An apparatus for manipulating a printable medium for the use in a printer is described. The apparatus comprises a drag device, a feed device and a lock device. The drag device conveys the printable medium to a printing area. The feed device feeds the printable medium to the drag device. The lock device is disposed between the feed device and the drag device. The lock device temporarily fixes a first portion of the printable medium so as to cause a second portion of the printable medium being in contact with the drag device to slip along the drag device.

A handle applicator includes controller that receives signals concerning marks on an endless band. The controller controls a contact body to be between a release position, in which a handle applicator is freely driven and a drawing position, in which the contact body contacts the endless band of material prior to its being cut to form the handle. The contact body moves along a continuum of positions between the release position and the drawing position based on actual position data indicative of actual positions of position markings on the handle.

An image forming apparatus includes an accommodating part configured to accommodate a sheet-like medium wound in a roll shape, an apparatus main body provided with a conveyer and an image forming engine, an electrically driven cutter, a cover configured to take a closed position for forming an exposable portion of a conveying path downstream in the conveying direction of the cutter and an open position to expose the exposable portion of the conveying path to the outside, a detector configured to detect a conveyance jam of the medium at a position downstream in the conveying direction of the exposable portion of the conveying path, a notifier configured to make notification to a user, and a controller configured to cause the notifier to prompt the user to cut off the medium at an arbitrary position in the exposable portion of the conveying path when the detector detects the conveyance jam.

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 including support columns (711) for supporting the delivery station (70), the transfer station (80) and the elevation station (82). The delivery station has a delivery table (71) 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 method for winding a material sheet, in particular a plastic film, by a winding device, wherein the material sheet is guided from at least one first roller to at least one second roller in a conveying direction. At least one cutting device is arranged between the first roller and the second roller to cut the material sheet into at least two partial sheets. The partial sheets are each wound up into a bobbin in the conveying direction behind the second roller. The at least one first roller and the at least one second roller are each driven by a drive so that the tensile stress in the material sheet or in the partial sheets changes periodically over time in the conveying direction of the material sheet.

A cutting device includes a fixed blade and a movable blade that slides with respect to the fixed blade during cutting, the movable blade having a first end that engages with the fixed blade at cutting start and a second end that engages with the fixed blade at cutting end, an urging member connected to the movable blade to urge the movable blade towards the fixed blade and a rotation of the movable blade in a first rotational direction, and a support for the movable blade having a shaft that rotates as the movable blade moves, the shaft having a center portion and first and second ends rotatably connected to the movable blade, wherein points of connection of the first and second ends are at locations that urge a rotation of the movable blade in a second rotational direction opposite the first rotational direction.

A plurality of marks (11) equidistantly provided on both side edge parts (1a) of a long medium (1), a plurality of first indicator holes (12) equidistantly given on at least one of the side edge parts (1a), and a plurality of second indicator holes (13) given on at least one of the side edge parts (1a) on a straight line different from a row of the first indicator holes (12) at spacings shorter than spacings of the first indicator holes (12) are provided, and the second indicator holes (13) are each provided to a side of a trailing-end mark (11b), and each gradually comes closer to a leading-end mark (11a) as the long medium (1) runs toward a trailing end.

A system and method is provided that allows for the non-interrupted coating of a pulled substrate with coating materials, even while a coated portion of the substrate is held stationary for cutting. The present invention eliminates waste and improves efficiency and yield, and is particularly applicable to laboratory drawdown coaters.

An apparatus and method for producing self-adhesive labels, in particular in a self-service area, for example of a drug store, is provided. The apparatus comprises a dye-sublimation thermal printer, as a printing means for printing a printing pattern onto an adhesive film, and a cutting apparatus for cutting the adhesive film along a cutting pattern, the adhesive film being moved automatically from the printing means to the cutting apparatus. Initially, only a first moving unit of the printing means moves the adhesive film at a first speed to a second moving unit of the cutting apparatus, after which both moving units move the printed adhesive film further in the forward direction.

In a turn-up method for a reel-up for reeling of fiber webs, a web travelling in direction (S) is cut by two water jet nozzles moving in a transverse direction in relation to the web travelling direction (S). Two cuts (C1, C2) are formed by two water jet nozzles starting from the edges of the web (W) and moving to the web center where the cuts (C1, C2) cross or meet forming a V-shaped tail end (V1). After the cuts the movement of the water jet nozzles is stopped and after the return movement of the water jet nozzles, cutting is started again from the center toward the edges so that the web W is cut by two cuts (C3, C4) and a substantially V-shaped beginning end (V2) to the web W is formed and between the cuts (C1, C2) for the tail end (V1) and the cuts (C3, C4) for the beginning end (V2) there is formed one web reject part (R) with two substantially V-shaped cuts. A turn-up device for a reel-up for reeling of fiber webs has two water jet nozzles, in which the cutting by the water jet nozzles (10,12) may be stopped between cutting of a tail end (V1) and cutting of a beginning end (V2) for a selected time for forming only, wherein there is one reject part (R) in the turn-up and the cross-direction travel distance (L1, L2) of each nozzle is substantially shorter than the width (L) of the web (W).