A winding machine for web-type materials, in particular film materials, comprises a feeding device and at least one winding shaft which is capable of being driven and designed to receive a winding core for the winding of the web-type film material, wherein the winding machine is allocated a system for regulating and/or reducing an electrostatic charge of the web-type material during the winding process.

The static charge eliminator includes a charger including one or more charging units, and a grounded needle-shaped conductor. The charger is configured to charge an insulating film such that the absolute value of the surface potential of the insulating film is 3 kV or more. The needle-shaped conductor is arranged to generate a corona discharge between the needle-shaped conductor and the insulating film charged by the charger. Thereby, the static charges on the insulating film can be reliably eliminated.

A printing apparatus includes a printing head that performs printing in a printing region of a first surface of a medium, a support portion that supports a second surface of a medium, a transport unit that transports the medium in a transport direction, and a static electricity eliminating material that is provided facing the second surface and that eliminates, in a non-contact manner with the medium, static electricity accumulated in the medium. The support portion includes a spacer that maintains a predetermined distance between the medium and the static electricity eliminating material.

A note directing device (1) comprises a first note feeder (11), a brushed roller (2), and a second note feeder (12); wherein: the first note feeder (11) feeds the bank note (10) along a direction (A) tangential to a bank note (10) surface and presents the leading edge (14) of the bank note (10) to the brushed roller (2); the brushed roller (2) engages with the bank note (10) and rotates in a direction (B) such that the leading edge (14) is directed towards the second note feeder (12); the second note feeder (12) accepts the leading edge (14) and feeds the bank note (10) along a direction (C) tangential to a bank note (10) surface; wherein the brushed roller (2) comprises an axis (4) and bristles (6), each bristle (6) being attached at one end to the axis (4) and extending radially from said axis (4), the distribution of bristles (6) extending along a longitudinal direction (E) of the axis (4).

A printer as a medium processing apparatus includes a transport path through which a paper being transported passes, a recording head that records on the paper on the transport path, and a platen that forms at least a portion of the transport path as a path forming member with which the paper comes into contact, in which a surface resistance value of the path forming member changes according to an applied voltage of the medium.

The invention relates to a device and a method for stacking card-like data carriers. The device comprises (i) a conveying device for transporting individual card-like data carriers downstream along a conveying path and (ii) a stacking unit for selectively transferring and stacking card-like data carriers conveyed along the conveying path. The conveying device is arranged to convey the card-like data carriers in such a way that they are fixed to it in a hanging mode of transport. The stacking unit is arranged to selectively release certain ones of the card-like data carriers conveyed along the conveying device from the latter in order to transfer them directly—i. e. in particular without intermediate processing, intermediate transport or intermediate storage—into a card magazine and to stack them therein when the card magazine is arranged in a stacking area at a stacking position which, in relation to the direction of gravity, is situated below the conveying path.

A printing apparatus includes a printing head that performs printing in a printing region of a first surface of a medium, a support portion that supports a second surface of a medium, a transport unit that transports the medium in a transport direction, and a static electricity eliminating material that is provided facing the second surface and that eliminates, in a non-contact manner with the medium, static electricity accumulated in the medium. The support portion includes a spacer that maintains a predetermined distance between the medium and the static electricity eliminating material.

A screening apparatus for an optical fiber includes a delivery unit that delivers an optical fiber; a screening unit that applies tension to the delivered optical fiber to perform screening of the optical fiber; a winding unit that winds the optical fiber after screening; and a static electricity removing unit that removes static electricity of the optical fiber traveling on the predetermined passage, the static electricity removing unit being disposed along a predetermined passage of a passage of the optical fiber from an exit side of the screening unit to an entry side of the winding unit.

A sheet discharging apparatus includes a discharge portion discharging a sheet in a discharge direction; a sheet supporting portion including a support surface which supports a lower surface of the sheet discharged from the discharge portion; and a conductive portion which is electrically conductive and connected to a ground potential. The conductive portion is provided at the support surface.

A sheet conveyance device includes a conveyor configured to convey a sheet in a sheet conveyance path and a discharger disposed at an intermediate position in the sheet conveyance path. The conveyor is configured to contact the sheet in a contact range within and narrower than a passage range where the sheet passes through the sheet conveyance path in a width direction of the sheet. The discharger is disposed close to the sheet that the conveyor is conveying in the sheet conveyance path, in a range different from the contact range and configured to remove static electricity from the sheet that the conveyor is conveying in the sheet conveyance path.