A medium conveying apparatus includes a suctioner that suctions a medium of a plurality of media to a feed belt, a driver that moves the feed belt to feed the medium, a first side blower that blows air at a first airflow rate to a first end face of the medium, a second side blower that blows air at a second airflow rate to a second end face of the medium, and a controller that controls the first side blower to blow air to the first end face at a third airflow rate that is greater than the first airflow rate and the second airflow rate when the medium has not been auctioned to a first portion of the feed belt close to the first end face and has been auctioned to a second portion of the feed belt close to the second end face.

A vacuum table for a wide format printing system, wherein a medium support surface with vacuum holes therein is spaced apart from a bottom plate by a spacer array. The spacer array is formed by an integrally formed spacer structure with a first and a second longitudinal plate positioned between the bottom plate and the medium support surface. These plates comprise a plurality of air flow through-holes as well as a top support edge and a bottom support edge extending equidistantly to one another. A connection element connects the first longitudinal plates and is positioned between the bottom support plane and the top support plane. The use of longitudinal plates allows the spacer to be cheaply and easily produced by punching. The plates further offer the advantage of a low air flow resistance while maintaining a high rigidity of the spacer array.

An arrangement (100) for handling flat elements (202), in particular paper elements (202). A guiding structure (101) is provided, along which a flat element (202) is guidable and transportable along a transport direction (T). A hold-down element (102) is coupled to the guiding structure (101) for holding down the flat element (202) to the guiding structure (101). The hold-down element (102) has a support section (103) on which the flat element (202) is supportable. The hold-down element (102) extends along an extending direction (116) having a component perpendicular to the transport direction (T), wherein suction holes (104) are arranged along the extending direction (116). A suction unit (110) includes a suction opening (111) coupled to the suction holes (104) of the hold-down element (102), an air inlet (112) and an air outlet (113), wherein the suction unit (110) directs air from the air inlet (112) to the air outlet (113) for generating an air flow (114). The suction opening (111) is formed and arranged such that the air flow (114) passes the suction opening (111) so that air flow (114) entrains air through the suction opening (111).

A sheet conveyance device transports a sheet to a predetermined processing unit, and includes a conveyance belt, a ventilation unit, and a suction unit. The conveyance belt has a first surface and a second surface, and is arranged to be opposed to the processing unit to transport the sheet on the first surface in a predetermined conveyance direction. On an upstream side of the processing unit in the conveyance direction, the ventilation unit blows out wind toward the sheet to adhere the sheet to the first surface of the conveyance belt. The suction unit is arranged to be opposed to the processing unit with the conveyance belt interposed therebetween to generate a negative pressure between the sheet adhered to the first surface by the ventilation unit and the conveyance belt, thereby bringing the sheet into close contact with the first surface of the conveyance belt.

An arrangement (100) for handling flat elements (202), in particular paper elements (202). A guiding structure (101) is provided, along which a flat element (202) is guidable and transportable along a transport direction (T). A hold-down element (102) is coupled to the guiding structure (101) for holding down the flat element (202) to the guiding structure (101). The hold-down element (102) has a support section (103) on which the flat element (202) is supportable. The hold-down element (102) extends along an extending direction (116) having a component perpendicular to the transport direction (T), wherein suction holes (104) are arranged along the extending direction (116). A suction unit (110) includes a suction opening (111) coupled to the suction holes (104) of the hold-down element (102), an air inlet (112) and an air outlet (113), wherein the suction unit (110) directs air from the air inlet (112) to the air outlet (113) for generating an air flow (114). The suction opening (111) is formed and arranged such that the air flow (114) passes the suction opening (111) so that air flow (114) entrains air through the suction opening (111).

An article holding device includes a base portion having flow paths communicated with holes and a holding portion provided on a lower surface of the base portion. The holes including a first hole and a second hole, the first hole being provided on one side of the holding portion in the predetermined direction, the second hole being provided on another side, which is opposite from the one side, of the holding portion in the predetermined direction. The recessed portion being provided between the first hole and the second hole and being recessed above the horizontal portion of the holding portion. It is thus possible to effectively generate a negative pressure in the space of the recessed portion between the holding portion and the article.

A vacuum belt conveyor sequentially delivers sheet articles to a digital printer. The sheets are held in position by vacuum on the underside of the sheets through apertures in the belts and covered by the sheets. A plurality of independent plenums on the underside of the belt have chambers respectively communicating with rows of apertures extending along the belt. Vacuum is selectively applied from a manifold only to the plenum chambers that supply apertures that are covered by the sheets so that the ink from the printer will not be directed from its intended position on the sheet by vacuum from adjacent uncovered belt apertures. The sheets are fed to the conveyor in synchronism with the conveyor speed by a timed feeder so that the sheets are carried by the conveyor with a predetermined gap between the sheets and no belt apertures in the gap. A sensor counts the apertures in the belt and activates the feeder at predetermined time intervals.

A sheet conveyance apparatus includes: a placement part configured such that stacked sheets are disposed on the placement part; a housing including an open/close part and accommodating the placement part, at least a portion of the open/close part being configured to be opened and closed; and a suction unit connected with the housing, and configured to draw gas from an interior of the housing.

A sheet conveyance device transports a sheet to a predetermined processing unit, and includes a conveyance belt, a ventilation unit, and a suction unit. The conveyance belt has a first surface and a second surface, and is arranged to be opposed to the processing unit to transport the sheet on the first surface in a predetermined conveyance direction. On an upstream side of the processing unit in the conveyance direction, the ventilation unit blows out wind toward the sheet to adhere the sheet to the first surface of the conveyance belt. The suction unit is arranged to be opposed to the processing unit with the conveyance belt interposed therebetween to generate a negative pressure between the sheet adhered to the first surface by the ventilation unit and the conveyance belt, thereby bringing the sheet into close contact with the first surface of the conveyance belt.

A sheet stacking device includes a sheet stacking section, pairs of ejection rollers, an airflow generator, and an airflow guide. The airflow guide has a center exhaust port and paired side exhaust ports. An airflow is blown out from the center exhaust port toward a central part of the lower surface of the sheet in a sheet width direction perpendicular to a conveyance direction of the sheet. Airflows are blown out from the respective paired side exhaust ports toward respective sides of the lower surface of the sheet. An amount of the airflow blown out from the center exhaust port is larger than those of the airflows blown out from the respective paired side exhaust ports.