scanning movement dependent on scanning angle. The cylinder lens is expedient here a meniscus lens. The practical implementation is expediently such that the curvature of the entry surface of the meniscus lens is less than the curvature of the Path of the scanning light beam in front of the meniscus lens and the curvature of the exit surface greater than the curvature of the path of the scanning light beam behind the meniscus lens is. In this way, the incoming scanning light beam becomes the center in each case broken out that said angle error is eliminated.

Preferably the meniscus lens is 1/4 to 1/2, and preferably 1/3 of the distance rotating mirror / web angcordnct.

The cylinder lens should in any case be symmetrical to the center scanning beam to be appropriate.

Another flaw in such scanning devices is that the light with increasing angle of the scanning light beam relative to the perpendicular Center scanning beam drops in intensity. This loss of light in the outer Scanning areas can be compensated according to the invention in that between the Rotating mirror and the path a graduated filter is arranged, which the scanning beam steadily weakens towards the middle. Preferably, the graduated filter is on the one or Mounted output surface of the cylinder lens. It can be there with an optical putty be glued on.

The graduated filter is therefore more translucent in the lateral, outer areas than in the middle, so that overall on the surface of the scanned web over whose entire width an always equally bright light spot is generated.

Finally, the high precision of a light spot scanning optical device becomes important impaired in photo-setting devices in that the focal plane of the light spot is circular while the line to be scanned is straight. Because of this, the Invention to avoid the focus error in question before that immediately before the web is arranged a Lichtlcitfaseroptik whose output surface is parallel runs to the plane of the path and whose input surface corresponds to the curvature of the incident scanning light beam is cylindrically curved, the optical fibers run perpendicular to the flat scanning surface. The optical fibers are therefore at right angles to photosensitive recording material. Due to the property of the optical fibers, that which hits them Laser light even with non-perpendicular incidence to continue into the glass fibers only with little loss of light is therefore according to the invention exploited. The entry surfaces of the optical fibers on the curved entry surface the optical fiber optics are therefore generally inclined to the longitudinal axis of the optical fibers and are each inclined so that the scanning light beam is perpendicular to the entrance surfaces.

It is of particular importance that the measures according to the invention all of the errors affecting the precision of the scanning device completely can be eliminated. According to the invention, it is therefore not just a matter of to reduce the errors that occur through more or less good compromises. Because of this complete error elimination can in the system according to the invention the deflection angle can be kept very large. The distance is correspondingly short between the rotating mirror and the photosensitive material to be exposed. For example a deflection angle of approximately 400 can easily be achieved. Leave it However, due to the properties of the optical fibers, plano-concave lenses are still used Produce a smaller radius, which is an even greater deflection and thus even more compact Enable construction.

The invention is illustrated below, for example, with reference to the drawing described, the single figure in a schematic perspective view preferred embodiment of the optical light spot scanning device according to the invention shows.

According to the drawing, the one emerging from a laser 23 becomes coherent Light beam centered in a modulator 25 via a focusing lens 24. The modulator is connected to an input device in a manner not shown and is permitted it is to interrupt the laser beam in a rhythm determined by the input device.

Following the modulator 25 is a short focal length lens 26 is provided, which the laser beam via a 900 deflecting mirror 27 to a another lens 28 deflects.

The lenses 26, 28 are dimensioned and arranged so that they reduce the size of the laser beam.

A thin, sharply focused lens emerges from the second lens 28 Laser beam 13, which through the modulator 25 during the printing process in the desired Way can be turned on and off. The modulator 25 thus scans the laser beam in a light-dark circuit, according to the invention, the sharply focused laser beam is now 13 is directed onto a rotating mirror 11 arranged in a mount 29. The version 29 is seated on a motor 30 which can be driven to rotate, the axis of rotation of which is designated by 12. The mount 29 also runs in the direction of the axis of rotation 12 of the arrow f at a high speed of e.g. 15600 rpm.

According to the invention, the axis of rotation 12 runs through the reflective surface of the rotating mirror 11, which in turn is arranged parallel to this axis of rotation 12 is. Due to this arrangement, the laser beam 13 always hits the same point on the surface of the rotating mirror 11, even if it is constantly rotating, at a rotation of the rotating mirror 11 is thus the laser beam 13 constantly in another Directions deflected so that a total of a scanning light beam extending in a plane 15 is generated, which from the position 14 'through the middle position 14 to the other End position 14 "is running.

This scanning cycle is repeated with each revolution of the rotary mirror 11.

The scanning light beams 14, 14 ', 14 "run in the direction of a photosensitive Material web 18 which emerges vertically from a supply cassette 31 and passes through Transport rollers 32, 33 continuously in the direction of arrow F from the cassette 31 is pulled out. The lower transport roller 33 directs the web 18 into the horizontal around what is indicated by the arrow F '. From here the exposed web for further use, according to the invention is between the web 18 and the rotating mirror 11 a cylindrical meniscus lens 16 symmetrical to the center scanning beam 14, the entry and exit fish of the meniscus lens 16 are so curved so that the angle error of the scanning light beam 14, 14 ', 14 "is eliminated.

A graduated filter is placed on the exit surface of the meniscus lens 16 20 glued on, which increases the scanning light beam 14, 14 ', 14 "from the outside to the inside weakens, so that overall a constantly bright scanning light spot over the entire scanning area is achieved.

The meniscus lens 16 and the graduated filter 20 are located relative close to the rotating mirror 11, so that the optical elements concerned are relatively small Can have dimensions Immediately before the photosensitive Track 18 is an optical fiber optic 22 which has the shape of a flat Has a plate, the plane of which lies in the scanning plane 15.

The output surface 21 'of the optical fiber optics 21 runs parallel to the plane of the path 18 or perpendicular to the center scanning beam 14.

The surface 21 ″ of the optical fiber optics facing the rotating mirror 11 21 is curved like a hollow cylinder mirror, the curvature being equal to the curvature is the scanning light path 34 which the scanning light beam 14, 14 ', 14 "carries out The axis of the cylindrical input surface 21 ″ therefore coincides with the axis of rotation 12 of the rotating mirror 11 together.

The optical fibers 22 of the optics 21 all extend perpendicularly to the exit surface 21 ', as shown only in a small section in the drawing is illustrated.

The entry end faces of the optical fibers 22 follow in their inclination the surface of the input cylinder surface 21 ". So you have from the inside out going relative to the longitudinal axis an increasingly inclined light entry face.

The optical fiber optics 21 directs the scanning light beams 14, 14 ', 14 "so that they impinge perpendicularly on the web 18 and there a scanning light spot 17 generate the web 18 along a straight line 19 in its transverse direction periodically scanned line by line. The optical fiber optics also take into account a Correction of the path covered by the scanning light rays in the glass of lens 16 have to.

Since the optical fibers 22 are perpendicular to the photosensitive Extending web material 18, all of the scanning light rays strike the web perpendicularly on. Due to the property of the optical fiber, it may also be at an angle to pass the incident laser light further in the glass fiber with only a small loss of light, is thus used according to the invention.

Before the scanning light beam 14 ′ enters the actual scanning plane 15 enters and detects the web material 18, it encounters a fast working photodiode 35, which synchronizes the modulator 25 in a manner not shown in detail and at the same time controls the material feed with the exposure cycle.

Since the rotating mirror 11 rotates at a very high speed, the bracket must 29 be electronically balanced with the rotating mirror 11. Preferably, the Counterweights on mirrors below and above the mirror surface.

The material to be exposed is not only highly sensitive Photo materials, but also offset plates, cylinders for high-speed electrostatic printing systems i.a.

use.

The scanning device according to the invention works as follows; After this Switching on the motor 12 and the advance of the web material 18 is this along the straight line 19 is scanned line by line from the scanning light spot 17. During the The scanning light beam 14, 14 ', 14 "is scanned by the modulator 25 in a suitable manner Rhythm light-dark keyed. The keying is done by the input device in one such a rhythm that finally a desired print pattern on the web 18, at - !; piclwise a text is written in latent form after the development of the film 18 appears the text in visible form.

Claims (9)

Optical light spot scanning device for a photosensitive Web material in optical photo-setting devices. Claims: i;) Optical light spot scanning device in photosetting devices for a photosensitive web material, electrostatic drums or the like. With a modulated laser, an imaging optics and one of the laser beam applied rotating mirror arrangement, which the laser beam periodically across the track moved in its longitudinal direction guides, with suitable modulation of the laser and line-by-line scanning of the web on a desired latent pattern the path is generated by the fact that the rotating mirror arrangement is formed by a rotating mirror (11) that its axis of rotation (12) in the reflective Surface runs and that the laser beam (13) on the axis of rotation (12) the reflective Surface meets. 2. Apparatus according to claim 1 (characterized g e k e n n z e i c h n e t that between the rotating mirror (11) and the path (18) an essentially corresponding one the circular path of the scanning light beam (14, 14 ', 14 ") curved cylindrical lens (16) is arranged with the cylinder axis perpendicular to the scanning plane (15), whose refractive power is chosen so that the scanning light spot (17) on the web (18) executes a liner scanning movement dependent on the scanning angle (OL). 3. Apparatus according to claim 2, characterized in that g e k e n n z e i c h -n e t that the cylinder lens is a meniscus lens (16). 4. Apparatus according to claim 3, characterized in that g e k e n n z e i c h -n e t that the curvature of the entrance surface of the meniscus lens (16) is less than that Curvature of the path of the scanning light beam (14, 14 ', 14 ") in front of the meniscus lens (16) and the curvature of the exit surface greater than the curvature of the path of the scanning light beam (14, 14 ', 14 ") is behind the meniscus lens (16). 5. Device according to one of claims 2 to 4, characterized g e -k e It should be noted that the meniscus lens (16) is 1/4 to 1/2 and preferably 1/3 of the distance between the rotating mirror (11) track (18) is arranged. 6. Device according to one of claims 2 to 5, characterized g e -k e It is noted that the cylindrical lens (16) is symmetrical to the center scanning beam (14) is arranged. 7. Device according to one of the preceding claims, characterized in that g e k e n n n n e i c h n e t that between the rotating mirror (11) and the track (18) Graduated filter (20) is arranged, which continuously moves the scanning beam towards the center weakens. 8. Apparatus according to claim 7 (characterized g e k e n n z e i c h n e t that the graduated filter (20) on the one or exit surface of the cylinder lens (16) is arranged, 9. Device according to one of the preceding claims, characterized it is noted that directly in front of the web (18) an optical fiber optic (21) is arranged, the exit surface (21 ') of which is parallel to the plane of the web (18) runs and its input surface (21 ") corresponding to the curvature of the impinging Scanning light beam (14, 14 'i 14 ") is cylindrically curved, the optical fibers (22) run perpendicular to the flat scanning surface (21 ').