EP0080132B1 - Apparatus for transferring a toner image - Google Patents

Description

The invention relates to a device for transferring a toner image from a planar photoconductive surface by means of pressure on a heated metallic image carrier which has line contact with the photoconductive surface over the length of a transport cylinder during the transfer of the toner image.

The transfer of a toner image from a moving photoconductor to a moving image carrier is generally carried out by means of pressure, heat and / or support through a corona discharge if the image carrier consists of paper, plastic film or the like material.

A device of the type described at the outset is known from US Pat. No. 3,063,859, which relates to the transfer of toner images from a flat photoconductor plate to a metallically conductive, curved printing plate made of, for example, surface-roughened zinc. The photoconductor plate is in line contact with the heated printing plate which is mounted on a transfer drum during the toner image transfer. The pressure plate used must be convexly shaped so that it has the same curvature as the transfer drum. Continuous operation is not possible since after each toner image transfer the printing plate has to be removed from the stopped transfer drum after releasing clamping devices and a new printing plate has to be pushed onto the transfer drum.

From US Pat. No. 3,554,836 a transfer method for toner images is known, in which a toner image is developed on a silicone elastomer surface and is then transferred one or more times to further silicone elastomer surfaces and finally reaches the final image carrier without the release of toner. For this purpose, for example, an aluminum plate coated with a silicone elastomer can form the outer surface of a roller, on which there is an image that is developed by a developer. The developed image can then be transferred to another roller, which also has a silicone elastomer coating, and is finally transferred from this roller to an image carrier belt.

US Pat. No. 4,092,925 describes a device of a printing plate system which has a reusable printing element made of aluminum, which is coated with a light-sensitive coating which, together with the aluminum printing element, becomes the image area. A support plate supports the aluminum pressure element and is detachably connected to it. After the printing process has ended, the aluminum printing element is detached from the carrier plate, which is also reusable.

In the known devices, the image is transferred from the photoconductor either via an intermediate image carrier to the image carrier or directly, without an intermediate image carrier, from the photoconductor to a light-sensitive coated image carrier.

The object of the invention is to provide a device for the toner image transfer from a photoconductor surface to a metallic image carrier, without using an intermediate image carrier, with which flat image carriers can be processed continuously, without the transfer drum being stopped and equipped with a new image carrier after each toner image transfer must become.

This object is achieved by a device of the type described at the outset such that gripping devices, which are moved along the circumferential surface of the transport cylinder with the circumferential transport cylinder, for holding and clamping the image carrier on the transport cylinder and stationary pressure devices are arranged which can be pivoted away from the transport cylinder and can be applied to the latter in order to press the image carrier which is brought up to the transport cylinder or detaches itself from the transport cylinder against the peripheral surface of the transport cylinder and that the gripper devices release the image carrier after the toner image transfer has ended.

The further embodiment of the device according to the invention results from the features of claims 2 to 9.

With the invention, the toner images are continuously transferred to the image carriers without downtime of the device, which, due to the only one-time contact between the photoconductor and the image carrier, have high image resolution without blurring or blurring, which occurs, for example, with two or more contacts during the image transfer of the occur more often. There are no additional cleaning problems by removing the residual toner from an intermediate image carrier and, moreover, the required device construction can be kept small, since the intermediate image carrier is omitted.

• Fig. 1 eine Schnittansicht der erfindungsgemäßen Vorrichtung,
• Fig. 2 ein Detail der Vorrichtung nach Fig. 1 in Seitenansicht,
• Fig. 3 eine schematische Gesamtansicht eines Geräts zur Bebilderung von Bildträgern,
• Fig. 4 bis 6 drei verschiedene Lagen des Bildträgers gegenüber der fotoleitfähigen Fläche innerhalb der Vorrichtung nach der Erfindung.

The invention is described below with reference to an exemplary embodiment shown in the drawing. It shows

• 1 is a sectional view of the device according to the invention,
• 2 shows a detail of the device of FIG. 1 in side view,
• 3 shows a schematic overall view of a device for imaging image carriers,
• 4 to 6 three different layers of the image carrier relative to the photoconductive surface within the device according to the invention.

The device shown in Fig. 1 has a transport cylinder 17, the shaft 18 is mounted with its end portions in scenes 30, 30 which are displaceable in side plates 28. As can be seen from Fig. 2, the backdrop 30 is surrounded by two vertically extending guide rails 29 on both sides and can move up and down in these guide rails 29. In the embodiment shown in FIG. 1 there is a pressure element, for example a compression spring 27, which is prestressed, above and below the link 30. The compression springs 27 bear against the upper side and against the lower side of the link 30 and enable the distance between the upper side of an upper part of the travel table 65 and the lateral surface of the transport cylinder 17 to be set differently according to the thickness of an image carrier 15, since the shaft 18 of the transport cylinder 17 is vertically displaceable against the respective pressures of the springs 27.

As FIG. 2 shows, hydraulic or pneumatic cylinders 26 can also be provided as pressure elements for the link 30, which are arranged above and below the link 30 in the side plate 28 and whose piston rods are connected to the link 30.

Above the transport cylinder 17, a gripper device is arranged on a shaft 33 which has gripper device 32 which cooperate with drivers 34. Between each gripper finger 32 and a clamping ring 36 there is a leg spring 35 for closing the gripper finger 32. Furthermore, stops 24 are also seated on the shaft 33. The operation of the gripper device is mentioned only briefly, since it is a known device. An actuating lever 46 of the gripper device carries an actuating roller 39 which rolls on a control cam 48. The lever 46 is pivoted by the control cam 48 and the gripper fingers 32 are accordingly opened or closed. In addition to the lever 46, there is a fork piece 45, in which a lifting rod 42 engages, which is surrounded by a compression spring 47, which is supported on the one hand against a support bearing 44 and on the other hand against a stop 40. The lifting rod 42 and the fork piece 45, the lever 46 together with the actuating roller 39 and cam 48 are arranged between one end face of the transport cylinder 17 and the inside of one side plate 28. Between the lifting rod 42 and the right side plate 28 in FIG. 1, a gearwheel 50 is seated on the shaft 18, which meshes with a toothed rack 51 attached to the side of the travel table 3. The rack 51 is moved back and forth by a gear 31, which is connected to a direct current motor 67. The engagement of the gear 50 with the rack 51 causes the transport cylinder 17 and the image carrier 15, for example an aluminum plate, held on its outer surface by the gripper device to rotate.

A heat radiator 37 is arranged centrally in the interior of the transport cylinder 17, the ends of which are mounted in the end sections of the shaft 18 of the transport cylinder 17. Brackets 38 are attached to the outside of the end portions of the shaft 18 and are connected to the ends of the heat radiator 37. The heat radiator 37 is controlled so that the surface temperature of the transport cylinder 17 or the aluminum plate 15 during the toner image transfer from the photoconductor 19 to the aluminum plate is 100 to 125 ° C. At such a temperature, very good image resolution is obtained with contact forces of up to 100 N / cm. Of course, it is also possible to provide a transport cylinder 17 which is not heated, but then the contact pressure between the photoconductor and the image carrier must be increased to values of up to 200 N / cm at room temperature. An infrared radiator with an output of 1600 watts, for example, can be used as the heat radiator 37, which heats the transport cylinder 17 to the desired surface temperature after a heating-up time of approx.

The device for imaging image carriers, in particular aluminum printing plates, is described with reference to the overall view according to FIG. 3. The photoconductive surface 19, for example a photoconductor film, rests on a top part 65 of a table 3, which can be moved horizontally in the direction of the double arrow A. The photoconductor is clamped onto the upper part 65 of the travel table by negative pressure. A charging device 1, preferably a corona charging device, runs over the photoconductor 19 and charges it with a predetermined voltage of a certain polarity. As soon as the charging process is completed, the charging device 1 returns to its starting position. The charged photoconductor is then exposed via an exposure station 2 arranged above the traveling table 3. After the exposure process has ended, the traveling table 3 is moved towards the transport cylinder 17. The latent charge image on the photoconductor 19 is emphasized from above by a schematically indicated developer station 4 and developed into a toner image. The developer station 4 can, for example, be designed such that it is lowered onto the photoconductor 19 only when required and is otherwise somewhat lifted off the path of the photoconductor.

The image carrier or the aluminum printing plate 15 is inserted in a feed 16 which is inclined with respect to the photoconductor path and extends in such a way that the image carrier 15 comes to rest against the transport cylinder 17 tangentially and obliquely from above. At the lower end of the feeder 16 there is a lock 5, which releases a pressure plate when necessary. As soon as the lock 5 opens, the uppermost pressure plate falls into an opened first gripper device 6, the front edge 22 of the pressure plate 15 being positioned by stops 24 (FIG. 4).

As soon as the toner image 25 on the photoconductor 19 comes into pressure contact with the printing plate 15, the transport cylinder 17 rolls with the printing plate 15 held thereon on the photoconductor 19 (FIG. 5). The toner image 25 is transferred under pressure from the photoconductor 19 to the printing plate 15.

As can be seen from FIG. 3, the first and second gripper devices 6 and 9, which can be completely identical in structure, are arranged along the circumferential surface of the transport cylinder 17 for holding the pressure plate 15. Both gripper devices of the transport cylinder 17 are supported in cams 53 which are fastened to the end faces of the transport cylinder 17. The gripper device 9, controlled by a control cam 48, serves to hold the rear edge 23 (FIG. 6) of the pressure plate 15 so that it is clamped onto the peripheral surface of the transport cylinder 17. The image carrier 15 is pressed in front of the point of contact with the transport cylinder 17 by the first pressure device 7, which essentially consists of a pivotable pressure roller, against the circumferential surface of the transport cylinder, the open gripper device 9 closing in the further course and the rear edge 23 of the image carrier 15 is clamped against the transport cylinder 17.

The pressure plate 15 is preferably a metal plate, for example, as already mentioned, an aluminum plate which can have a thickness of 0.1 mm to 0.5 mm. The strip material available for such aluminum plates is subject to larger thickness tolerances according to the DIN standards, which can be between ± 0.008 mm with a thickness of 0.1 mm of the aluminum plate and with ± 0.58 mm with a 0.5 mm thick aluminum plate mm can be. This means that with an aluminum plate with a length of 370 mm, tolerance-related deviations in the path amount of ± 0.3 mm for the 0.5 mm thick aluminum plate.

The surface of the printing plate is expediently roughened electrochemically and has a roughness of 2 to 8 _{1 1} m.

In order that the transfer of the toner image can take place without a loss in the image quality, namely the resolution, a perfect synchronous operation between the photoconductor 19 spanned on the upper part 65 of the traveling table and the peripheral surface which is formed by the aluminum plate attached to the transport cylinder is required. The previously mentioned different path amounts, which are caused by the tolerance deviations in the thicknesses of the aluminum plates, act as a braking or accelerating force which is exerted by the aluminum plate on the photoconductor 19. The resulting tensions and / or frictional forces can lead to losses in the resolution for larger format lengths and, moreover, to damage and when the upper part of the travel table 65 returns due to the reduced rolling radius, since the aluminum plate no longer rests on the transport cylinder lead to increased wear between the surface of the photoconductor 19 clamped on the upper part 65 of the traveling table and the surface of the transport cylinder 17. This is avoided in that a synchronism between the transport cylinder 17 with the pressure plate fastened thereon and the upper part of the travel table 65 is ensured during the pressure contact between these two assemblies. For this purpose, according to the German patent application P 31 36659.7 (EP-A1-74602) it is proposed to provide a gearwheel which meshes with a toothed rack attached to the side of a travel table, the upper part of the travel table via locking elements during the advance to the point of transferring the toner image to the travel table -Lower part to connect and this connection only at the moment of contact between the photoconductor and the pressure plate and to provide rolling elements between the upper part of the table and the lower part of the table, which ensure that the table after unlocking with its predetermined speed according to the propulsion continues through the rack, while the upper part of the moving table assumes a speed corresponding to the given rolling radius, which is made possible by the rolling bearings due to the rolling elements, since the upper part of the moving table can be easily moved relative to the lower part of the moving table or the moving table.

After the end of the toner image transfer, the printing plate 15 is transported by the transport cylinder 17 with its leading edge in the direction of a third gripper device 11 which is arranged in front of a fixing device 14. The third gripper device 11 is moved by means of a drive 52 parallel to a tray 20 for the image carrier or the printing plates 15. The fixing device 14 is switched on before the printing plate 15 is transported over it. As soon as the third gripper device 11 has reached its highest position, it opens and releases the pressure plate 15, which falls into the tray 20. The fixing device 14 and the shelf 20 are inclined to the horizontal. The tray 20 connects to the discharge runners 68 and the fixing device 14 is located below the discharge table. The discharge runners 68 run tangentially to the circumferential surface of the transport cylinder 17, so that the pressure plate 15 detaching from the transport cylinder 17 is attached laterally to the outside of the image area without kinking Austragungskufen 68 comes to the concern.

The travel table 3 initially continues to travel in the direction it is in even after it has passed the transport cylinder 17. The cleaning station 13 is followed by a discharge device 12, for example a corona discharge device, in the forward direction of the travel table 3, which deletes the residual voltage still present on the photoconductor 19 (FIG. 3). However, an arrangement is also possible in which the discharge device 12 is arranged in front of the cleaning station 13, viewed in the forward direction (FIG. 6). When resetting, the cleaning station 13, which is indicated schematically by a cleaning squeegee, is lowered onto the surface 19 and cleans the surface Residual toner photoconductor.

The device according to the invention and its mode of operation will be explained in more detail below with reference to FIGS. 4 to 6. 4 that the pressure plate 15 is gripped by the first gripper device 6 with its front edge 22. The first pressure device 7 presses the pressure plate 15 against the peripheral surface of the transport cylinder 17. The second pressure device 21 is pivoted away from the circumferential surface of the transport cylinder 17 by the cams 53 (FIG. 1), as is shown by the position of the pressure device 21 drawn with solid lines. The second gripper device 9 is open and pivoted away from the peripheral surface of the transport cylinder 17. The first gripper device 6 is closed by means of the cam control, which was previously mentioned in connection with FIG. 1. The rotation of the transport cylinder 17 takes place synchronously with the speed of the travel table by the drive via the gear wheel 50 and the rack 51.

5 shows a position in which the toner image 25 has already been partially transferred from the photoconductor 19 to the anodized surface of the printing plate 15 or the image carrier under the force of the transport cylinder on the photoconductor 19. The pressure plate 15 is partially guided around the circumferential surface of the transport cylinder 17 and still lies with its rear edge 23 on the feed 16, while its front edge 22 is inserted into the third gripper device 11. In this position, the second pressure device 21 is pivoted against the transport cylinder 17 and, together with it, transports the pressure plate 15 in the direction of the tray 20. The first and the second gripper devices 6 and 9 assume an upper position on the transport cylinder 17. The toner image 25 is transferred in strips in a transfer zone 8 from the photoconductor 19 to the printing plate 15. The toner contact is anchored in the pores of the anodized surface of the printing plate 15 by the pressure contact. As soon as the rear edge 23 of the printing plate 15 leaves the feed line 16, as can be seen in FIG. 6 from the dash-dotted representation of the printing plate and the second gripper device 9, the first pressure device 7 presses the pressure plate 15 against the transport cylinder 17. During further transport, the second gripper device 9 closes and presses the rear edge 23 of the pressure plate 15 against the peripheral surface of the transport cylinder 17. This prevents the rear edge 23 of the printing plate 15 from hitting the illustrated photoconductor 19 and ensures high resolution in the rear image area during image transmission. The third gripper device 11 grips the front edge 22 of the printing plate 15 and conveys it via the fixing device 14, which is switched on and burns the toner image 25 onto the printing plate 15, up to the upper end position of the third gripper device 11. In this position, the third gripper device 11 is moved over opened a cam and the fixed pressure plate 15 falls into the tray 20th

At the same time, the traveling table 3 with the photoconductor 19 passes under the unloading device 12. After reaching the end position, the traveling table 3 moves back into its starting position, the photoconductor 19 being cleaned by the cleaning device 13 which is then lowered. At the same time, the developing device 4 is swung up, all drives are moved back to their starting positions and the radiant heater of the fixing device 14 is switched off.

After the supply of a new printing plate 15, the cycle is started again and the printing plate 15, as described above, is bitdered and developed.

Claims (9)

1. An apparatus for transferring a toner image by pressure from a plane photoconductive surface to a heated metallic image carrier which is in linear contact with the photoconductive surface over the length of a transport cylinder during the toner transfer, characterized in that gripper mechanisms (6, 9), which are taken along by the rotating transport cylinder, for clamping and fixing the image carrier (15) on the transport cylinder (17) and stationary pressure mechanisms (7, 21) are disposed along the circumferential surface of the transport cylinder (17), it being possible to swing said gripper and pressure mechanisms out of the way of and to join them to the transport cylinder, in order to press the image carrier, which is fed to or is detached from the transport cylinder, respectively, against the circumferential surface of the transport cylinder, and in that the gripper mechanisms (6, 9) release the image carrier (15) upon completion of the toner image transfer.

2. An apparatus as claimed in claim 1, characterized in that a feed table (16) for the image carrier and an image-carrier deposit (20) are arranged in V-shape with respect to the transport cylinder (17), in such a way that an image carrier (15) to be fed-in and also an image carrier (15) to be deposited contact either side of the circumferential surface of the transport cylinder (17) in each case tangentially and inclined with respect to the horizontal.

3. An apparatus as claimed in claim 1, characterized in that a shaft (18) of the transport cylinder (17) is supported in links (30 and 30) which are vertically displaceable in guide rails (29 and 29), against the pressures exerted by pressure elements (26, 26 or 27, 27) and in that the distance between the upper side of the photoconductive surface (19) which is mounted on an upper part (65) of a travelling table and the circumferential surface of the transport cylinder (17) adjusts itself during toner image transfer, so as to correspond to the thickness of the image carrier (15).

4. An apparatus as claimed in claim 1, characterized in that a heat radiator (37) is provided in the interior of the transport cylinder (17), which heats the circumferential surface of the transport cylinder (17) and the image (15) to a temperature below the softening temperature of the toner image.

5. An apparatus as claimed in claim 2, characterized in that a fixing device (14) is arranged upstream of the image-carrier deposit (20), the image carrier (15) being conveyed over the fixing device (14) with its underside facing downwards, by means of the transport cylinder (17) and a second pressure mechanism (21), after its leading edge (22) has been released by the first gripper mechanism (6).

6. An apparatus as claimed in claim 5, characterized in that a third gripper mechanism (11) is provided upstream of the fixing device (14), which grips the leading edge (22) of the image carrier (15) to convey it over the fixing device (14) and which releases the image carrier (15) at the image-carrier deposit (20).

7. An apparatus as claimed in claim 6, characterized in that the third gripper mechanism (11) is transportable parallel to the image-carrier deposit (20) with the aid of a driving mechanism (52).

8. An apparatus as claimed in claim 1, characterized in that the gripper mechanisms (6, 9 and 11) are provide with gripper fingers (32) which are mounted on a shaft (33), wherein a leg spring (35) is arranged between each gripper finger (32) and a clamping ring (36) for closing the gripper finger, and in that the leg springs (35) within a gripper mechanism can be adjusted to different spring tensions.

9. An apparatus as claimed in claim 3, characterized in that a pressure medium is applied to the pressure elements (26) during the reversal of the travelling table (3) so that the transport cylinder (17) is lifted above the level of the travelling table (3).

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