The disclosure relates to a method and apparatus for uncut material detection while lifting from an automated cutting table select pieces of thin, flexible material. The apparatus comprises a structured energy source and a structured energy sensor. The structured energy can be used to detect undesired lifting of a peripheral portion of the flexible material resulting from the presence of uncut material.

The control apparatus includes an acquisition unit, an air volume setting unit, and an air blow control unit. The air volume setting unit sets a volume of air to be blown toward the plurality of sheets from a separation blower based on the information on the processing job acquired by the acquisition unit or by manipulation of a user. When the air volume is changed from a first air volume to a second air volume different from the first air volume by the user, the air volume setting unit maintains the air volume as the second air volume, irrespective of the information on the processing job acquired by the acquisition unit, until the air volume is changed from the second air volume to an air volume different from the second air volume by the user.

A post-processing device includes a discharge port through which a sheet is discharged, an intermediate tray, a discharge tray and an air sending part. The air sending part includes an upper air sending member, an upper switching member, a lower air sending member, a lower switching member and a controller. The upper air sending member generates a downward air flow from above the discharge port. The upper switching member is distributable the air flow generated by the upper air sending member to above the intermediate tray and to above the discharge tray. The lower air sending member generates an upward air flow from below the discharge port. The lower switching member is distributable the air flow generated by the lower air sending member to below the intermediate tray and to above the discharge tray. The controller controls the upper switching member and the lower switching member.

A post-processing device includes a discharge port through which a sheet is discharged, an intermediate tray, a discharge tray and an air sending part. The air sending part includes an upper air sending member, an upper switching member, a lower air sending member, a lower switching member and a controller. The upper air sending member generates a downward air flow from above the discharge port. The upper switching member is distributable the air flow generated by the upper air sending member to above the intermediate tray and to above the discharge tray. The lower air sending member generates an upward air flow from below the discharge port. The lower switching member is distributable the air flow generated by the lower air sending member to below the intermediate tray and to above the discharge tray. The controller controls the upper switching member and the lower switching member.

An image forming apparatus comprises a main body, a conveyance path, a first external cover and a second external cover. The first cover provided in the main body to cover the conveyance path includes a blocking wall facing the conveyance path; a concave portion provided below the blocking wall and recessed toward the main body with respect to a lower end of the blocking wall; a communication portion, provided between the lower end of the blocking wall and an upper end of the concave portion, that penetrates the first external cover and faces an outer space of the image forming apparatus at a position that extends from the concave portion to the blocking wall; and an air exhaust portion provided above the blocking wall.

A sheet stacker includes a sheet ejector, a sheet stack portion, and air blowers. The sheet ejector ejects a sheet. The sheet stack portion stacks the sheet ejected by the sheet ejector. The air blowers blow air from blow ports toward the sheet ejected from the sheet ejector. Each of the air blowers includes an air generator, an air guide, a first blow portion, a second blow portion, and a switcher. The air generator generates the air. The air guide guides the air to each of the blow ports. The first blow portion blows the air toward the sheet. The second blow portion blows the air in a direction different from a direction in which the first blow portion blows the air. The switcher performs switching so that the air guide guides the air to one of the first blow portion and the second blow portion.

A medium feeding device includes: a medium mounting section that a medium is mounted; a feeding unit that feeds the medium in a feeding direction; a separation unit that separates the medium with the feeding unit; an operation detection unit that is disposed at a position facing a surface of the medium in the medium mounting section and detects a movement of the medium in the feeding direction; an interval forming unit that forms an interval in the feeding direction between a trailing end of a first medium which is the lowest medium fed among media mounted on the medium mounting section and a trailing end of a second medium which is bound with the first medium and stacked on the first medium; and a control unit that stops feeding of the medium based on a detection interval by a detection value of the operation detection unit.

The invention presented and described comprises an apparatus for mounting flat data carriers (1) on a continuous carrier web (2), having a data carrier supply device (3), a data carrier transfer device (4) and a carrier web positioning device (5), wherein the supply device (3) has a drive roller (6), a deflector (7) arranged substantially horizontally spaced apart from the drive roller (6) and at least one carrying belt (8) which runs around the drive roller (6) and deflector (7), wherein the carrying belt (8) has an upper run (9) which runs substantially horizontally in the feed direction of the data carriers (1), and a lower run (10) which runs in the opposite direction below said upper run, wherein the upper run (9) forms a transport path (11) for the data carrier (1) and is hydraulically connected to a suction box (12) which is arranged beneath in such a way that data carriers (1) which are located on the upper run (9) can be drawn by suction onto the carrying belt (8) by negative pressure, wherein the transfer device (4) has a transfer roller (14), which is provided with intake openings (13) on the circumference and which is hydraulically connected to a negative pressure source in such a way that data carriers (1) located on the outer casing of the transfer roller (14) can be drawn by suction onto the outer casing by negative pressure, wherein the transfer roller (14) has an entry region (15) which is adjacent to the suction box (12) of the supply device (3) and an exit region (16), which is spaced apart from the entry region (15) by a specific angle and is adjacent to the positioning device (5), and wherein at the exit region (16) of the transfer roller (14), a data carrier (1) which is located there on the outer casing of the transfer roller (14) can be transferred onto the carrier web (2).

Certain examples described herein relate to transporting sheets of print media. In one example, a media transport apparatus has a plurality of media transport sections including a first media transport section and a second media transport section offset from the first media transport section in a media transport direction. The media transport apparatus has a holding section arranged to receive a sheet of print media from the first media transport section. The holding section is moveable to deposit the sheet of print media upon the second media transport section.

A sheet stacking system includes a conveyor for carrying sheets from a conveyor intake end to a conveyor discharge end and a hopper at the discharge end for receiving the sheets and guiding them as they fall in a cascade path onto a platform. The hopper has a backstop facing the discharge end of the conveyor and a first accumulator that includes a carrier and a support extending from the carrier through the backstop. The support is configured to rotate from a retracted position to an extended position relative to the backstop, and the carrier is movable linearly and vertically relative to the backstop with the support in the extended position from a raised location with the support outside the cascade path to a lowered location with the support in the cascade path.