In a paper feeding apparatus, paper feed rolls in paper feed roll rows for feeding the lowermost one of cardboard sheets placed in a stacked manner on a paper feeding table intermittently one by one toward the printing device are coupled via shafts to separate servomotors. The servomotors are controlled so to be accelerated synchronously and rapidly from a stopped state to a high rotational speed during one cycle of feeding through contact with the lowermost cardboard sheet, while controlled so to be decelerated from the high rotational speed to be stopped rapidly and respectively when determined not to be in contact with the lowermost cardboard sheet.

A front end conveyor include a lower deck having a plurality of lower sheet supports, an upstream upper deck having an upstream end at the upstream end of the front end conveyor, a downstream end and a plurality of first upper sheet guides and a downstream upper deck having an upstream end, a downstream end at the downstream end of the front end conveyor, and a plurality of second upper sheet guides. The lower sheet supports and the upper sheet guides define a sheet transport path for moving sheets of material though the conveyor. The downstream end of the upstream upper deck and the upstream end of the downstream upper deck are independently pivotably mounted to the frame such that the upstream end of the upstream upper deck and the downstream end of the downstream upper deck shiftable toward and away from the lower deck.

Method for applying glue on tubular cores for the production of logs of paper material comprising the step of supplying in sequence more tubular cores (1) along a predetermined advancing direction (A) and the step of applying on each of said cores (1) a predetermined amount of glue, and the glue is applied on the tubular cores (1) from the above. While advancing along said direction (A) and without interrupting their run, the tubular cores (1) intercept for a predetermined time the glue (EG) released by a predetermined number of nozzles (114); and during said time interval the glue (EG) is both on the nozzles (114) and the tubular cores (1) given the absence of any element interposed between the nozzles and the tubular cores.

A method for producing a cardboard strip for packaging from a first plurality of cardboard sheets for packaging which are cyclically united to one another. The method includes providing a first plurality of cardboard sheets each having a first perimeter portion extending along a first flank of the cardboard sheet and a second perimeter portion extending along the second flank of the cardboard sheet and further includes reducing the thickness of first perimeter portion and the second perimeter portion of a given cardboard sheet. The given cardboard sheet and another cardboard sheet are approximated to one another, so that the second perimeter portion of the given cardboard sheet and the first perimeter portion of the other cardboard sheet, of reduced thickness from a preceding cycle, are mutually superposed. The second perimeter portion of the given cardboard sheet and the first perimeter portion of the other cardboard sheet are affixed to one another.

Disclosed is a supply device for supplying cutouts to a machine from an inventory configured in several adjacent stacks of cutouts; the device includes a manipulator to transfer, by batch, the cutouts from the inventory to the machine. This device further includes a pressing unit to compress at least one stack that is adjacent to the one from which the manipulator removes cutouts. Also disclosed is a corresponding method.

A sheet stacking system includes a main conveyor configured to carry sheets in a downstream direction, an accumulator section downstream of the main conveyor configured to receive the sheets from the main conveyor, at least one tamping plate in the accumulator section, and at least one linear motor connected to the at least one tamping plate. The at least one linear motor is configured to move the at least one tamping plate back and forth in a direction perpendicular to the downstream direction to tamp a stack of the sheets in the accumulator section.

A sheet feeder especially designed for use in the food and pharmaceutical industries is constructed in a hygienic manner and with suitable materials to permit rapid and effective cleaning and sanitizing thereof. Flexible, liquid impermeable bellows are mounted to the feeder housings in surrounding relation to the apertures through which the machine's several rotary shafts enter the housings. The bellows support bearing isolators that not only seal the housings from fluid entry, but because the bellows can flex, they also permit shaft spacings to be adjusted to adapt the machine to sheets of differing thicknesses and to set infeed belt tension. The sheet feeder's product input hopper and its discharge conveyor are designed to be easily detachable for cleaning in a dipping mode.

A register (20; 60) for a processing machine (1) for processing plate-like elements (10) includes a gripping element (21; 22) for placing the plate-like elements (10) in a gripper bar (31) of a conveyor (30) of a processing machine (1) conveying the plate-like elements (10) in a longitudinal direction, an actuator module (201, 202) to drive the gripping element (21; 22), at least one front correction sensor module (7) configured to measure the front position of register marks (12a) printed on a front section of the plate-like element (10) grasped by the gripping element (21; 22). The register (20; 60) includes at least one front pre-correction sensor module (80), placed upstream of the front correction sensor module (7) in the longitudinal direction, the front pre-correction sensor module (80) is configured: to detect the passage of a front transversel edge of the plate-like element (10) in at least two longitudinally spaced lateral axis of detection (P1, P2), one located in front of the other, and to provide measurements to a computation and control unit (40) of the processing machine (1) that is configured: to control the actuator module (201, 202) in order to move the gripping element (21; 22) toward the gripper bar (31) and to activate the gripping element (21; 22) in order to grasp a plate-like element (10). Also a processing machine for processing plate-like elements includes the register. A method for placing plate-like elements within a processing machine is disclosed.

A sheet stacker including a sheet conveyor arrangement and a stacking bay, wherein sheets delivered by the sheet conveyor arrangement are formed into stacks; the stacking bay including a stacker platform. The stacker platform is provided with a vertical lifting and lowering movement with respect to a stationary supporting structure and is controlled to move downwards while a stack of sheets is formed thereon. The stacker platform supports a stack conveyor configured and controlled to perform at least an evacuation motion, to remove a completed stack from the stacking bay. The evacuation motion of the stack conveyor is oriented such that a completed stack is moved from the stacking bay onto an evacuation conveyor arranged under the sheet conveyor arrangement.

A quality control station (2) for a sheet element processing machine, the station having at least one camera (6) arranged for capturing images of sheet elements (4) transported through the quality control station (2), and further having a camera calibration system (10). The camera calibration system (10) having a target holder (12) for holding an optical target (14), and a drive (15) for the target holder (12). The drive (15) is adapted for displacing the target holder (12) between a rest position, in which it is outside of the viewing area (7) of the camera (6), and a calibration position in which it is arranged in the viewing area (7) of the camera (6).