A suction conveyor device comprising a suction arrangement having a suction side on which low pressure is generated, continuously rotating flexible conveying means made of flexible flat material having holes, an inner side enabling the conveying means to move along the suction side, and an outer side for receiving flat items in the active area of the suction side, where the conveying means moves in the transporting direction, the suction arrangement and the conveyor means designed with a transport path width in the active range perpendicular to the transporting direction. The conveying means includes continuously circulating individual, single-piece, flexible conveying means, both lateral edges thereof extending in the transporting direction at a distance from each other being at least the same as the total width of the transport path such that the individual, single-piece flexible conveyor means extend over the total width of the transport path.

A device (110) for sampling sheet elements (20) in a sorting unit (100) comprises: transport means (111, 112) defining a plane (P0) and able to move (A) a sheet element (20) longitudinally upstream to downstream, an axis (R1) situated at the level of the transport means (111, 112) and extending transversely, a diversion part (113) rotatable about the axis (R1) and having at least one end (114) so that during the rotation of the diversion part (113) through a first angular sector (S1) the horizontal projection of the end (114) remains below the plane (P0) and during the rotation through a second angular sector (S2) complementary to the first angular sector the horizontal projection of the end (114) moves above the plane (P0) so as to divert a sheet element (20) in a direction different from the plane (P0) and thus to sample the sheet element (20).

A system for cutting a web material and applying the web material on a substrate. The system comprises a feed roll configured to advance a web material. The system includes an anvil roll configured to receive the web material from the feed roll and provide a section of web material having a defined length. The system includes a cutting element configured to cut the web material to form the section of web material. The anvil roll is configured such that the anvil roll surface advances at an anvil roll surface speed. The feed roll is configured to rotate at a first feed roll surface speed that is slower than the anvil roll surface speed and a second feed roll surface speed that is substantially the same as the anvil roll surface speed when the cutting element cuts the web material.

The present invention provides a sheet stacking device, a counter-ejector, and a carton former and is provided with: a hopper unit that stacks cardboard boxes; feed rollers that feed a cardboard box to the hopper unit; a first blower device that blows air from above the hopper unit toward the cardboard box fed by the feed rollers; and a second blower device that blows air between the cardboard box stacked in the hopper unit and the cardboard box fed by the feed roller.

A drying device includes: a supporting section that supports a medium on which printing was performed; a conveying section that conveys, along a conveying region, the medium supported by the supporting section; a heat generating section configured to heat, over a width direction, the medium supported by the supporting section; a fix-supporting section configured to support the heat generating section fixing the heat generating section; and free-supporting section configured to support the heat generating section so that the heat generating section can expand and contract, wherein the fix-supporting section is located in a first lateral region that is a region outside the conveying region in the width direction, and the free-supporting section is located in a second lateral region that is a region outside the conveying region in the width direction and different from the first lateral region.

A printer includes a record section, a discharge section, a mount section, a movable rib, a move section, and a control section. The record section records on a sheet by ejecting an ink to the sheet. The discharge section discharges the sheet. The mount section has a mount surface on which the sheet discharged is mounted. A movable rib is configured to protrude from the mount surface and supports the sheet. The dimension of the movable rib in an A-direction is larger than the dimension thereof in a Y-direction. The move section moves the movable rib in a C-direction. The control section controls, based on temperature and humidity information, movement of the movable rib made by the move section.

Post-processing apparatus for performing given process subsequently to image forming process by image forming apparatus is disclosed. Post-processing apparatus includes: first ejector which ejects sheet; first tray which temporarily holds sheet; second tray situated downstream of first tray in ejection direction of sheet; a tray driver which moves second tray downwardly from first height position; blower which forms airstream between second tray and lower surface of sheet; and controller which controls blower and tray driver. Controller includes: blower controller which causes blower to blow air over time period in synchronization with first time period from start to end of sheet ejection by first ejector; and tray controller which causes tray driver to move second tray downwardly from first height position after first time period.

A sheet conveyance apparatus includes a control unit (120) that controls driving of a belt drive mechanism (4). The control unit (120) performs control such that the sheet is conveyed from the sheet accumulation area if (a) it is determined that the number of sheets currently accumulated in the sheet accumulation area is two or greater, while the sheet is not conveyed from the sheet accumulation area if (b) it is determined that the number of sheets currently accumulated in the sheet accumulation area is one.

An air nozzle apparatus that includes an air orifice and a nozzle housing, said nozzle housing configured as u-shaped having a first elongated sidewall, a second elongated sidewall, and a third curved sidewall formed continuous with said first elongated sidewall and said second elongated sidewall to form a channel having an open end opposite said third curved sidewall, said air orifice positioned centered in said channel and proximate a base of said third sidewall facing said open end, wherein said first elongated sidewall, said second elongated sidewall, and said third curved sidewall are configured having an arched top surface, and, thus, functions to optimize the Coanda effect to position and convey the paper web through an air threading chute to thread a paper web from the end of the drying step through the dry-end to the paper winding step.

An assembly method and a combined and bivalent workstation for automatically assembling photovoltaic panels, with printing of ECA on cell portions and progressive arrangement with a partial superimposition on the contacts, pre-forming shingled strings in a continuous cycle, which are ready for loading on a backsheet, without dry-curing. The method provides a macro-phase of lay-up entirely made in the station, with simultaneous and coordinated sub-phases: picking of portions with a first handler and control, oriented loading on a vacuum belt, control of positioning on the belt, printing of ECA, control of printing and positioning, progressive superimpositions on a shuttle-tray with bidirectional translation coordinated with a second handler with chocked vacuum, picking of the shingled string with a third handler, control of string alignment, loading and pre-fixing. Vision systems are integrated for the execution of said sub-phases.