A device for processing a material web (3) that includes means (2) for conveying the material web in a longitudinal direction (L), wherein both an applied, in particular repeated printed image (9) and a control line (10, 11) extending in the longitudinal direction are configured on the material web (3). The control line (10, 11) has a defined position transverse to the material web (3), and the control line (10, 11) is scanned by means of a sensor (15, 16) in a material web (3) processing step. The control line (3) has a digital code structure in its longitudinal direction (L) that encodes a data set of at least four bits, in particular at least two bytes, of information content.

A method for controlling a drive of a machine having at least one first roll element, which rolls with a surface on a counter surface at least in subintervals of a revolution cycle with the action of a contact force under elastic deformation, that includes a speed correction method, which automatically compensates for deformation-related deviations of the peripheral velocity of the first roll element by way of an adaptation of the setpoint value for the velocity of the first roll element, and a retrospective method, which automatically compensates for deviations of the speed consistency of the first roll element within a revolution cycle by applying a correction signal determined from the curve of a control variable, in particular an actual velocity or actual position of the first roll element, in a preceding revolution cycle or in multiple preceding revolution cycles, are applied in combination.

A method for controlling a drive of a machine having at least one first roll element, which rolls with a surface on a counter surface at least in subintervals of a revolution cycle with the action of a contact force under elastic deformation, that includes a speed correction method, which automatically compensates for deformation-related deviations of the peripheral velocity of the first roll element by way of an adaptation of the setpoint value for the velocity of the first roll element, and a retrospective method, which automatically compensates for deviations of the speed consistency of the first roll element within a revolution cycle by applying a correction signal determined from the curve of a control variable, in particular an actual velocity or actual position of the first roll element, in a preceding revolution cycle or in multiple preceding revolution cycles, are applied in combination.

A production system such as an inkjet printer system includes a plurality of communication distribution devices connected in a daisy chain arrangement. A plurality of secondary devices, such as printhead electronics boards for inkjet printheads, is connected to each of the communication distribution devices. A first communication distribution device which is connected to a system controller assigns a communication address to itself from a first set of communication address and assigns communication addresses to its connected secondary devices from a second set of communication addresses. It then communicates information to the next communication distribution device specifying the next available communication addresses. This process continues down the chain of communication distribution devices. The assigned communication addresses are then transmitted to the system controller. The assigned communication addresses enable the system controller to determine the relative physical locations of the communication distribution devices and secondary devices.

A processing machine has a plurality of processing stations for the processing of articles. A plurality of the processing stations are each configured in the form of a printing unit. The processing stations, which are provided for processing the articles, are each arranged at different positions. At least one handling device is provided for transporting at least one of the articles which is to be processed. The handling device has a drive which is controlled by a control device and, which handling device, by the use of this drive, can be displaced from one processing station, in which the respective article is processed, to at least one next processing station for processing this article. The processing machine has a learning phase and a production phase. Provision is made for a memory device, which is connected to the control device, to store, in the learning phase, position-related values of the relevant handling system, those position-related values being determined by the use of a calibration travel executed by the relevant handling system for a certain processing procedure. Following the changeover of the processing machine from its learning phase to its production phase, the drive of the relevant handling device is controlled by the control device such that the relevant handling device assumes, one after the other, the positions previously stored for it in the memory device in the learning phase.

A processing machine has a plurality of processing stations for the processing of articles. A plurality of the processing stations are each configured in the form of a printing unit. The processing stations, which are provided for processing the articles, are each arranged at different positions. At least one handling device is provided for transporting at least one of the articles which is to be processed. The handling device has a drive which is controlled by a control device and, which handling device, by the use of this drive, can be displaced from one processing station, in which the respective article is processed, to at least one next processing station for processing this article. The processing machine has a learning phase and a production phase. Provision is made for a memory device, which is connected to the control device, to store, in the learning phase, position-related values of the relevant handling system, those position-related values being determined by the use of a calibration travel executed by the relevant handling system for a certain processing procedure. Following the changeover of the processing machine from its learning phase to its production phase, the drive of the relevant handling device is controlled by the control device such that the relevant handling device assumes, one after the other, the positions previously stored for it in the memory device in the learning phase.

An exchanging unit for use in a printing device including a printing section to execute a printing process of printing a viscous fluid on a processing target object using a screen mask, and includes a receiving section configured to receive an accommodation rack having multiple shelf sections each configured to accommodate a frame that is capable of supporting an exchangeable member for use in the printing device, a lifting and lowering section configure to lift and lower the accommodation rack between an exchange position where to exchange the exchangeable member and a liftable position situated further downwards than the exchange position, and a moving section configured to move the accommodation rack between the liftable position where the accommodation rack can be lifted up by the lifting and lowering section and an accommodation position where the accommodation rack enters an interior of a housing of the printing device.

A replacement unit for a printing device includes a moving section to receive an accommodation rack having multiple shelf sections for accommodating a printing-related member for use in the printing device and to move the accommodation rack between a replacement position where to replace the printing-related member and a standby position which lies further downwards than the replacement position and a region detection section configured to detect an object existing in a predetermined first detection region lying around a circumference of the replacement unit when the accommodation rack exists outside a predetermined movement region which lies between the standby position and the replacement position, while being configured to detect an object existing in a second detection region which is different from the first detection region when the accommodation rack exists inside the movement region.

Disclosed are methods that couple effective nesting of fabric, as part of a textile cutting process, in which designs and/or graphic elements are directly printed on the nested elements, instead of on the entire textile sheet. Embodiments of the invention can address issues of waste and redundant printing, such as by starting with a blank textile roll, and printing only in the geometry areas of the patterns. Embodiments of the invention can increase fabric yield, because there are no constraints between the pattern geometries and the textile sheet print.

Disclosed are methods that couple effective nesting of fabric, as part of a textile cutting process, in which designs and/or graphic elements are directly printed on the nested elements, instead of on the entire textile sheet. Embodiments of the invention can address issues of waste and redundant printing, such as by starting with a blank textile roll, and printing only in the geometry areas of the patterns. Embodiments of the invention can increase fabric yield, because there are no constraints between the pattern geometries and the textile sheet print.