A conveyor includes a first conveyor deck having a first plurality of contact elements, each having a contact surface movable around a closed path from a contact region to a non-contact region, the first contact regions lying in a plane or being bounded by the plane and a second conveyor deck having a second plurality of contact elements, each having a contact surface movable around a closed path from a contact region to a non-contact region, these contact regions lying in a second plane or being bounded by the second plane. The transport path of the conveyor is defined by the contact surfaces of the first and second contact elements in the contact regions, and the first plurality of contact elements are belts and the second plurality of contact elements are wheels.

A conveying apparatus includes an upper conveyor and a lower conveyor, the top of the lower conveyor facing the bottom of the upper conveyor and defining with the bottom of the upper conveyor a sheet transport path. An air duct having an opening facing the top of the upper conveyor is mounted over the upper conveyor, and a fan is provided that is in fluid communication with the air duct. The fan draws air through the opening, into the air duct and out an exhaust vent. A housing substantially encloses the upper conveyor and the lower conveyor and is connected to the air duct, and the housing has a bottom opening located below the sheet transport path such that a majority of the air drawn through the opening by the fan passes through the upper conveyor.

A continuous body folding device includes a conveying part having a moving surface that moves while suctioning and holding a first region of a continuous body, the conveying part conveying the continuous body in the longitudinal direction thereof; a first folding reference part in which a first endless belt, which moves in a first circulatory pathway along a first virtual plane including the moving surface, moves along a first reference segment adjacent to a virtual line of the continuous body in the same direction at the same speed as the moving surface; and first guiding members that are disposed along the first reference segment, contact a second region of the continuous body, and fold the continuous body along the virtual line and move the second region toward the first region so that the angle formed by the first and second regions becomes smaller as the continuous body is conveyed downstream.

A method for reducing skew in a media advance system comprises advancing a media from a media roll (6a) through a feed roller (3) towards the nip of a drive roller (4); reducing a media transportation speed at the feed roller (3) relative to the media transportation speed at the drive roller (4) for a predetermined period of time when a leading edge of the media reaches the nip of the drive roller; and cutting the media to a predetermined page size at a position upstream of the feed roller.

A conveyor includes a first conveyor deck having a first plurality of contact elements, each having a contact surface movable around a closed path from a contact region to a non-contact region, the first contact regions lying in a plane or being bounded by the plane and a second conveyor deck having a second plurality of contact elements, each having a contact surface movable around a closed path from a contact region to a non-contact region, these contact regions lying in a second plane or being bounded by the second plane. The transport path of the conveyor is defined by the contact surfaces of the first and second contact elements in the contact regions, and the first plurality of contact elements are belts and the second plurality of contact elements are wheels.

A conveying apparatus includes an upper conveyor and a lower conveyor, the top of the lower conveyor facing the bottom of the upper conveyor and defining with the bottom of the upper conveyor a sheet transport path. An air duct having an opening facing the top of the upper conveyor is mounted over the upper conveyor, and a fan is provided that is in fluid communication with the air duct. The fan draws air through the opening, into the air duct and out an exhaust vent. A housing substantially encloses the upper conveyor and the lower conveyor and is connected to the air duct, and the housing has a bottom opening located below the sheet transport path such that a majority of the air drawn through the opening by the fan passes through the upper conveyor.

A diverter conveyor includes a frame supporting an upper conveyor that has an upstream end and a downstream end and that is configured to carry sheets in a first, downstream, direction. A plurality of nip rollers are mounted on the frame upstream of the upstream end of the upper conveyor and are spaced from the upstream end of the upper conveyor by a gap. The nip rollers feed the sheets along a main path to the upstream end of the upper conveyor. A rejection conveyor is supported by the frame and has a portion beneath the gap and extends away from the upper conveyor at an acute angle. A plurality of paddles are mounted at the first gap, and an actuator is operably connected to the paddles and configured to shift the paddles from a first position out of the main path to a second position in the main path.

According to an example, a roller assembly for media loading comprises a fixed frame, a plurality of parallel rollers that protrude from a bottom surface of the fixed frame, and a coupling member to mechanically coupled the fixed frame to a reference surface, wherein each roller of the plurality of rollers is rotatably coupled to the fixed frame and is movable with respect to the bottom surface of the fixed frame.

A conveyor for transporting sheets along a path from an input end to a discharge end includes a main frame, an upper conveyor deck supported by the main frame and having a plurality of belts and a lower conveyor deck supported by the main frame and having a plurality of wheels supported by a plurality of shafts. The transport path is defined by the contact surfaces of the plurality of belts in the first contact region and the contact surfaces of the plurality of wheels in the second contact region, and the conveyor is configured such that the sheets make direct contact with the contact surfaces of the plurality of belts and make direct contact with the contact surfaces of the plurality of wheels when the sheets move along the transport path. The lower conveyor deck is shiftable laterally relative to the upper conveyor deck.

A device for reducing rotation of an article during singulation of a stack of articles is disclosed. The device may include a torsion element, a rotatable member configured to rotate about an elongated axis of the torsion element between a first position and a second position, and a revolving member coupled to the rotatable member. An outer surface of the revolving member contacts a drive belt in the first position and an article in the second position. The torsion element exerts torque on the rotatable member when it moves from the first position towards the second position. The torque causes the outer surface of the revolving member to apply a frictional force to the article, thereby minimizing rotation of the article. Systems and methods of singulating articles are also disclosed.