An image formation device includes: a registration roller pair configured to shift sheet in a second direction perpendicular to a first direction of a sheet feeding direction while holding the sheet; a feeding section provided upstream of the registration roller pair in the first direction and including a feeding belt configured to convey the sheet to the registration roller pair; a first air adjustment section configured to perform air suction or blowing for the sheet conveyed by the feeding belt; and a control section configured to switch between a first operation of controlling, when the sheet is conveyed by the feeding belt, the first air adjustment section to suck the sheet with air and a second operation of controlling, when the sheet is swung by the registration roller pair, the first air adjustment section to blow air on the sheet.

A substrate support system 10 for a conveyor printer is provided, comprising a support unit 100 comprising a plurality of vacuum apertures 108 arranged for fluidic communication with a source of negative pressure. The support unit 100 also comprises at least one air bearing 114 arranged for fluidic communication with a source of positive pressure. The air bearing 114 comprises porous media 116. The substrate support system 10 also comprises a conveyor belt 150 arranged over the support unit 100 for supporting a substrate 170 to be printed on. The conveyor belt 150 comprises a plurality of belt apertures. The vacuum apertures 108 are arranged to convey a negative pressure through the belt apertures for retaining the substrate 170 on the conveyor belt 150. The at least one air bearing 114 is arranged to convey a positive pressure to support the conveyor belt 150.

A paper feeding apparatus for feeding paper from a paper-mounting table on which a paper bundle is mounted includes a suctioning conveyor that suctions and conveys uppermost paper among the paper bundle mounted on the paper-mounting table; and a hardware processor that controls the suctioning conveyor, wherein the suctioning conveyor includes a suction region for suctioning paper in a paper width direction orthogonal to a paper conveyance direction, and the hardware processor controls distribution of a suction amount in the paper width direction based on stiffness and a paper width, which is a paper size in the paper width direction, of paper.

Methods and apparatuses for moving and/or transferring discrete articles are described. In particular, the methods and apparatuses relate to flexible arrangements to move and/or transfer discrete articles that vary in size and/or shape with minimal to no change in equipment.

A sheet feeding device includes a sheet stacking table, an air blower, a feeder, and an air sucker. The sheet stacking table stacks a bundle of sheets. The air blower blows air to the bundle of sheets to float an uppermost sheet from the bundle of sheets. The feeder feeds the uppermost sheet. The air sucker sucks air in such a direction that a sheet in vicinity of the uppermost sheet moves away from the feeder. The air sucker includes a suction nozzle to suck air, a suction fan to generate a negative pressure, a suction duct to communicate the suction nozzle with the suction fan, and an opening-and-closing mechanism to shut off and release ventilation in the suction duct.

Systems and methods for folding and stacking fanfold corrugated board material. A system may include a rotatable member (e.g., a wheel) having a number of head pieces disposed thereon. Each head piece has a vacuum setting that can be used to pick up a portion of a length of fanfold and hold it while the rotatable member rotates around its axis and a second blower setting that blows the portion of the length of fanfold that was picked up and rotated around the rotatable member down onto a stack of fan fold. Such a system is capable of forming regular and consistent stacks of fanfold material efficiently and cost effectively without the need for significant human intervention.

Methods and apparatuses for moving and/or transferring discrete articles are described. In particular, the methods and apparatuses relate to flexible arrangements to move and/or transfer discrete articles that vary in size and/or shape with minimal to no change in equipment.

Methods and apparatuses for moving and/or transferring discrete articles are described. In particular, the methods and apparatuses relate to flexible arrangements to move and/or transfer discrete articles that vary in size and/or shape with minimal to no change in equipment.

A sheet feeder, which is included in an image forming apparatus, includes a sheet loader, an air blowing device, a regulator, a sheet attracting device, and a sheet conveying body. The sheet loader loads a sheet bundle including a sheet and a subsequent sheet placed below the sheet. The air blowing device blows air and lifts the sheet over the sheet bundle. The regulator regulates movement of the subsequent sheet, and includes an opposing portion located upper end and separated from the sheet loader toward the downstream side of the sheet conveying direction and an inclined portion upwardly inclined relative to a vertical axis from a same position as the sheet loader to the downstream side of the sheet conveying direction. The sheet attracting device attracts the sheet lifted over the sheet bundle. The sheet conveying body conveys the sheet in a sheet conveying direction.

Methods of conveying a glass ribbon are provided that each includes the step of conveying the glass ribbon over a support device with a cushion of fluid supporting the glass ribbon over the support device. Each method further includes the step of monitoring a physical contact event between the glass ribbon and the support device by detecting an acoustic signal associated with the physical contact event. In further examples, glass ribbon conveying apparatus are provided that each includes a support device configured to support a glass ribbon over the support device with a cushion of fluid. Each apparatus further includes an acoustic sensor configured to monitor a physical contact event between the glass ribbon and the support device by detecting an acoustic signal associated with the physical contact event.