EP0508273A1 - Printing apparatus for offset printing with a toner - Google Patents

Abstract

The invention relates to a printing apparatus for offset printing with a toner, having a forme cylinder (1), a transfer cylinder (4) and an impression cylinder (7). A web (6) of printing carrier is moved between the transfer cylinder (4) and the impression cylinder (7). On its outer surface, the forme cylinder (1) has a transfer medium (2) which is preferably a ferroelectric. The transfer medium (2) is covered by a toner deposit (3) which represents an image to be printed and is intended to be applied to the web (6) of printing carrier by the offset method. According to the invention, the toner deposit (3) is deposited onto the web (6) of printing carrier by electric influence. For this purpose, a negative direct voltage is applied to the impression cylinder (7), which leads to a voltage likewise being applied to the forme cylinder (1) and the transfer cylinder (4), such that the toner particles situated on the transfer medium (2) are attracted to the web (6) of printing carrier. <IMAGE>

Description

Printing devices for electrostatic printing processes are generally known. An electrostatically latent image attracts electrostatic marking particles, so-called toners. The toners can be so-called dry toners or so-called liquid toners. Electrostatic printing methods are particularly useful when only a fairly small number of prints are required, or when the image to be printed changes frequently, or when a part of the image to be printed has to be replaced at regular intervals.

Powdered dry toners have a number of disadvantages for use in a printing process. The main disadvantage is dust formation; very small toner particles very easily leave the so-called developer, and they settle on surfaces inside and outside the printing device. On the one hand, they cause faults within the printing device and, on the other hand, environmental problems outside the printing device. This disadvantage is particularly significant when printing devices are operated at high speed. This leads to high maintenance costs for the printing device; loss of dry toner also incurs costs.

However, printing processes using an electrostatic toner dissolved in a solvent also have a number of disadvantages, particularly when they are required to operate at high speeds. A major disadvantage is the so-called liquid separation. A certain amount of the solvent, ie the carrier of the toner, is deposited in the paper by a transfer cylinder that transfers the toner and is mechanically advanced. The solvent then evaporates, polluting the air and significantly increasing production costs. Another disadvantage of liquid toners is the tendency for color particles to deposit on non-colored or background surfaces, which leads to a general weakening of the color effect on the copy, which is usually referred to as background fog.

Improved transfer occurs when the print medium is a ferroelectric transfer medium with a more or less permanent latent image that has been embossed on or above its surface by means of internal polarization. The toner dissolved in the solvent is accumulated only on those areas of the transfer medium which are an image without the above-mentioned background fog, so that the solvent immission can be reduced considerably. Such a device is described in US Application No. 07 / 697,106, which is incorporated herein by reference.

The meniscus toning process described therein leads to a considerable reduction in solvent separation under carefully observed conditions, as are disclosed in the US application; however, it is not yet very user-friendly.

It is the object of the present invention to improve the above-mentioned device and to provide a printing device which enables the transfer of the toner in an uncomplicated manner.

According to the invention, this object is achieved in a printing device of the type mentioned at the outset in that the printing device for offset printing with a toner has a forme cylinder, a transfer cylinder and a printing cylinder, the forme cylinder being covered on its outer surface with a transfer medium, which in turn is one of them has a toner image depicting a printing image on its outer surface, the transfer cylinder being at a spatial distance from the forme cylinder, a printing material web being pressed against the transfer cylinder by the printing cylinder and running between the transfer cylinder and the printing cylinder, and a direct voltage being applied to the printing cylinder , which causes the transfer of the toner deposit from the forme cylinder via the transfer cylinder to the printing material web by influence.

The transmission medium is preferably a ferroelectric. The transfer cylinder preferably has an elastic surface made of a semiconducting or insulating material. The transfer cylinder can also be a metal cylinder.

The present invention relates to a printing device for the offset transfer of a toner, which covers the image surfaces of the surface of a transfer medium, which in turn is located on the outer surface of a forme cylinder. The printing process therefore consists essentially of the fact that a forme cylinder containing the transfer medium rotates, with the toner being deposited on the surface of the transfer medium, that an offset cylinder which does not directly touch the forme cylinder also rotates and at the same speed, whereby the transfer cylinder touches a printing material web which moves past the transfer cylinder essentially at a distance from the circumference of the transfer cylinder from the forme cylinder, the printing material web being held in contact with the transfer cylinder by a printing cylinder. The printing cylinder presses on that side of the printing material web which is not printed. At the same time, a direct voltage is applied to the printing cylinder, which causes the toner deposit to be transferred successively from the surface of the transfer medium to the forme cylinder to the surface of the transfer cylinder and finally from this to the surface of the printing material web.

In a preferred embodiment of the present invention, the transmission medium is designed as the outer surface of a forme cylinder, which is in spatial proximity to a clay dispenser, which is also in the form of a cylinder. The transfer medium does not touch the toner dispenser. The transfer cylinder is also adjacent to the transfer medium, without touching it, on the side of the transfer medium facing away from the toner dispenser. The outer surface of the transfer cylinder is preferably coated with an elastic layer made of a semiconducting or insulating material, for example made of a synthetic rubber or the like. The preferred distance between the transfer cylinder and the forme cylinder is of the order of 0.1 mm; however, it can also be chosen to be larger or smaller depending on the amount of liquid that the toner deposition on the surface of the transfer medium entails. The drier the toner deposit, the smaller the distance between the forme cylinder and the transfer cylinder can be selected.

The impression cylinder is positioned on the side of the transfer cylinder that is more or less opposite the position that the forme cylinder assumes. The printing material is moved in the form of a printing material web between the printing cylinder and the transfer cylinder and is pressed between them.

During operation, a DC voltage of approximately 2 kV is applied to the impression cylinder. Due to influenza, a voltage of the order of 1 kV is present on the surface of the transfer cylinder. This, in turn, is large enough to cause toner particles to transfer due to the influence from the surface of the forme cylinder to the surface of the transfer cylinder, even when there is no surface contact between the forme cylinder and the transfer cylinder. Liquid in which the toner particles are contained and which is carried along by the surface of the transfer medium on the forme cylinder is not transferred to the transfer cylinder, although a sufficient amount of liquid remains in the toner deposit to ensure the transfer. The higher voltage on the printing cylinder causes the electrostatic transfer of the toner deposit from the transfer cylinder to the surface of the substrate. Non-image areas remain completely dry on the surface of the printing material, while the amount of liquid contained in the toner deposit is no longer measurable.

Another advantage of this device is that it is no longer necessary to apply a voltage to transfer the toner particles to apply any cylinder which is in contact with the surface of the transfer medium containing the image to be printed on the forme cylinder. In this way, distortion of the latent image on the transfer medium is avoided.

Another advantageous embodiment of the invention is that the semiconducting or insulating layer covering the transfer cylinder is additionally charged by a corona discharge, while the toner deposit on the forme cylinder is charged in the opposite direction. This additional charge, in addition to the charge caused by the influence, facilitates the transfer of toner particles from the image areas on the surface of the transfer medium to the surface of the transfer cylinder.

Fig. 1

eine bevorzugte Ausführungsform einer Druckvorrichtung mit einem Formzylinder, einem Übertragungszylinder und einem Druckzylinder und

Fig. 2

eine weitere Ausbildung des Übertragungszylinders.

An exemplary embodiment of the invention is described below with reference to drawings. Show it:

Fig. 1

a preferred embodiment of a printing device with a forme cylinder, a transfer cylinder and a printing cylinder and

Fig. 2

a further training of the transfer cylinder.

The outer surface of a forme cylinder 1 (FIG. 1) is covered by a transmission medium 2. The forme cylinder 1 rotates in the direction indicated by the arrow. The transfer medium 2 carries a toner deposit 3 representing an image to be printed on its outer surface. A transfer cylinder 4, which is covered on its outer surface by a semiconducting or insulating layer 5, is mounted at a certain distance from the forme cylinder 1 and rotates at the same angular velocity as this in the direction indicated by the arrow. A printing material web 6 touches the transfer cylinder 4 and is pressed against it by the pressure exerted by a printing cylinder 7. The pressure cylinder 7 preferably has an elastic, semiconducting or insulating layer 8 on its surface. To the Printing cylinder 7 is at a DC voltage, which generates a lower voltage due to influence on the surface of the transfer cylinder 4. The rotation of the printing cylinder 7 of the transfer cylinder 4 and the forme cylinder 1, while a DC voltage is present thereon due to the influence, causes a transfer of the toner deposit 3 to the transfer cylinder 4 across an air gap between the forme cylinder 1 and the transfer cylinder 4 and leads to toner deposition 9 on the outer surface of the transfer cylinder 4. By further electrostatic transfer of the toner deposit 9 corresponding to the image to be printed onto the printing material web 6, the final image is generated thereon by a toner deposit 10.

In another embodiment of the printing device, a transfer cylinder 11 (FIG. 2) is provided instead of the transfer cylinder 4. It consists of a cylindrical insulating support 12 which is covered by a metallic hollow cylinder 14. This is connected to the first potential via a resistor 13. The transfer cylinder 11 rotates in the direction indicated by the arrow.

In preferred embodiments of this printing device, the transfer medium 2 is a ferroelectric from which the toner is transferred to the printing material web 6. This is done according to methods known per se for the electrostatic transfer of a toner onto a printing material, in particular paper.

According to the embodiment of the printing device shown in FIG. 1, the layer 5 of the transfer cylinder 4 consists of a more or less elastic semiconductor material, such as a polyurethane coating. This is for example 3 mm thick and characterized by a specific surface resistance of 1.7 x 10¹¹ Ω, as well as by a volume resistivity of 4.7 x 10¹⁰ Ω x cm and a Duro hardness of 49 Shore A. The printing speed is, for example 0.5 m / s, while the distance between the forme cylinder 1 and the transfer cylinder 4th Is 0.1 mm. A negative voltage of 2 kV is preferably applied to the pressure cylinder 7. A negative voltage of 1 kV is then present at layer 5.

If the printing speed is increased to a speed of 1 m / s, the negative voltage applied to the printing cylinder 7 is advantageously increased to 4 kV, so that a negative voltage of 1.5 kV is applied to the surface of the layer 5 of the transfer cylinder 4.

Even at a distance of only 0.05 mm between the forme cylinder 1 and the transfer cylinder 4, a satisfactory print quality can still be achieved at a printing speed of 1 m / s.

Instead of the above-mentioned layer 5, a polyurethane layer with a specific surface resistance of 2 x 10¹² Ω and with a specific volume resistance of 8 x 10¹⁰Ω x cm and a duro hardness of 80 Shore A can also be applied to the transfer cylinder 4. At a transfer speed of 0.5 m / s and a distance of 0.1 mm between the forme cylinder 1 and the transfer cylinder 4 and when a negative voltage of 2 kV is applied to the printing cylinder 7, a negative voltage of 1.25 kV is applied to the Transfer cylinder 4 measured. If the distance between the forme cylinder 1 and the transfer cylinder 4 is now reduced to 0.15 mm, a negative voltage of 1.1 kV can be measured on the transfer cylinder 4. In the method described so far to operate the printing device, a corona electrode can additionally be attached at a distance of 15 mm from the transfer cylinder 4. This has a diameter of 50 µm, for example, and is charged with a voltage of 4 kV; in contrast, the toner deposit 3 on the forme cylinder 1 has an opposite charge. In this way, an even easier transfer of the toner from the forme cylinder 1 via the transfer cylinder 4 to the printing material web 6 can be effected.

The surface topography of the transfer cylinder 4 has an influence on the quality of the print image that appears on the printing material web 6. The surface of the transfer cylinder 4 should preferably have a height fluctuation of less than 2 μm, although an average square error of 10 μm can also be tolerated. The higher the duro hardness of the polyurethane in layer 5, for example 75 to 85 Shore A, the smoother the surface. In the ideal case, the specific surface resistance of layer 5 is approximately 10 11 Ω, the specific volume resistance is in the order of 10 10 to 10 11 Ω x cm.

In the case of the transfer cylinder 11, the resistance 13, via which the metallic hollow cylinder 14 is grounded, is 1 G Ω. If the transfer cylinder 11 is used instead of the transfer cylinder 4 in the printing device, as shown in FIG. 1, the printing speed is advantageously 0.5 m / s with a distance of 0.1 mm between the forme cylinder 1 and the transfer cylinder 11. A sufficient good print quality is achieved when a negative voltage of 1.5 kV is applied to the printing cylinder 7. This causes a negative voltage of 1.0 kV on the transfer cylinder 11. When the printing speed is 1 m / s, a negative voltage of 1.1 kV is measured on the transfer cylinder 11.

At a printing speed of 0.5 m / s and a distance of 0.15 mm between the forme cylinder 1 and the transfer cylinder 11, a negative voltage of 1.15 kV is measured on the transfer cylinder 11.

It is also possible to apply a direct voltage directly to the transfer cylinder 11 without a direct voltage being applied to the printing cylinder 7. At higher printing speeds, higher voltages are also required.

Claims (12)

Printing device for offset printing with a toner, which has a forme cylinder (1), a transfer cylinder (4) and an impression cylinder (7), the forme cylinder (1) being covered on its outer surface with a transfer medium (2), which in turn is the one Has image deposit to be printed on its outer surface, the transfer cylinder (4) being at a spatial distance from the forme cylinder (1), a printing material web (6) through the print cylinder (7) against the transfer cylinder (4 ) is pressed and runs between the transfer cylinder (4) and the impression cylinder (7) and a direct voltage is applied to the impression cylinder (7), which influences the transfer of the toner deposit (3) from the forme cylinder (1) via the transfer cylinder (4 ) on the substrate (6). Printing device according to claim 1, characterized in that the transmission medium (2) is a ferroelectric. Printing device according to claim 1 or 2, characterized in that the forme cylinder (1) and the printing cylinder (7) are located on opposite sides of the transfer cylinder (4). Printing device according to one of the preceding claims, characterized in that the spatial distance between the forme cylinder (1) and the transfer cylinder (4) is between 0.05 and 0.15 mm. Printing device according to one of the preceding claims, characterized in that a negative direct voltage between 1 kV and 4 kV is present on the printing cylinder (7). Printing device according to one of the preceding claims, characterized in that the transfer cylinder (4) has a layer (5) made of a semiconducting or insulating material on its outer surface. Printing device according to claim 6, characterized in that the layer (5) contains polyurethane. Printing device according to claim 6 or 7, characterized in that the layer (5) has a specific surface resistance in the range between 1.7 x 10¹¹Ω and 2 x 10¹²Ω and a specific volume resistance in the range between 1 x 10¹⁰ Ω x cm and 8 x 10¹⁰ Ω x cm. Printing device according to one of claims 6 to 8, characterized in that the layer (5) has a duro hardness in the range between 49 and 85 Shore A. Printing device according to one of the preceding claims, characterized in that the transfer cylinder (4) is additionally charged by the discharge of a corona electrode which is located in the vicinity of the transfer cylinder (4). Printing device according to one of the claims, characterized in that the transfer cylinder (11) essentially consists of an inner, insulating support (12) which is covered on its outer surface by a conductive, metallic hollow cylinder (14). Printing device according to claim 11, characterized in that the hollow cylinder (14) is connected to the earth potential via a resistor (13).

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