DE940624C - Device for the production of screened printing forms by photoelectric transmission of images - Google Patents

Description

In the process, which are used for the production of screened printing forms, the methods of image telegraphy operate, an image with a photocell arrangement is in a known manner line by line scanned. In the same way, an engraving tool, its action by the photoelectric Currents is controlled, led line by line over the printing plate to be processed, the Movements of the scanning element and the engraving element always correspond to one another. As an engraving organ pressing, drilling, milling, cutting or burning tools are used. In the known method, the engraving process is periodically interrupted so that one line each is resolved into points and a grid is created.

In some of the known methods, the original image and the printing plate are placed next to one another a common drum or placed on two individual drums that are on a common drum

Wave sit. The scanning element experiences a longitudinal advance during the rotation of the drum whose surface line, so that the original image is scanned in spirals and in the same way the Printing form is created. The synchronism between the scanning is depending on the common shaft one line of the original image and the printing plate guaranteed. The feed movement is through a revolving, endless belt or generated by a ίο threaded spindle. In the latter arrangements however, a subdivided feed spindle is necessary, namely a right-handed and left-handed one Threaded spindle for the scanning and the engraving 'organ, so that the two organs point in opposite directions Execute feed movements. In this way the printing form is created as a mirror image of the Image template, so that an imprint from the printing form is right-sided again. The accuracy of the two spindle parts are high demands.

In other known methods, the original image and the printing plate are located next to one another a common flat slide that carries out the line movement and feed movement, as while the scanning and engraving elements are fixed. Here, the adjacent lines are consecutively in the same sense of direction scanned without a feed movement. The return movement takes place between each line scan of the slide with simultaneous execution of the feed movement. This arrangement has the Disadvantage that the print template is not created as a mirror image of the image template.

In other known arrangements, the original image and printing plate are on two separate ones Carriages whose movements are mechanically coupled to one another. The line movement takes place in the same direction for both carriages and the feed movement in opposite directions, so that the printing form is a mirror image of the original image. The line movement and the feed movement is distributed to the carriages that are coupled to one another. Definitely is but a subdivided feed spindle is required for the mirror-image production of the printing form, whose two sections are in opposite directions and placed great demands on their accuracy because there are already slight differences in the line spacing of the printing form from the eye as a striped pattern be perceived.

In the present invention, the disadvantage of two opposing feed movements and the associated effort with regard to the threaded spindle or similar feed mechanisms and their accuracy is avoided and the printing form is nevertheless generated as a mirror image of the original. According to the idea of the invention, the original image and the printing plate are on the front on the back of a sled. Both sides of the slide are scanning elements and Engraving organ firmly opposite. If the carriage executes the line and feed movement, where in As is known, the feed movement can only take place during the return movement of the slide can, the printing form is created automatically as a mirror image of the original image. This arrangement draws is due to its simple structure and eliminates all errors caused by the transmission of the feed movement of the scanning element on the engraving element in the previously known arrangements. ' The structure of the arrangement is particularly simple when the line movement of the .Schlitten and the feed movement of the opposing ones located on a common arm Scanning and engraving organs are carried out.

In newspaper printing, it is desirable that the printing originals have a grid, the marked direction of which is at an angle of 45 ° to the image edge. It is known to produce such grids in that the image original is scanned at an angle of 45 ⁰ to the image edge, and the printing plate in the same manner manufacturer γ "is provided. In this method, the diagonal j is called the cut, is thus the original is mounted diagonally on a slide or on a drum. Since with drum arrangements / the line movement always remains the same size, areas are scanned whose side length corresponds to the diagonal of the original or whose surface area is twice the size of the original. Half of the printing plate produced in this way or half of the working time therefore remains unused.

This disadvantage of the diagonal cut is avoided according to the present invention by a Reversing device terminates and reverses the line movement each time the scanning element reached the edge of the original image. In contrast to known reversing arrangements that only can be adjusted to the overall size of the original image and the line movement is always for the same Limit the path, the arrangement that is inevitably controlled by the Bdldrand scans for the playback ineffective areas beyond the edge of the picture.

In one embodiment of this inventive concept, the one carrying out the line movement carries Sled has a frame that shows the shape and position of the original image clamped at 45 ° Has. In addition, the arm executing the feed movement carries two stops that are assigned to the beginning and end of the line and their mutual spacing affects the size the image template is adjustable. These two stops protrude into the frame and operate then a rocker arm when the frame hits, and return via a linkage and a coupling the direction of the line movement. So if an original image is scanned in the direction of its diagonal, so at the end of the line the frame carried by the carriage presses against the frame assigned to it Stop, and this tilts a lever into the opposite position, which controls the scanning movement via a coupling reverses. At the end of the now following return movement, the other side of the carried one pushes Frame against the one assigned to this side

Neten second stop, which tilts the same lever back into its original position and again the original scanning movement direction establishes. Since the stops with the feed movement the diagonals of the frame migrate, while the frame is perpendicular to the direction of the line and goes here, the frame will hit the attacks earlier and earlier, the closer the attacks of the Approach the corner of the frame. In this way ίο the path of the line movement becomes shorter and shorter always corresponds to the length of a diagonal line in the original image.

According to a further idea of the invention, the slide has a reflective surface on which the original image is placed. If the scanning element illuminating the original exceeds the edge the original image, the reflective surface of the slide casts the incident light with an intensity into the photocell, which is larger than that of the light that is only diffusely reflected from the original. In this way, when the image edge is exceeded in the photocell, a powerful impulse is created, who actuates a reversing relay, for example, but which reacts to the weaker image pulses 2φ does not respond. By means of the relay the line movement reversed, so that the carriage 'a reciprocating motion between the : Executes image edges.

In an arrangement in which, for example, the scanning element creates a point of light on the original image is shown, the light of which is diffusely reflected by the original image into the photocell, would the light rays after crossing the image edge from the ideally reflecting slide surface be thrown back in itself and not reach the photocell.

According to the idea of the invention, the axis of the scanning element is therefore against the normal of the Sled surface inclined so that the reflected from the reflective sled surface Light just falls into the photocell. When the axis of the is perpendicular to the slide surface Sensing element, the surface of the slide receives a corrugation that supports the incident light rays with an intensity in the photocell that is greater than the intensity of the original image diffusely reflected light is. In another embodiment of the inventive concept there is Slide surface made of a thick mirror glass plate, on the upper side of which the picture template lies, in which the light source of the scanning element is imaged. After crossing the edge of the picture, it penetrates Light enters the mirror glass plate and is only reflected by its mirror coating on the back. Since there is no longer a sharp image on the back, the light rays are no longer in thrown back, but rather reflected in the photocell.

In Fig. Ι is an embodiment of the inventive concept shown in a highly schematic perspective view.

Fig. 2 shows the principle of a further embodiment.

In a housing not shown in FIG. 1 there are two guide rods 1 and 2 on which a scanning carriage 3 slides. A frame 4 is attached to the slide and has the position and shape of the recess 5 located in the slide. In the recess 5 there is a glass plate on which the original picture is placed with its front side pointing downwards. As is not shown in FIG. 1 for the sake of clarity, a plate is placed on the original image, on the side of which the printing plate is clamped upwards. The surface of the printing plate is processed by the engraving element 6 and the original image is scanned from below by means of the scanning element 7. Engraving element and scanning element are opposite to one another and are attached to an arm 8 which encompasses the carriage 3 and is guided on a guide rod 9 and a spindle 41. The arm 8 carries out a feed movement in the direction of the arrow 11, while the carriage 3 carries out the reciprocating line movement in a direction of the arrow 12 perpendicular thereto. In this way, when the original image is scanned, the printing form is created as a mirror image. The driving of the carriage 3 and the engraving and scanning arm 8 takes dur.ch a motor 13 via a gear 14 and the gears 15, 16, 17 communicates with the wheel 18 of the clutch 19 engaged. The wheel 18 is firmly connected to the spindle 20, which has a thread and moves the carriage 3 in the row direction 12 via the threaded sleeve 21. If, on the other hand, the clutch 19 is engaged on the opposite side, the drive is transmitted from the transmission 14 via the gears 22 and 23 to the wheel 24, which is also firmly connected to the spindle 20. In this case, the spindle 20 has opposite directions of rotation, so that the carriage 3 is moved back in the direction opposite to the arrow 12. As a result of the different transmission ratios of the gears 22, 23 and 15, 16, 17, the return movement of the carriage 3 takes place faster than its forward movement. The reversal of the forward movement into a return movement and vice versa is carried out by the frame 4 in conjunction with two stops 25, 26, which are assigned to the beginning and the end of the line movement. The stops 25, 26 are rigidly connected to one another and to a fork 27 and protrude into the frame 4. This arrangement is fastened in a rail 28 on the scanning arm 8 with a clearance which corresponds to the distance between the two end positions of a rod 31 tilting about the pivot points 29, 30. If the frame 4 hits the stop 25 during its forward movement in the direction of the arrow 12, the latter is moved together with the fork 27 in the same direction, and the rod 21 also tips over in this direction. The roller 35 is also moved in this direction via the lever 32 and the linkage 33, 34. The roller 35 slides resiliently on a wedge 36, the linkage 34 evading this sliding movement as a result of the joint 37, and the roller strikes up

Crossing the tip of the wedge 36, the clutch lever 38 jerkily to the other side. In this way, the direction of rotation of the spindle 20 is reversed and the carriage 3 and frame 4 move now in the opposite direction. The frame 4 abuts against during this return movement the stop 26, it is pressed with the fork 27 in the direction of the return movement, which Rod 31 and lever 32 turn back into the starting position shown in FIG. 1, and the Roller 35 also returns the clutch lever 38 to its starting position. Now is the old sense of rotation and the carriage movement begins again in the direction of arrow 12. Fills the Bildvprlage the recess 5 straight out, then the hitting of the frame 4 corresponds to just that Scanning the edge of the image. If the original image is smaller than the recess 5 or the frame 4, then the stops 25, 26 by means of the adjusting screw 39 and one not particularly shown in FIG The screw drive is pulled apart so that the frame is then hit again when the scanning element 7 reaches the edge of the original image.

During this reciprocating movement of the carriage 3 in the line direction, the motor 13 drives Via the transmission 14, another transmission 40, which has a not specifically shown and in the box of the gear 40 with housed slip clutch with the threaded spindle 41 in connection stands. With the threaded spindle 41 of the engraving and scanning arm 8 is in engagement, the in this way a feed movement in the direction of arrow 11 can be issued. On the Spindle 41 is a ratchet wheel 42 fixedly arranged in which a pawl 43 engages. As long as that Ratchet wheel 42 is held, the motor runs against the slip clutch without the feed movement to drive. This state is shown in FIG. At this stage the Movement of the carriage 3 in the direction of arrow 12 without advancing the arm 8. When reversing the outward movement of the carriage 3 in the back

'Movement is through the nose 44 located on the linkage 33 of the lever which is rotatable in the bearing 45 46 pushed in the direction of arrow 12 and the pawl 43 out of engagement of the ratchet wheel 42 pulled out so that the spindle 41 together with the ratchet wheel 42 of the slip clutch

50 'is taken. Arm 8 now performs the feed movement perpendicular to the line direction, while the carriage 3 is meanwhile moving back performs. The ratchet wheel 42 rotates until the pawl 43 in the next engagement of the Ratchet wheel 42 engages again, whereby the feed movement stops. During the reversal the return movement to the next forward movement, which takes place via the rod 33, 34 and the roller 35, the pawl 43 is not actuated by the nose 44. Because by the movement of the linkage 33 and the nose 44 in the direction of the roller 35, the lever 46 can in this direction do not give way, the nose 44 deviates downwards and the joint 37 upwards, so that this reversal process no feed movement is triggered. In this way, the carriage 3 performs one and forward movement, the forward movement of which is slow in each case, the feed movement is locked, whereas the return movement takes place quickly and at the same time a forward-push movement executed by a constant amount.

When the ratchet wheel 42 is rotated tooth by tooth and the rows thereby one after the other are scanned, the arm 8 moves with the stops 25 and 26 more and more in the corner of the Frame 4. As a result, each reversal of the line movement will occur continuously earlier because the distances within the rectangular frame 4 become shorter and shorter. That at an angle of An image scanned 45 ° to the image edge is therefore always only within the edges of the original line for Line scanned. When the spacing of the stops 25, 26 is set to the size of the original image any small images can be scanned and displayed; without the Area outside the image field has an effect / comes into play. j

The rail 28 carries an extension 47 which through a f rotatable about the bearing 48 \ lever 49 a diaphragm 50 controls. Namely, in I of initiation of the return movement of the carriage '3 ί the stopper 25 in the direction of arrow 12 overall / suppressed, so the extension 47 moves in the same direction and brings the shutter 50 into the optical path of the scanning unit 7. In this The scanning element is darkened during the entire return movement of the carriage. As a result, the engraving element 6 remains inoperative during the line return movement. When the forward movement of the slide 3 is initiated, the frame 4 pushes the stop 26 in a direction opposite to the arrow 12, so that the diaphragm 50 is pulled back again via the lever 47 and releases the beam path during the forward movement of the slide.

In Fig. 2, another reversing device is shown according to the concept of the invention. In this Arrangement, the reversal of the line movement when reaching the edge of the image is optical triggered. As in FIG. 1, a glass plate 51 is inserted into the recess 5 of the scanning carriage. The original image 52 lies on this glass plate, with its front side pointing downwards. About the In this arrangement, the original image is covered by a mirror glass plate 53, the reflective rear side of which 54 comes to lie on top. Finally this mirror plate is covered with a base plate 55, on which the material 56 receiving the artwork is attached. The light source 57 is by means of Lens 58 onto a perforated diaphragm 59 and through a further lens 60 into the plane of the original image 52 as a point of light shown in focus. As long as the original image is in the beam path of this lighting device is located, the light is diffusely reflected from the top of the original image and falls into

the two photocells 6i. The photoelectric currents control the engraving element 6, which processes the printing plate 56, proportionally to the brightness of the original image via an amplifier 62. If this scanning device has just passed the edge of the original image 52, as shown in FIG. 2, the light is no longer diffusely reflected in the plane of the original image 52, but enters the mirror glass plate 53. The rays are now reflected on the reflective rear side of the plate 53 and reach the photocells 61 with an intensity that is much greater than the intensity of the light now diffusely reflected on the original. The currents triggered in this way in the photocells are stronger than the image currents and are separated from the image currents by a switch. For example, they are able to stimulate an in comparison \ more 62 lying relay that to

\ does not address the weaker image streams. This ! 20 relay actuates the reversing device 63, which is the reversal of the. Scanning direction of the carriage caused in a known manner. Thus, the 'lines of each movement is reversed when exceeding the BiId- \ edge, wherein the size of BIId-25 template and its location are irrelevant to the carriage. Simultaneously with the line movement S controlled in this way takes place during each return movement of the carriage

the feed movement of the scanning member by a constant amount, for example in the described Art is controlled by means of a linkage and a ratchet wheel. In the present However, the arrangement of FIG Signals are triggered by using a reducer only every second signal is selected that is associated with the initiation of the return movement. The reversing device enables the areas lying outside the edge of the image not to be scanned.

In a further embodiment of this inventive concept, the mirror glass plate 53 and the The base plate 55 lies directly on the master image 52. The side of the base plate facing the master image 55 has a reflective corrugated surface that is also used when scanning higher light intensities reflected in the photocells than the only diffusely reflecting original image, This triggers the reversing signals when the edge of the screen is exceeded.

In a further embodiment of the inventive concept, the optical axis 64 of the scanning device is inclined towards the base plate 55 so that the light rays are reflected by the smooth, reflective underside of the base plate 55 into the photocells 61 after crossing the image edge. This intensity is again greater than the intensity of the light that is only diffusely reflected by the original image 52 and triggers the reversing relay in the amplifier 62.

The arrangements described are therefore suitable for scanning both in the direction of the edge of the The original image is also suitable at an angle to its edge, the original image also being smaller than that Can be recess 5 of the carriage 3 and is still only scanned within its field of view and the artwork is produced in mirror image in the same way.

Claims (13)

PATENT CLAIMS: 1. Device for the production of screened printing forms by photoelectric transmission of images, characterized by a relative to the scanning and engraving organs (7, 6) positively guided slide (3), on one side of which the to be scanned The original image lies and on the back of which the printing form is created in mirror image. 2. Device according to claim 1, characterized in that that the carriage (3) necessarily guided in two mutually perpendicular directions is, while the scanning element (7) and the engraving element (6) are firmly opposed to each other. 3. Device according to claim 1, characterized in that that the carriage (3) is only moved in one direction, and in a direction perpendicular to it Direction of the opposing scanning and engraving elements (7, 6) mounted on an arm (8) a feed movement carry out. 4. Apparatus according to claim 1 to 3, characterized by a reversing device that reverses the direction of the scanning movement when the scanning element hits the edge the original image. 5. Apparatus according to claim 1 to 4, characterized in that the slide (3) carries a frame (4) which actuates a stop (25, 26) when the edge of the picture is reached, which reverses the direction of movement of the slide. 6. Apparatus according to claim 1 to 5, characterized characterized in that the frame (4) has the shape and position of the picture format. 7. Apparatus according to claim 1 to 6, characterized in that the two image edges a stop (25, 26) located on the arm (8) is assigned in the scanning direction, whose mutual distance can be adjusted to the size of the original image. 8. Apparatus according to claim 1 to 7, characterized in that the feed movement of the arm (8) during a direction of movement of the slide that is always in the same direction (3), namely the working direction, is blocked by a detent and only during the opposite movement of the carriage, namely the return, takes place. 9. Apparatus according to claim 1 to 8, characterized in that the carriage return triggering stop a cover (50) carries the during the carriage return The beam path of the scanning element blocks. 10. Apparatus according to claim 1 to 4, characterized characterized in that the original image is covered with a reflective plate (53 or 55) is optical when the edge of the image is exceeded Triggers uni control signals, which reverse the direction of the scanning movement. 11. The device according to claim ι to 4 and 10, characterized in that the optical axis of the scanner against the smooth, reflective Underside of the base plate (55) is inclined. 12. Apparatus according to claim 1 to 4 and 10, characterized in that the base plate (55) has a reflective corrugated surface at the bottom-hat. 13. The device according to claim 1 to 4 and 10, characterized in that the reflective plate is a mirror glass plate (53) on which The front side is the original image and which is arranged so that the reflection on its rear side to trigger the reversing signals. 1 sheet of drawings 509 676 3.56