The present invention relates to a method of stacking individual sheets and a stacking machine for handling individual sheets, the stacking machine comprising a frame assembly (13) including support columns (711, 811) for supporting the delivery station (70), the transfer station (80) and the elevation station (82). The delivery station has a delivery table and the transfer station including a handling arm (85) is movable from a first position above the delivery table to a second position above the elevation station. The handling arm includes a holding member (86) for contacting the sheets individually and transferring the sheets individually from the delivery table to the elevation station and releasing the sheets individually at the elevation station. The elevation station has a platform for collecting the individual sheets and the platform is moved vertically from a first level to a second level for allowing the sheets to be stacked on top of the one another.

A separation unit is provided for separating a web material having a web width along preformed lines of weakness. The separation unit includes at least a first shaft extending along a first longitudinal axis and at least a second shaft extending along a second longitudinal axis in parallel with the first shaft. The separation unit also includes at least one first protrusion element extending perpendicularly from the first shaft and being arranged to be rotatable about the first longitudinal axis, and at least one second protrusion element extending perpendicularly from the second shaft and being arranged to be rotatable about the second longitudinal axis. The separation unit further includes at least one contact element being arranged in biased abutment against at least one of the first and second protrusion elements in a direction perpendicular to the first or second longitudinal axis.

A method and a vacuum-coating system (10) for coating a strip-shaped material (11), in particular made of metal, are disclosed. Thereby, the strip-shaped material (11) is moved over a conveying section (12) in a transport direction (T) and vacuum-coated within a coating chamber (14) in which a vacuum is applied. When viewed in the transport direction (T) of the strip-shaped material (11), at least one trimming shear (38) is arranged upstream of the coating chamber (14), with which the strip-shaped material (11) is trimmed at at least one strip edge, preferably at both strip edges, in order to produce a constant width for the strip-shaped material (11) over its longitudinal extension.

A stretch wrap applicator includes one or more cutting members arranged to engage the stretch wrap to cut it into strips as it is dispensed from the roll. The strips are then gathered and stretched into strings that are wrapped around the object. A roller is biased toward the stretch wrap roll to ensure an even flow of stretch film from the roll and more consistent tension on the film dispensed from the roll. The roller includes a groove. A cutting member is disposed to rest in the groove such that stretch film passes over and around the roller as it is dispensed from the roll and then engages the cutting member in the grove before the stretch film separates from the roller.

The present invention relates to a device (1) for automatically cutting a material web (2) with a longitudinal cutting device (60) using a material web (2) in a longitudinal direction (L) separable in at least a partial web (3) and/or at least a remaining web (4), a discharging device (10) for automatically discharging the produced remaining web (4), a transverse cutting device (70) downstream of a longitudinal cutting device (60) for cutting the remaining web (4) transversely to the longitudinal direction (L).

The invention relates to a method for cutting substrates with printed images in an automatic cutting device. The longitudinal cutting marks (LM) are provided with a discontinuity (N) arranged upstream of each transverse cutting mark (TM) with respect to a feeding direction (F) of a substrate (S) and spaced therefrom by a predefined known measure (d). The automatic cutting device has a first optical unit configured to detect the transverse cutting marks (TM) and a second optical unit configured to detect the discontinuities (N) in the longitudinal cutting mark (LM). Since the velocity of the substrate is known, the control system activates the first optical unit when the transverse cutting mark (TM) actually passed underneath it.

The present invention relates to a device (1) for automatically cutting a material web (2) with a longitudinal cutting device (60) using a material web (2) in a longitudinal direction (L) separable in at least a partial web (3) and/or at least a remaining web (4), a discharging device (10) for automatically discharging the produced remaining web (4), a transverse cutting device (70) downstream of a longitudinal cutting device (60) for cutting the remaining web (4) transversely to the longitudinal direction (L).

A flexible material transport system for fabric and a system for continuous fabric workflow is presented. The flexible material transport system comprises a printing machine, a material web transporter connected to the printing machine, a material accumulator connected to the material web transporter, and a cutting machine connected to the material accumulator, wherein the material accumulator is configured to feed printed fabric from the material web transporter into the cutting machine, and wherein the material web transporter comprises a plurality of rollers configured to control movement of the fabric from the printing machine to the material accumulator and onto the cutting machine. The system can also comprise a heater and/or an image scanner. The system for continuous fabric workflow comprises two or more of the flexible material transport systems. Information regarding the fabric can be tracked for local or centralized reporting and additional data processing.

A garment production system, comprising a virtual development environment configured to receive and store in a database thereof body information relating to a user, establish measurements for the user based on the body information, display, on a display device connected to the virtual development environment, a virtual representation of the user using the established measurements, customize one or more garments for the user based on the established measurements, display, on the display device, a virtual representation of the one or more customized garments on the virtual representation of the user, receive and store in the database personalization information from the user regarding the one or more customized garments, and alter the one or more customized garments and the virtual representation thereof based on the received personalization information for manufacture thereof.

A ceramic sheet includes a first surface, a second surface opposite the first surface, and a pair of parallel edges extending therebetween. A thickness of the ceramic sheet is defined between the first and second surfaces, a width of the ceramic sheet is defined between the pair of parallel edges, and a length of the ceramic sheet is defined as a dimension orthogonal to both the thickness and the width. The thickness is less than or equal to 100 m, the length is greater than or equal to 10 m, and the width is less than or equal to 12 mm. The ceramic sheet has a grain size of less than or equal to 0.2 m and a porosity of less than or equal to 5%.