According to various embodiments, the temperature control roller may comprise: a cylindrical roller shell, which has a multiplicity of gas outlet openings; a temperature control device, which is configured to supply and/or extract thermal energy to or from the cylindrical roller shell; multiple gas lines made to extend along the axis of rotation; a gas distributing structure, which couples the multiple gas lines and the multiplicity of gas outlet openings to one another in a gas-conducting manner, the gas distributing structure having a lower structure density than the multiplicity of gas outlet openings.

A sheet 200 for an array of vacuum apertures 152 in a substrate support unit 150 of a printer is provided. The sheet 200 comprises a plurality of valves 202 formed into the sheet 200. The sheet 200 is made from a resilient material. Each valve 202 comprises a valve head 204 for sealing a vacuum aperture 152 in the substrate support unit 150, and a valve lever arm 206 for permitting movement of the valve head 204 towards and away from the vacuum aperture 152 in order to open and close the valve 202.

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 vacuum lifter apparatus for lifting sheet material articles comprises an upper chassis, a modular lower suction plate supported beneath the chassis, a controller and a source of vacuum air pressure, the suction plate comprising a suction lifting surface for providing vacuum lifting pressure to said articles. The modular suction plate has plural side-by-side modules, each module providing a different portion of the suction lifting surface and having one or more air outlets, outlets of one module separate from outlets of other modules and in fluid communication with the corresponding portion of the suction lifting surface and not with different portions of the suction lifting surface. The chassis comprises at least one air outlet connected to said source of vacuum air pressure, and a plurality of separate air flow channels through the chassis. Each air flow channel has an associated air flow valve and a valve actuator.

A sheet separating device includes: a lifting nozzle configured to blow air against an end portion of a sheet bundle placed on a sheet loading portion to lift sheets; a separating nozzle configured to separate the sheets; a lifting-nozzle shutter member configured to open and close the lifting nozzle; a separating-nozzle shutter member configured to open and close the separating nozzle; a lifting-shutter driving mechanism configured to drive the lifting-nozzle shutter member; a separating-shutter driving mechanism configured to drive the separating-nozzle shutter member; and an open/close control unit configured to control the lifting-shutter driving mechanism and the separating-shutter driving mechanism such that the lifting-nozzle shutter member and the separating-nozzle shutter member are opened or closed simultaneously.

A transport device transports an individualized sheet-shaped workpiece. The transport device includes: an annular transport belt having a first surface and a second surface opposite to the first surface and having a plurality of suction holes extending between the first surface and the second surface; first and second decompression chambers arranged along a moving direction of the transport belt; and a vacuum degree adjusting mechanism provided in the first decompression chamber and adjusting a vacuum degree in the first decompression chamber. The first and second decompression chambers each abut against the second surface, and each suction the workpiece through at least one of the plurality of suction holes toward the first surface such that the transport belt is capable of transporting the workpiece in the moving direction in a suspended state from the first surface.

A device (10) for optically controlling a face (13) of a blank (12) has a vacuum conveyor (20) capable of transporting the blank (12) along a path of travel (15) and which includes a conveyor belt (22) having an apertured structure of which the conveying path follows the path of travel (15) of the blank (12). A suction device (40) is suitable for pressing the blank (12) against the conveyor belt (14). An inspection device (30) inspects the face (13) of the blank (12) during its conveyance by the vacuum conveyor (20). The inspection device is located on the side opposite the vacuum conveyor (20). The suction device (40) delimits three separate successive suction sections (41, 42, 43) along the path of travel (15), including a central suction section (42) that extends opposite the inspection device (30), an upstream suction section (41) and a downstream suction section (43).

A suction device configured to reliably support or transfer a fiber material web made from glass fibers, fleece material or paper, the suction device including a first guide roller and a second guide roller; a suction box arranged between the first guide roller and the second guide roller; and a permeable clothing that runs over the first guide roller, the second guide roller and the suction box, wherein the suction box includes an operating surface configured to impart a vacuum upon the permeable clothing that runs over the operating surface and upon the fiber material web transported on the permeable clothing during operations, wherein the operating surface is arranged and sized so that it essentially bridges an entire path traveled by the clothing between the first guide roller and the second guide roller; an additional guide roller and an additional suction box over which the permeable clothing is run.

A medium feeding device includes a container member that accommodates sheet media, a discharging member disposed further than the media accommodated in the container member in a discharging direction in which the media are discharged, a hand-over member disposed above the container member at a position closer to the discharging member, a floating device disposed on a side of the media accommodated in the container member, and an auxiliary suction member disposed above the container member on a side of the hand-over member opposite to a side closer to the discharging member in the discharging direction in which the media are discharged. The auxiliary suction member is disposed closer to the hand-over member than to an end portion of the media accommodated in the container member opposite to an end portion of the media located closer to the discharging member.

In one example, a media support with a continuous belt rotatable and suction cups lengthwise along the belt and in lines laterally across the belt to hold down a sheet of print media as the sheet is moved through a hold down area, a vacuum pump to supply vacuum to the suction cups. The vacuum control system is configured to close a supply of vacuum to all of the suction cups in the hold down area and then open the supply of vacuum sequentially to each of multiple lines of suction cups as each line enters the hold down area and then close the supply of vacuum sequentially to each of the multiple lines of suction cups as each line leaves the hold down area until all of the suction cups in the hold down area are closed.