DE1046477B - Method of making xerographic copies - Google Patents

Description

Method for producing xerographic copies In the known xerographic The printing process is first arranged on an electrically conductive plate photoelectric conductive layer charged and corresponding to that to be copied by Original falling light distribution discharged. That of those not struck by the light Dividing the Xeroplatte persisting charge image is then in a Electroscopic tinting powder dusted on developer device so that it is visible will. In a printing station, the powder image is finally printed on a paper web transferred and on this z. B. attached by heat or chemical solvents. With this method, cleaning and recharging after each image transfer the xero plate can only have one of each electrostatic latent image Copy can be made.

There are also xerographic methods become known, the one Allow any number of copies to be made from an original. With this one In the process, the tint image is fixed on the xeroplate itself. This permanent Image is loaded as often as required and according to the procedure described above dusted and transferred to a printing pad.

The invention relates to a method and a device for To carry out this process of creating xerographic copies, first a first latent charge image by means of electrically insulating tinting agent the photoelectric layer of the xeroplate is fixed. After that it will be at the same time the xeroplate carrying the fixed first charge image is charged again and accordingly exposed again to a second original. Eventually that gets pinned on the .first charge image located at the same time as that of the second original originating charge image developed by tinting agents and together on a printing substrate transferred and fixed. Are these original documents with consistent information several original documents that are individually effective for each transmission and printing process with different information, e.g. B. counting or punch cards, assigned, so can according to the invention these for the respective insertion of their information in the on the photoelectric The plate produced a permanent image as a function of the rotational movement of the xero drum fed by a transport device to a photoelectric sensing station will. This combination thus offers the greater advantage, e.g. B. to produce form letters, whose basic text is recorded as a permanent electrostatic image on the layered plate is inserted while the address or the like. Changing information in this picture and after a machine run for printing before adding a new address can be deleted again by a next card. The known advantages, which the xerographic printing process offers are expanded in this way, and for example, shaped letters are created that are uniform because they are printed in one printing process getting produced.

The control of the operation as well as that of the individual devices for fixing, printing, cleaning and erasing, etc. are advantageous from the controlled by the Mas®hin.enbetrieb dependent and activated control organs.

According to a further embodiment of the invention, the device can also be used as a mere duplicating machine, in which the effective Control of the fixing device for producing the permanent image and the printing device for transferring the powder image onto the paper web by counting or punching cards he follows. These punch cards can still be used to determine the number to be produced of copies received value markings that are used to monitor the machine aisles in a storage unit can be introduced.

Another advantageous embodiment of the invention consists in that the indications for the photoelectric plate from a screen of a cathode ray tube can be removed, which means, for example, in fast-working calculating machines Between- and final results can also be recorded quickly.

In the drawings, there is a printing device as an exemplary embodiment shown for the production of shaped letters. In the drawings, FIG. 1 shows a schematic representation of a xerographic printing device for production of printed documents, Fig. 2 the different work stages, Fig. 3 the original document, Maps for the head and a finished printed copy, Fig. 4 shows a part for locomotion the base, Figure 5 is a schematic representation of a xerographic printing device, in which a cathode ray tube is used for the optical input, Fig. 6a and 6b the circuit diagram for controlling the xerographic printing device, Fig. 7 shows a block diagram for driving the motor, FIG. 8 shows a cam diagram.

In the embodiment shown in FIG. 1, the cards are 10 for the original document, in this case for the letterhead, in the card magazine 11 stacked. They are selected one at a time at every card machine game The card magazine is stored in a storage magazine 12 via a transport device. Successive pairs of transport rollers 13 to 20 cause that with each card run a card is advanced over the brush sensing station 21 and the optical station 22 will. For reasons that will become clear as the description proceeds, the drive speeds are of the aforementioned transport rollers selected so that the cards with speeds are advanced over the brush station 21 and the optical station 22, the correlated with the surface speed of the xerographic drum 23 stand.

The optical station has a projector 24 through a window 26 throws a bundle of rays onto a mirror surface. Each card 10 passed by the Station 22 is guided, is therefore exposed to an exposure. being one on the Card printed image, here designated 27 (see also Fig. 3), on the photoelectric Layer surface of the photoelectric plate 29 on the xerographic drum 23 is transmitted.

The cylinder of the xerographic drum is rotatable on a shaft 28 and is driven clockwise by an electric motor (Fig. 7). On this drum there is a photoelectric plate 29 (Fig. 1), which for example from a photoelectric layer of amorphous selenium on an electrically conductive one Carrier layer 32 consists of aluminum. The plate 29 is around the cylinder 33 placed and in the usual way, e.g. B. by means of suitable clamping devices on it attached. However the attachment is carried out, it is essential that that the layer 32 of the photoelectric plate 29 is in good electrical contact with the drum cylinder electrically grounded and connected to the shaft 28.

During the first machine run, a formal document 34 (Fig. 3) moved from a conveying station 36 to a receiving point 37. During this Time this pad 34 is removed from the xerographic drum 23 between the layer plate 29 and a transparent belt 38 moves. The clear strap will go through a pair of freely attached wheels 39 and 41, each driven by a arranged on a frame support shaft and supported by springs 43 and 44 are pressed against the outer surface of the cylinder 33 - as will be explained later is, no card is transported through the optical station 22 when a pad 34 from the xerographic drum under the clear belt and over the Exposure point 45 is pushed. In this case, the mirror 46 through the Lenses 47 and the transparent belt 38 provide a uniform beam of light in pretty much constant strength on and through the pad 34 reflected.

The xerographic drum 23 is driven by a motor via a shaft 28 driven clockwise. As soon as successive fields of the photosensitive and photoelectric layer 31 via those known in the xerographic method ion generating charger 48, the aforementioned layer becomes electrostatic charged.

A cam 49 is also located on the shaft 28 of the xero drum (Fig. 1), which in the first machine gear at approximately 71 ° on a slide 51 acts (FIG. 8) in order to press it against a spring 52. With this movement the slide 51 releases an opening 53 for the substrate 34 to pass through. As a result the impact of the tensioned driver 54 on the rear end of the pad 34 becomes the front end of the pad between the clear straps 38 and ply board 29 pushed. The driver 54 is slidably attached to the support frame 55. As soon the front end of the photoelectric plate 29 is slightly behind the advanced one Opening 53 is located, this is opened, and thus the substrate is in the conveyor station 36 released. The pad is then together with the plate 29 over the constant Light radiation that passes through the transparent belt 38 to the exposure point 45 penetrates, advanced. By exposing the photoelectric surface to the photoelectric Plate 29 with the optical image of the substrate 34 is a latent, creates an electrostatic image; as is well known, this image arises from the fact that the electrically charged fields of the photoelectric layer 31, which the light rays hit directly, are discharged, while those not exposed by the light rays Fields stay charged. That way remains after the transfer of the document on the plate a latent electrostatic image that corresponds to the specifications of the original Document 34 corresponds. On the electrostatic picture represent the dark fields the information on the document which hold the electrical charge while the The light areas representing the background of the documents are no longer charged are.

By continuously rotating the xerographic drum 23 clockwise the pad 34 is pushed into a storage station 37, where the fingers 83 and 84 strip the pad 34 from the plate 29 (Fig. 4). Through the continuous Rotation also turns the electrostatic latent image on the platen 29 into one Brought in their action known development chamber 56 (Fig. 2). In the development chamber the xerographic developer, for example the corresponding powder the photoelectric surface of the layered plate, over the entire latent, electrostatic Distributed image. By the developer who only worked on the aforementioned dark fields of the plate 29, which is charged, is formed on the surface of the photographic plate an image which is the latent, electrostatic image visibly outlines. The excess xerographic developer not on the surface of the plate29 remains adhered, falls in the chamber 56 and into a corresponding receptacle.

As the xerographic drum continues to rotate, the image becomes brought on the plate 29 from the chamber 56 into the area of a fixing station 57, so that the powder particles are somewhat compressed on the image layer and on the Surface of the photoelectric plate 29 are adhered. At this station 57 is located an electromagnetically controlled spray gun in which there is a fixative 65, for example methylene chloride, is located. By actuating the piston 58 in a manner which will be explained later, the nozzle 59 becomes a jet and Solvent hurled onto heated element 61. This heated atomizer element has the task of converting the large particles in the solvent jet into vapor form immediately Split particles. For better fixation, the fixative is steamed radiated onto the image so that there is a permanent image of insulating material arises, which adheres to the photoelectric layer 31.

After the fusing station 57, the image is transferred to the printing station. During the first machine run, the moving one is the one that initiates the imprint Transfer roller 62 is out of action, so that no printing of the xero image takes place. Since the printing device is known per se and is not part of the present invention heard, it is not explained in detail.

The impression roller 62 consists of an inner current-carrying part 63 made of metal and an outer part 64 made of very elastic or soft material with a high electrical resistance of at least 10s ohms per cm3, for example a layer of soft conductive rubber. The arm 68 to which the roller 62 is attached is normally held in a certain position by a spring, so that the roller 62 is lifted from the surface of the xerographic drum 23 and the paper web 66 with the surface of the xerographic drum 23 and of the photoelectric plate 29 does not come into contact. To bring about a After the impression, the solenoid 67 is energized. This is the arm 68 around the Axis 69 moves, causing the impression roller 62 against the surface of the xerographic The drum 23 is moved and the paper web 66 is brought into contact with the xeroplate 29 will. The positive voltage applied to the impression roller causes the pressure on the Xerobild adhering powder particles are transferred to the paper web.

Around any xerographic developer powder particles left on plate 29 before the next electrical charging of the fields of the photoelectric layer by means of The ion generating loader 48 is a rotating plush roller 71 available. This cleaning roller is mounted in a housing 72 that the developer particles removed by the roller moved clockwise on the platen 29 records. A suction device (not shown) can also be connected to the housing 72 to suck up the xerographic developer particles accumulated in the housing.

As the xerographic drum continues to rotate clockwise the fields of the layer plate 29 reach a station 73 for cleaning the permanent image layer. During the first machine aisle and all aisles of the Printing facility for original documents up to and including the machine aisle NTH is the device for cleaning the image layer inoperative. After, however the last original document has been transferred onto the paper web 66, the device becomes 73 put into operation for cleaning as a result of the excitation of the magnet 74. This Magnet attracts an armature 75 which swings about a pivot 76 so that the three rows of cleaning sponges 77 attached to the upper part of the anchor 75 for the layer plate can be brought into contact with it. At this point there a cam member 78 also attached to the upper part of the armature has an opening 79 free so that something through corresponding connecting tubes 80 to each of the sponges 77 liquid developer solvent 81 can flow. Those saturated with solvent Sponges 77 act in such a way on the surface of the plate that this is cleaned, d. H. adhering fixed developer particles are removed. the Sponges are. best attached to their holders so that they can be replaced when replacement is required can be changed quickly. During the second machine gear the successive fields of the photoelectric plate 29, which are the permanent Image layer contains insulating material, electrically charged by it be conveyed via an ion-generating charging unit 48 (FIG. 2). At approximately 38 ° of the second machine aisle, the card 10 containing the first information is passed through a card transport device is guided to the first transport roller set 13 and 14. The operation is such that this card is brought over the optical station 22 is, through which the information 27 (Fig. 3) of the card on the advanced section the photoelectric plate 29 can be projected. In the chosen embodiment this section corresponds to the field 35 of the pad 34 (Fig. 3) and is located also within the boundaries of the permanent picture layer. According to this optical Transfer of the information field to the corresponding field of the photoelectric layer 31 an electrostatic image of the information field of the card is formed thereon. In view of the fact that the existing permanent image layer on the xerographic Plate 29 is made of an insulating material (in reality fixed xerographic Developer), the permanent image layer is exposed to light Charging unit 48 has not been canceled. After that photoelectric layer 31 with the optically scanned indication portion 27 of the card has been exposed, is a latent, electrostatic on the xerographic plate 29 Image that corresponds to the information on pad 34 and card 10. With this latent electrostatic image, an original document 34a (Fig. 3) is produced, which contains information from both formal document 34 and card 10.

When the laminated plate 29 is passed through the developing chamber As a result of the action of the xerographic developer, 56 becomes the latent, electrostatic Image developed (Figs. 1 and 2). Should now this powder picture for the production of a Original document are transferred to the paper web 66, so the fusing station 57 do not come into effect while the impression roller 62 is transferred into the working position is, so in a position in which the paper web 66 during the second machine cycle with the xerographic drum in touch is brought. the electrical voltage, which is conducted into the impression roller, then causes that the charged developer particles from the xerographic drum onto the paper roll hike. Since the developer particles are colored, they stand out on the paper web 66 and deliver a clearly legible printed original document. For fixation of these images transferred onto the paper web 66, the pressure rollers 77 and 78 become used. For example, a pressure of 500 pounds per inch will cause the xerographic developer particles penetrate into the fibers of the paper web material. An oil pad 79 is provided to remove excess developer particles. which is located on the upper fixing roller 77. For the sake of simplicity, In the exemplary embodiment (FIG. 1), a paper web 66 instead of individual sheets shown. The paper web can of course be trimmed after printing to get individual documents. The arrangement for the transport of the paper web and the control of them is not described since they do not belong to the invention.

As long as there are cards 10 in the card magazine 11 for transport, every second machine cycle is similar to the second machine cycle described. After the last card 10 has been fed from the card magazine 11 during the machine aisle n the last original document is produced on the paper web 66. After manufacture of this last document the device 73 is put into operation for cleaning and the permanent image layer on the photoelectric plate 29 is removed.

As already mentioned, during the machine operation that is on those follows, in which the last document is printed on the paper web 66, d. H. while the machine aisle n + 1, the device 73 is put into operation for cleaning, d. H. the magnet 74 is excited by circuits which will be described later, whereupon the armature 75 is pivoted so that the saturated with solvent Sponges 77 to the surface of the layer 31 on the photoelectric plate 29 be brought into cleaning position. While the sponges 77 are in the cleaning position are, by the continuous rotation of the xerographic drum 23, the permanent image layer of insulating material removed (Fig.2) and thus the entire photoelectric layer 31 of the plate 29 cleaned and ready for the next Series of original documents prepared.

If, for example, it is assumed that a so-called form letter dealing with medical matters is to be sent to five hundred persons in the medical profession, such original documents and the like must be produced. The formal document, which contains all the information for such a letter, with the exception of the information for the letterhead, in particular the name and address, is placed in conveying station 36 (FIG. 1). Five hundred cards 10, each of which contains the address information for the letterheads, are placed in the card magazine 11. By pressing the start button, the contacts 91 (Fig. 6a), which are open in the rest position, close in order to close a circuit to the relay 10 from line 92 through the stop button contacts 94 and start button contacts 91 closed in the rest position to the relay R 10 and from there to line 93. The power supply lines 92 and 93 are connected to a corresponding power source, which is denoted by 96. Since the card magazine contact 97 is always closed when there are 11 cards in the card magazine (Fig. 1), and the relay R10 responds by pressing the start button, a holding circuit is closed for the relay RIO, from the line 92 via the contacts 94, 97 and R 10a to relay R10 and from there to the other side of the line. The power supply for the motor 98 (FIG. 7) and the electromagnetic clutch 81 is prepared by these circuits. As soon as the machine is to be stopped by pressing the stop button, the stop contact 94 (FIG. 6a), which is closed in the rest position, is opened. However, the hold circuit for relay R10 via cam contact C6 is maintained up to approximately 355 ° (Fig. 8) of a machine gear. This process also takes place when the card magazine contact 97 opens after the last card 10 has been transported out of the card magazine 11 .

It is mentioned that the CF cams only work when the card feeder is working. The C-cams and CB-cams, on the other hand, are effective when the Xerotrommel rotates.

As soon as contact R 10 b closes, the control relay speaks HD for the high-performance motor, whereby the contacts HDa (Fig. 7) and HDb close so that the electric motor 98 and the electromagnetic clutch 81 can be connected to the power source 99. The motor 98 is used to drive the Card feeder and the xero drum. As can be seen from Fig. 7, the drive motor 98 is connected to the control cam 25 of the card transport device by the coupling 101 connected. The clutch 101 is controlled by the clutch magnet 102 (Fig. 6 a), the mode of operation of which will be explained later. The coupling 81 is used for coupling of the drive motor with xero drum. Both clutches engage at 290 ° of the machine aisle a (Fig. 8), which follows the one in which the control magnets from this Reason to be put out of action.

The first gear of the machine is achieved by pressing the start button 91 initiated and thereby the motor 98 put into operation. After the clutch 81 has also been put into operation, the xerographic drum 23 is at 29 ° des first gear driven. Once the front end of the photoelectric plate 29 (Fig. 1 and 2) rotates clockwise, the loading unit 48 is the Layer 31 is electrostatically charged. At approximately 71 ° (Fig. 8) the slide will 51 actuated by cam 49, and the front end of the pad 34 is through the Opening 53 carried out between belt 38 and plate 29. With this movement will the substrate passed the exposure point 45, where a constant light beam is reflected by mirror 46 onto the xerographic drum. About the pad 34 therefore becomes a latent, electrostatic layer on the photoelectric layer 31 Image made. As the xerotrommel continues to rotate, the fields arrive of the photoelectric plate to the developing chamber 56, within which the latent, electrostatic image is developed, creating the electrostatic image becomes visible. This visible image then corresponds to the formal document.

Close at approximately 48 ° of the first machine gear (Fig. 6 a and 8) the cam contacts C 1 to a circuit to respond to the relay R 1 P and R2P to close. The cam contacts CF1 in the relay @ R2P circuit close at 22 ° and interrupt at 40 ° of a card feed machine game. There the clutch 101 (Fig. 7) engages at 29 ° of a machine gear and during the first. Machine gear remains engaged because clutch magnet 102 is not in action is, the cam contacts CF1 close when the cam contacts C 1 during the first Close machine aisle. The cam for controlling the CF 1 contacts is only rotated when when the clutch 101 is effective. In all subsequent machine aisles, when the cards 10 are transported from the magazine 11 to the tray 12, the cam contacts CF 1 disconnected when the cam contacts C1 close and the relay R2P speaks not on.

The hold circuit for the. Relay R2 goes from line 92 via the Contacts R 10c and R 1 a. to relay R 1 H and from there to the other: side of the line. A circle parallel to the contacts R 10c closes the cam contacts C 11 and the magazine contacts 82, so that relay R 1 is held for as long as that Relay R 10 or as long as there are 11 cards in the magazine. The holding circle. for Relay R2H is approximately via the contacts C2 (Fig. 8) and relay contacts R 2 a 54 ° to 18 ° of the second machine gear effective. From this it can be concluded that if the start button was pressed once, relay R 1 in the addressed The state remains as there are 11 cards in the magazine, whereas the relay R2 remains energized for only one gear following the first machine gear.

The leading edge comes at approximately 216 ° of the first machine aisle the plate 29 in the effective area of the fixing station 57 (Fig. 1). Since from the If a permanent image layer is to be made, powder painting must be done during this first The image layer is fixed in the fixing station 57 during the machine cycle will. Thus, at approximately 216 °, the magnet 103 for the spraying of the fixing agent becomes energized, via line 92 (Fig. 6 a), cam contact C 3, relay contact R. 2 b, R 11 d and R 12 e, after magnet 103 and from there to line 93. In the time between 216 ° and 314 ° are all fields of the layer plate 29 on which the powder image is is., guided by the fuser 57. This control magnet 103 is up 314 ° six-channel excited and put out of action again. In this way, the Pistons 58 actuated reciprocally one behind the other to direct the solvent jet 65 onto the To direct thermal element 61. The solvent jet is through the heating element 61 evaporates, and this permeated steam fixes the powder image on the plate 29

The leading edge of the laminate is at approximately 270 ° 29 at the level of the movable pressure roller 62. Since during the first machine run the relay R2 responds, the magnet for controlling the impression roller 62 is not energized because the circuit for the magnet 67 is closed in the normal state. Includes contacts R 2 c.

In the different work stages: charging, exposure, developing and fixing, which take place during the first machine run (Fig. 2) on the surface of the photographic plate 29 a permanent image layer is generated and attached.

The card feed clutch magnet is activated on the second machine run 102 for controlling the clutch 101 (FIG. 7) as a result of the during all machine gears effective relay R 1 (Fig. 7) for the first time at approximately 20 ° and up to 40 ° of the second Machine gear excited. The circuit for energizing the magnet 102 is of conduction 92 via contacts C 5, R 1 b and R 14 to magnet 102 and from there to the other Side of the line closed.

This current flow to excite the magnet 102 causes the card transport cam 25 (Fig. 7) mechanically coupled to the drive motor 98, so that at approximately 38 ° of the second machine gear the cam roller 30 (Fig. 1) for driving the card knife falls into the cutout of the cam 25. The card knife pushes the bottom one Card 10 from the magazine 11 against the first pair of transport rollers 13 and 14. The transport rollers. 13 and 20 operate so that each card 10 transports at one speed which is correlated to the surface speed of the xerographic drum 23 stands, i.e., the interrelationship of the speed is chosen so that the Information field 27 of each card 10 in the station 22 is then scanned when the corresponding Part of the xero image is present on layer 31; this is part 35 of the formal documents 34 (Fig. 3), which is conveyed via the optical station. At the second machine aisle the slide 51 (Fig. 1) is actuated by cam 49, but this is irrelevant, since there are no more documents in the transport station 36.

In the second machine aisle, the first card is scanned as soon as it is passed through the optical station 22, thereby removing from the printed indication 27, which can be an address (FIG. 3), has a latent, electrostatic image the corresponding field of the photo layer 31 is generated. That already from the formal document permanent image produced on layer 31 is of insulating material, so that no discharge takes place during irradiation. All other fields of the photoelectric However, apart from the card field just mentioned, the field 35 corresponds, discharged by the incident light rays. With the ongoing Rotation of the xerotrommel will only display the charged fields through the xerographic Developer developed in chamber 56.

As soon as the xerographic plate 29 in is passed through the effective area of the fixing station 57, the finished development becomes Powder image not fixed because the control magnet 103 (FIG. 6) is due to the open contact R2b does not respond.

During this second machine cycle, the imprint magnet 67 is at energized to approximately 270 °, thereby forming the impression roller 62 (Figs. 1 and 2) against the xerographic plate 29 to move. Then the developer particles, which the original document designated in FIG. 3 with 34a for visual representation bring and electrostatically adhere to the image layer, on the surface of the paper web 66 transferred.

The movement of the paper web is controlled by a device (not shown) controlled. The advance of the paper web together with the plate 29 takes place only while the paper web is in contact with it. The paper web can then be pushed through a paper cutter. to the continuously appearing Separate documents into individual original documents.

At the nth machine gear, the last card 10 is removed from the magazine taken. An imprint on the paper web is achieved in the same way as with second machine organ. While this machine k # Banges open up However, the magazine contacts 104 closed in the normal state (Fig. 6a), since the the last card was pushed out of the magazine 11. As soon as this last card from the Transport rollers: 13, 14 captured and transported to transport rollers 15 and 16 the card lever contact 107 closes as a result of the action of the card on the card lever 106. By closing the contacts 104 and 107, the n-th machine gear the relay R11 energized. A. Holding circle for this Relay is made by the cam contacts C7, which - as Fig. 8 shows - of close approximately 59 ° to 40 ° of the next machine aisle. This holding circle goes from line 92 via contacts C7 and R 11 a to relay R 11 and from there to Line 93. At approximately 20 ° of the next machine aisle, i. i.e., at gear n + 1, the contact C8 closes to follow from line 92 via contacts C 8 and R 11 b Relay R 12 to line 93 to establish a circuit. The hold circuit for relays R12 is via contacts C 9 and R 12a, up to: approximately 10 ° of the machine gear n + 2 built.

There. the magazine contact 97 opens at the same time the magazine contact opens again 104 closes, the hold circuit for relay R 10 becomes during machine operation n interrupted when the cam contact C6 is at approximately 355 ° of the machine gear n opens. Since relay R 11 has already responded when relay RIO drops out, it remains the motor control relay is HD via contact R 11c under power. As a result of the fact that relay R 11 drops out at approximately 40 ° of the machine gear n + 1 when the cam contact C7 opens (Fig. 8), the contact R 12b is parallel to the contacts R 10b and R 11c switched so that the highly sensitive motor relay HD for a sufficiently long deceleration time is kept under current.

The relay R 1 drops out at 355 ° when contact R10c opens, da Contact 82 is already open. The card feeder is therefore at 29 ° des Machine gear n + 1 ineffective, since the contact is open in the normal state as well R 1 b prevents the establishment of a circuit to the clutch magnet 102.

At approximately 30 ° of the following machine bend n + l, contact closes C10 (Fig. 8) to provide a circuit to magnet 74 for the cleaning device 73 (Fig. 1 and 6a) to close via the contact R 12 d. The operation of this device causes. that the sponges 77 are in contact with the surface of the electrophotographic plate 29 to be brought. By the continuous rotational movement of the xerotrommel 23 along the solvent-soaked sponges 77 becomes the permanent image layer of the plate 29 removed and the plates oherfläche cleaned.

As the xerographic drum continues to rotate, the photoelectric Layer 31 charged by the unit 48 and by the following irradiation with Discharge light beams of constant strength in station 25. Because at this point there is no electrostatic charge on the xerographic plate 29. is omitted the development (Fig. 2). The magnet 103 for fixation is not excited because Contact R 12 e is open. The pressure magnet 67 is also not energized because the Contacts R 12c are separated. At approximately 10 ° of the machine gear n + 2 falls the relay R 12 from, and the motor magnet HD, as well as the motor 98 and the electromagnetic Clutch 81 (Fig. 7), put out of action. The xerographic drum is coming but only to a standstill when the clutch 81 engages at 29 °.

The xerographic printing device shown in FIG. 1 can also find use as a duplicating machine; that's a machine with which a certain number of copies can be made from a single printing sheet. When using the xerographic printing device as a duplicating machine only one is the document to be copied 34 in the conveyor station 36 and two cards 10 placed in the card magazine 11. The second or top card in the card magazine is a blank card. It is necessary to control the card magazine contacts, while the xerographic machine makes a large number of copies of the base. There are none on the first or bottom card 10 in the card magazine 11 transferred information; but only one perforation in a control column, the one Represents the number of copies to be made.

After pressing the start button, the xerographic printing device begins to work in the manner already explained. The document is placed over the exposure station 25 pushed to by her on the photoelectric layer 31 of the electro-photographic plate 29 to create a latent, electrostatic image. During the first machine run this latent, electrostatic image is developed in the chamber 56 and through a device of the station 57 is fixed. In the second machine aisle, the resulting permanent image layer charged by unit 48 and developed in chamber 56, so that a powder image is available for transfer to a paper web 66. At the The second machine aisle becomes the first or lowest through the card transport device Card 10 between: the transport rollers 13 and 14 pushed. The punching in the Control column of the card is sensed in the station 21 in a known manner and in a memory controlled by an adding magnet 111 (FIG. 6 a). When storing a value other than zero, the transport will be the second card from the magazine 11 and prevents the production of such a large number of copies that correspond to the value stated on the card.

Assume that the first card 10 (Fig. 1) has a number punch 4 contains, this value is introduced into the memory in a known manner. This is controlled by magnet 111 through the circuit on line 92 via cam contacts CB 1 and CB 2, card lever contact 112, sensing station 21, plug connection 113 and 114, contact R 16 b to the adding magnet 111 and from there to the other side the line. The relay R 16 is energized at this point, since R16p is at 54 ° of the first machine gear is energized via cam contact C 2, and via cam contact C12 (Fig. 6b) to 90 ° of the next or the second. Machine gear held will. The subtraction magnet 87 receives a pulse in the zero position of the memory, to uncouple the storage tank. The relay R14p is at 279 ° of the first machine gear addressed as soon as cam contact C40 closes and is triggered by the circuit held by line 92 via contacts R 15 a and R 14 b. The switch 86 prevents that the circuit of relay R14p is closed during other machine work will. It should be noted that relay R'15 is only addressed during machine operation can be if the Switching arm 116 with the contact segment 0 and the common contact bar 115 is in contact. Thus, if the digit value 4 is transferred to the memory during the second machine cycle, the relay R15 do not respond during this machine operation because the switching arm 116 with the contact segment 4 and the contact bar 115 is in connection. The in itself known value output can be used together with the memory. The relay R14 remains energized, and the clutch magnet 102 (Fig. 6 a) is not energized when Cam contact C5 closes. In addition, after cam contact C12 is interrupted at 90 °, the relay R16 de-energized for the second machine gear and a circuit to the adding magnet 111 closed. At index "9", this goes via the cam contacts CB3 and CB 4 and the relay contacts R 14 c and R 16 b. This circuit is during the third, Machine gear effective to bring a value 9 into the memory. The entrance this number causes the switching arm 116 from the contact segment 4 to the contact segment 3 is transferred. Relay R15 is therefore not activated during the third machine gear addressed. During the fourth machine aisle, a numeric value is displayed again 9 conducted impulse over the described. Circuit introduced into the memory, and the switching element 116 is moved from the contact segment 3 to the contact segment 2. Similarly, in the fifth machine gear, a digit input 9 causes the through the magnet 11 controlled switching arm 116 from the contact segment 1 to the contact segment 0 slides.

At 144 ° of the fifth machine gear, relay R 15 is activated by cam contact C13 effective. As a result, relay R14 drops out immediately, as contacts R 15 a interrupt, and the circuit including contacts CB3 and CB4 is interrupted, when the contacts R 14 c open. Also is the circuit to the clutch control solenoid 102 such that the clutch magnet 102 is at 20 ° of the fifth machine gear is excited. Then the second card 10 is transported from the magazine, and because If this card does not contain any control features, it is simply placed in the storage magazine 12 brought. It is not absolutely necessary to have underlay sheets to make copies or the like. Another improvement of the invention, shown schematically in Fig. 5, consists of the use of a cathode ray tube 120 which is powered by circuits for the formation and display of characters and books: -stabend: arstellung controlled will:. The corresponding circuits 121 are triggered by mechanically controlled trigger arrangements switched and z. B. turned on at the time when the optical exposure necessary is. After exposure of the photoelectric layer on the plate 29 with the characters formed on the screen of the cathode ray tube becomes the Trigger 122 turned OFF to clear the CRT setting. The device for forming characters on the surface of a cathode ray tube 120 and for projecting the characters onto a surface is known and required therefore no further explanation.

Claims (12)

PATENT CLAIMS: 1. Method for producing xerographic copies, characterized in that first a first latent charge image by means of electrical. insulating tint is fixed on the photoelectric layer of the xero plate becomes that afterwards the recharged, at the same time the fixed first charge image the supporting xero plate is exposed again according to a second original, and that finally the charge image located on the fixed first charge image simultaneously with the charge image originating from the second original by toning agents is developed and jointly transferred and fixed on a printing material. 2. Device for carrying out the method according to claim 1, characterized in that that an original document with constant information (34) several for each Transfer process individually effective original documents with different information (10, 27) are assigned, and these for the respective insertion of their information in the permanent image formed on the photoelectric plate (29) depending on the rotation of the xero drum (23) by a transport device (13, 14, 19, 20) to a photoelectric sensing station (22). 3. Device according to claim 2, characterized in that the original documents with different Information (10) recording media, in particular punched or counting cards, with a printed information field (27). 4. Device according to claims 2 and 3, characterized characterized in that the imprint of the powder image present on the xero layer on a paper web (66) causing the impression roller (64) controlled by an element (67) its effectiveness by the control organs monitored by the machine operation (C4, R2) depends. 5. Device according to claims 2 to 4, characterized in that that the atomization of the fixing liquid (65) with a to heat the atomizer element (61) equipped fixing device an electromechanical drive means (magnet 103), which depends on control organs (C3, R 2 b, R 11d, R 12e) only for is effective in certain machine aisles. 6. Device according to the claims. 2 to 5, characterized in that to delete the information on the photoelectric Plate (29) and for cleaning the same one under machine control (C 10) equipped with sponges (77) connected to a liquid cleaning agent Device is used. 7. Device according to claims 2 to 6, characterized in that d: ate a slide controlled by the cam (49) rotating with the xerotrommel (53) the release of the original document (34) moved by a driver (54) for Induced introduction into the exposure station (45). B. Device according to the claims, 2 to 7, da: d'arch indicates that the coupling of the transport device (13, 14 to 19, 20) for the recording media (10) with different information to the drive motor (98) of. a clutch dependent on machine operation (101) is monitored. 9. Device according to claims 2 to 8, characterized in that that the drive of the Xerotroinmel (23) monitored by one of the start button (10) Coupling (81) takes place. 10. Device according to claims 2 to 9, characterized in that that effective control the fixing device (57) and the printing station (64, 66) takes place via counting or punch cards (10) .. 11. Device according to the claims 2 to 10, characterized in that to determine the number to be produced Copies of a counting or punch card (10) containing value information, which are in one of the machine aisles monitoring counting memory (111, 115) are transferred. 12. Device according to the Claims 2 to 11, characterized in that the one on your screen (123) Cathode ray tube (120) generated information directly on the layer of photoelectric Plate (29) are transferred.