EP0778129A1 - Digital printing machine and method for its conveying of sheets - Google Patents

Abstract

The machine has sheets of paper or other material transported in sequence on a linear feed conveyor Ä1Ü belt. The sheets are engaged by a print roller Ä3Ü that has an electrically charged print image formed by a printing head Ä6Ü as the roller rotates. The sheets are retained on the belt by an electrostatic charge. In order to ensure that separation does not occur, the print roller is set at an angle Ä alpha Ü to the belt. The print head Ä6Ü is at this angle or perpendicular to the belt edge.

Description

The invention relates to a digital printing press and a method for sheet transport by means of an endless conveyor belt past one or more digital printing units.

A digital printing press contains one or more printing units in which a write head which can be controlled by electrical signals generates latent images on a movable intermediate carrier which correspond to the electrical signals. The latent images can be charge distributions of electrons or ions on the intermediate carrier, for example. The latent images are developed by an inking unit by applying printing ink to the intermediate carrier in accordance with the charge distribution. The printing ink is then transferred either directly from the intermediate carrier or via one or more further intermediate carriers to substrates to be printed, such as paper sheets.

Rotating cylinders or belts rotating around rotating cylinders are used as intermediate carriers. The sheets to be printed are transported past the intermediate support or the last one from a series of intermediate supports connected in series, the color e.g. B. is transmitted by more or less strong pressure on the sheets.

For the transport of the sheets past the printing units, endless conveyor belts have been proposed which have an elongated section on which the sheets of a feeder stack can be transported to a delivery stack. The required transfer pressure can e.g. B. be applied by impression cylinders, which are arranged on the side of the conveyor belt opposite the sheets, so that the conveyor belt and thus the sheets are pressed against the intermediate carrier of the printing unit.

When a sheet emerges from the printing gap between the conveyor belt and the intermediate carrier, there is a risk that the sheet will stick to the intermediate carrier and detach from the conveyor belt. This must be prevented under all circumstances.

For this purpose, one can use, for example, a conveyor belt made of an insulating material that is electrically charged in order to hold the sheets on the conveyor belt by electrostatic attractive forces. As has been shown, however, relatively strong holding forces are required to reliably prevent sheet detachments. Generating such strong holding forces is not only complex, but also complicates the separation of the sheets from the conveyor belt for delivery to a delivery stack after they have passed the printing units.

The object of the invention is to reliably hold the sheets on the conveyor belt with only slight holding forces when they pass through an intermediate carrier from which the printing ink is transferred to the sheets.

This object is achieved according to the invention by a printing press according to claim 1 and by a method according to claim 8.

According to the invention, the sheets are not run with their entire leading edge at once into the pressure gap between a cylinder and the conveyor belt, as in Printing press is common, but in an inclined position to the cylinder. As a result, there is always only a small section of the sheet leading edge along the sheet width in a critical area in which there is a risk of detachment. Therefore, the inherent rigidity of the sheets in connection with their interface adhesion on the conveyor belt may be sufficient so that they leave the printing nip reliably without detaching from the conveyor belt.

Additional support forces acting on the conveyor belt can be used to support this, which advantageously cooperate with the type of sheet inlet into the printing nip according to the invention. The areas on the sheet adjacent to the critical area mentioned have an overall much larger area than the area currently in the printing nip. As a result, the areas that are not currently in the printing nip, even with relatively weak holding forces, are able to hold back the narrow section of the leading edge of the sheet on the conveyor belt that is currently in the printing nip.

The invention is particularly suitable in connection with electrostatic holding forces which can be generated in a very simple manner, but which become smaller in proportion to the distance of the sheet from the conveyor belt. While in this case even a slight sheet detachment can no longer be repaired in a conventional type of sheet inlet and leads to a malfunction of the printing operation, any partial sheet detachments that occur in the inventive type of sheet inlet can be reversed by the adjacent areas.

On the other hand, the invention is also useful in connection with supporting holding forces on the conveyor belt, generated in any other way than electrostatic, e.g. B. by slight negative pressure.

The invention has the additional advantage that shocks are avoided when the sheets enter or exit the printing nip. This shock absorption is particularly effective when the sheets follow one another closely, so that a new sheet already enters the printing nip on one side if the previous sheet has not yet left the printing nip.

The invention can be implemented in two alternative ways. Either the sheets are conveyed onto the conveyor belt by a feeder in a conventional manner, namely with their leading edges exactly at right angles to the direction of transport, and the cylinders on which the ink is transferred are tilted. Or the cylinders are arranged in a conventional manner at right angles to the direction of transport, and the feeder is set up to place the sheets on the conveyor belt in a desired inclined position.

In both cases, use is made of the fact that digital printing machines have a writing device which generates the latent images on the basis of image data on an intermediate carrier. Either the image data are changed or influenced according to the inclination of the sheets before they are fed to the writing device so that the sheets are subsequently printed undistorted and true to the original, or the writing device is arranged at an angle to the intermediate carrier which corresponds to the inclination of the sheets.

Fig. 1

eine Teilansicht einer digitalen Druckmaschine in Längsschnitt; und

Fig. 2

eine Teilansicht einer digitalen Druckmaschine von oben.

Further features and advantages of the invention result from the following description of several exemplary embodiments and from the drawing to which reference is made. The drawing shows:

Fig. 1

a partial view of a digital printing machine in longitudinal section; and

Fig. 2

a partial view of a digital printing machine from above.

The printing machine shown in section in FIG. 1 contains a conveyor belt 1, which transports sheets 2 lying thereon one behind the other in the direction of an arrow P from a feeder stack to a delivery stack, both of which are not shown. The sheets 2 can be sheets of paper or any other substrates to be printed, e.g. B. plastic films.

A transfer cylinder 3 is rotatably supported above the conveyor belt 1 or the sheets 2 about an axis 4. An impression cylinder 5 is rotatably mounted below the conveyor belt 1. The transfer cylinder 3 and the impression cylinder 5 extend in their axial direction across the printing width of the sheets 2. The transfer cylinder 3 and the impression cylinder 5 press against each other, so that the sheets 2 are pressed against the impression cylinder 3 when they are removed from the conveyor belt 1 by the Printing gap between the transfer cylinder 3 and the impression cylinder 5 are transported. The conveyor belt 1 has an insulating surface which is electrically charged by a device not shown, so that the sheets 2 adhere to it electrostatically during transport. Alternatively or additionally, the arches 2 can be suitably electrically charged.

Image data is supplied to a write head 6 arranged and schematically drawn in at one point on the circumference of the transfer cylinder 1, by means of which the write head 6 generates latent images on the transfer cylinder 3, e.g. B. in the form of charge distributions that correspond to the desired print images. The latent images are developed by a schematically shown inking unit 7 in accordance with the charge distribution by selectively applying printing ink to the transfer cylinder 3, and the developed images are then transferred to the sheets 2 by more or less strong pressure and fixed thereon by means not shown.

When a leading edge 8 of the sheet emerges from the printing gap between the transfer cylinder 3 and the impression cylinder 5, there is a risk that the leading edge 8 of the sheet will detach from the conveyor belt 1 despite the electrostatic holding force and remain attached to the transfer cylinder 3, as shown in broken lines.

This is avoided by the fact that the transfer cylinder 3 (and correspondingly the impression cylinder 5) is not mounted at right angles to the transport direction P on the printing press, but rather at an angle to it, as can be seen in the top view of FIG. 2. Since the sheets 2 lie at right angles on the conveyor belt 1, ie with their front edge 8 perpendicular to the transport direction P, the axis 4 of the transfer cylinder 3 forms a small angle α with the front edge 8 of the sheet. While in FIG. 2 an angle α of approx. 10 ° is drawn, this can also be much smaller in practice. For the dimensioning of the angle α, it is essential that when a sheet 2 enters, only a small part of the sheet leading edge 8 is always in the printing gap between the transfer cylinder 3 and the impression cylinder 5. With a width of Pressure gap of z. B. 0.5 to 1 mm in a given machine configuration, an angle α of 1 ° or less is sufficient to achieve this.

The inclined position of the transfer cylinder 3 ensures that the sheets 2 are less easily detached from the conveyor belt 1 when they leave the printing nip. In addition, shocks are avoided when the sheets 2 enter and exit the printing nip. Such shocks are avoided particularly reliably if a distance a between successive sheets 2 is small, so that at least one sheet 2 is in the printing nip at all times.

The write head 6, the z. B. is an elongated array that extends across the printable sheet width can be arranged parallel to the axis 4 of the transfer cylinder 3. In this case, the image data supplied to the write head 6 must be changed or influenced in accordance with the inclination of the transfer cylinder 3. In the case of a write head 6 which contains a series of image-forming elements arranged next to one another at a pixel spacing, z. B. the data belonging to imaging elements that are along the circumference of the transfer cylinder 3 closer to the sheet 2, are accordingly delayed to the write head 6. There are also a number of other ways to take into account the inclination of the transfer cylinder 3, z. B. by angular transformation of an electronically stored template, "oblique" scanning and reading a template, etc.

If it cannot be neglected due to a relatively small angle α, the change in the pixel spacing or the printing width due to the inclination must also be taken into account.

Just like the transfer cylinder 3, other transfer cylinders can also be tilted for additional colors.

The write heads can also be arranged parallel to the leading edge 8 of the sheet, as shown in FIG. 2 on a further transfer cylinder 9, for example by a write head 10 shown in broken lines. In this case, there is no change in the pixel spacing or the printing width, and the image data can be fed to the write head 10 line by line without change, so that the information is processed in exactly the same way as with a transfer cylinder lying straight. If the angle .alpha. Is small and the write head 10 is of a type in which it is not necessary to maintain a very precise distance from the transfer cylinder 9, the write head 10 need not be set up specifically for this arrangement. Otherwise, write head designs are also conceivable that "nestle" to a certain extent on the transfer cylinder 9.

In both cases mentioned, the inking unit 7 can be arranged in a conventional manner, i. H. parallel to the axis of the transfer cylinder 3 or 9.

Instead of printing units with only one transfer cylinder 3 or 9, as shown in FIGS. 1 and 2, printing units with a plurality of transfer cylinders connected in series can also be used, for example a cylinder, on the circumference of which the print head and the inking unit are arranged, and one thereon rolling further cylinder, which in turn rolls on the sheets or the conveyor belt.

In addition, instead of the transfer cylinders 3 or 9, a belt rotating around two or more cylinders can be used are used, on the surface of which the printed images are generated or transferred by an upstream cylinder or belt and then transferred from this surface to the sheets. In this case, the cylinder on which the printing ink is transferred from the belt to the sheets is arranged above the conveyor belt in the manner shown in FIG. 2. There is then the advantageous possibility of arranging the print head on a rectilinear section of the tape in such a way that the latent images are produced without any adaptation of the image data and subsequently true-to-the-original, undistorted images are printed on the sheets.

An alternative embodiment, which is not shown in detail, is to arrange the transfer cylinders at right angles to the direction of transport and to design the feeder of the printing press in such a way that the sheets are each conveyed in an inclined position on the conveyor belt, with their longitudinal edges at a small angle to the direction of transport run. In this case, too, there are the two possibilities explained in connection with FIG. 2, to arrange the write heads either parallel to the leading edge of the sheet or at right angles to the transport direction and to control them appropriately in each case.

REFERENCE SIGN LIST

1

Conveyor belt

2nd

bow

3rd

Transfer cylinder

4th

axis

5

Impression cylinder

6

Printhead

7

Inking unit

8th

Leading edge

9

Transfer cylinder

10th

Printhead

P

Direction of transport

a

distance

Claims (11)

Digital printing machine with an endless conveyor belt, which has an elongated section, on which substrates to be printed are transported successively through the printing machine in a transport direction, and with one or more printing units, each having a cylinder, which is the elongated section of the conveyor belt or the substrates arranged thereon are arranged opposite one another, the axis of which extends transversely to the direction of transport and which can be rotated synchronously with the movement of the conveyor belt in order to transfer printing ink to the substrates in a distribution corresponding to a desired printed image,
characterized by
that each of the cylinders (3; 9) is arranged so that the angle between its axis (4) and the transport direction (P) is not equal to 90 °. Digital printing machine according to claim 1,
characterized by
that the printing ink to be transferred is on a surface of the cylinder (3; 4) or on a belt running around the cylinder. Digital printing machine according to claim 2,
characterized by
that each printing unit has an elongated writing device (6; 10) which can be controlled by electrical signals and which extends transversely to the transport direction (P) along the The surface of the cylinder (3; 9) or of the band running around the cylinder is arranged and generates latent images on the surface which correspond to the electrical signals and has an inking unit (7) which develops the latent images with printing ink. Digital printing machine according to claim 3,
characterized by
that the writing device (10) is arranged at an angle of 90 ° to the transport direction (P). Digital printing machine according to claim 3,
characterized by
that the writing device (6) is arranged parallel to the axis of the cylinder (3). Digital printing machine according to one of the preceding claims,
characterized by
that it has a device for generating attractive forces between the conveyor belt (1) and the substrates (2) transported thereon. Digital printing machine according to claim 6,
characterized by
that the attraction forces are electrostatic forces. Method for transporting substrates to be printed in a printing press by means of an endless conveyor belt past one or more digital printing units,
characterized by
that the substrates (2) are applied to the conveyor belt (1) in such an orientation that the angle between the front edge (8) of the substrates and the Transport direction (P) of the conveyor belt is not 90 °. A method according to claim 8,
characterized by
that printing ink is generated on the digital printing units in a distribution corresponding to the desired print images and transferred to the substrates (2), and in that the print images are generated in an orientation which corresponds to the inclination of the substrates. Method according to claim 8 or 9,
characterized by
that attraction forces are generated between the conveyor belt (1) and the substrates (2) transported thereon. A method according to claim 10,
characterized by
that the attractive forces are generated electrostatically.

Images