A method is provided for printing on hollow bodies in which the hollow bodies are printed on in a decorator having a rotating segment wheel. Printing ink provided by multiple different plate cylinders and inking units are each collected on printing blankets arranged one after another on the circumference of the segment wheel. The plate cylinders and inking units involved in the printing are arranged and set in such a way that, when printing on the hollow body, an iris print is, or at least can be implemented.

The present invention is directed to a method of inkjet printing an image on a glass container comprising the steps of: a) manufacturing a glass container having a CEC layer; b) removing at least part of the CEC layer to a level wherein the remaining CEC layer has a thickness of less than 20 nm by washing the CEC from the glass container with an aqueous solution containing non-ionic surfactant, rinsing with water and blowing the water from the container by means of a pressurized air stream, c) inkjet printing an image on the glass container.

A method for printing on at least partially transparent containers, wherein, in a first printing step, a first printing image is printed onto the container by the application of at least one printing ink, and wherein, in a second printing step, a second printing image is printed onto the container by the application of at least one printing ink, wherein the printing images are printed at least partially covering one another, and specifically in such a way that ink layers are applied in a temporal offset sequence onto the container, wherein a first ink layer is allocated to the first printing image and a second ink layer is allocated to the second printing image, and that between the first and second printing image a reflection layer is at least partially provided, by means of which the printing images are at least partially optically separated from one another.

A method of collecting a metrology data set of a contoured surface with a metrology system and executing an automatic control plan for printing on a contoured surface is disclosed. The method includes attaching a work piece to a work piece frame and scanning a contoured surface of the work piece to obtain a metrology data set, a three-dimensional point cloud model is generated based on the metrology data set. Additionally, the method includes defining a spatial reference model of the work piece frame, and defining a print path for a print head assembly of a surface treatment assembly. Furthermore, the method includes discretizing the contoured surface into a plurality of regions and the print path is further defined into at least one independent regional print path for each region of the plurality of regions. Moreover, a computer software simulation verifies a control plan for printing on the contoured surface.

A printing apparatus (500) is provided with a moving unit (550) used to convey a can body (10). In addition, the printing apparatus (500) is provided with a first linear unit (610) in a linear shape which the moving unit (550) travels to move in one direction. Moreover, the printing apparatus (500) is provided with a second linear unit (620) which the moving unit (550) travels to move in a direction opposite to the one direction, the second linear unit (620) being arranged in parallel with the first linear unit (610) and formed linearly. Further, the printing apparatus (500) is provided with a printing unit (520) that performs printing on the can body (10) held by the moving unit (550). By these units, the miniaturization of a printing apparatus and a can body manufacturing system is attained.

A system for printing on a multi-dimensional object includes a plurality of print heads, a mounting structure configured to receive an integrated object packaging and holder for an object and to movably mount on a support member, an actuator configured to move the mounting structure along the support member, and a processing device. The system also includes a non-transitory, computer-readable memory containing programming instructions that are configured to cause the processing device to control a movement of the mounting structure relative to the plurality of print heads, and operate the plurality of print heads to eject marking material onto an object mounted on the mounting structure.

A method and a device for printing onto containers, in particular bottles, made of glass are described. Containers that have been heated and coated by hot end coating are received from a transport section and transferred to a printing machine. The containers are cooled to a printing temperature in the region of the transport section and/or of the printing machine are provided with a printed image in the printing maching by direct printing. This allows for high-quality direct printing with sufficient resistance to mechanical stresses without cold end coating of the containers prior to the direct printing and/or without the resulting effort of improving the adhesive action of the print or of removing the cold end coating in the print region at least in part.

A fabric material includes a plurality of synthetic yarns, the yarns including staple fibers having a range of denier values. The polyester staple fibers have deniers ranging from about 0.5 denier per filament to about 2.0 denier per filament. Additionally, more than 50% of the staple fibers present in the fabric possess a length of greater than 1 inch.

Process for selectively and locally treating the surface of a part, whereina part having a surface to be treated is provided, said surface being defined by a direction P and a direction Q; three-dimensional profilometric data are acquired from the surface to be treated, in order to obtain a set F1 of three-dimensional data on the surface to be treated, said set F1 associating a height with each point in the plane PQ; this set F1 of digital data is processed digitally with a view to subtracting said curves, to obtain a set F2 of reprocessed three-dimensional data; this set F2 of data is processed digitally, to obtain a set F3 of binary data on the surface to be treated, said digital processing attributing, to each point on the surface, a first binary value or a second binary value, depending on at least one criterion related to the height of the point on the surface; the surface is selectively and locally treated using said set F3 of binary data, said surface treatment being performed only at points on the surface the binary datum of which has said first or said second binary value.

A drying apparatus includes a drying chamber configured to be connected to a decompression section, and a moving section configured to move a target object in the interior of the drying chamber. With this structure, the pressure in the interior of the drying chamber can be reduced and the target object can be dried in the interior of the drying chamber, and thereby the drying efficiency of the target object can be increased.