A gripper carriage transports a sheet in a sheet transport direction along a sheet transport path. The gripper carriage has a wall and a reflector. The reflector is associated with a flank of the wall which is trailing, in relation to the sheet transport direction.

A device for stacking notes of value includes at least one circulating belt arrangement including an endless belt guided over rollers serving as deflecting elements. The circumferential surface of the belt has at least one transport tongue into which at least a section of a note of value is insertable. The device includes at least one strip-off element that contacts the note for the removal from the transport tongue. The device includes a contact element which is arranged and configured such that during the transport in the transport tongue the note moves the contact element into a first position. The contact element contacts an area of the note at least after the removal of the note of value from the transport tongue up to the arrival of this note on the deposit surface or on the upper note of value of a value note stack deposited on the deposit surface.

In an example, a clamp may include a chassis, a swingarm disposed on the chassis, a clamp wheel disposed on a first end of the swingarm to engage with a drag portion of the chassis, and an auxiliary bias member to exert a force against the clamp wheel to resist a rotation of the clamp wheel. The force may periodically increase in magnitude.

In an example, a clamp may include a chassis, a swingarm disposed on the chassis, a clamp wheel disposed on a first end of the swingarm to engage with a drag portion of the chassis, and an auxiliary bias member to exert a force against the clamp wheel to resist a rotation of the clamp wheel. The force may periodically increase in magnitude.

A sheet guide includes an endless belt, and a guide supported by a plurality of places of the endless belt, the guide configured to hold a downstream end of the sheet in a conveyance direction of the sheet, wherein the endless belt is configured to rotate to move the sheet held by the guide in the conveyance direction.

A chain tensioner (50; 500) for a conveying device (70) of a machine (1; 1) for processing elements in the form of sheets (10), the conveying device (70) includes two lateral chain sets connected to the ends of transverse gripper bars (75) able to grasp the elements (10) and at least one chain-guiding device (90) configured to guide a respective chain set (80); the chain tensioner (50; 500) includes: an actuator (9) controlled by a control unit (8), a movable support (11), a transmission element (12) borne by the movable support (11), a rotary element (13) rotated by the actuator (9) and cooperating with the transmission element (12) in order to exert a thrust force on the movable support (11), the rotary element (13) being rotatable, to adjust the tension of the chain set (80). The actuator (9) is controlled in synchronism with the machine angle (MA). A machine (1; 1) for processing elements and a method for tensioning the chain sets (80) of the conveying device (70) are disclosed.

An insert sheet loading device (10) comprising a movable carriage (12; 12) for inserting insert sheets into a receiving area (2) of a blank-receiving station (500). The movable carriage (12; 12) has a plurality of longitudinal bars (27a, 27b). At least one longitudinal bar (27a) has a suction channel (35) leading out, via at least one suction opening (30), onto the surface of the longitudinal bar (27a) for receiving an insert sheet, the suction channel (35) is connected to a vacuum source (31) for holding, by suction, the insert sheet transported by the movable carriage (12; 12). Also a blank-receiving station, a sheet-shaped element processing machine, and a method for transporting an insert sheet in a receiving area of a blank-receiving station are disclosed.

A printing press arrangement has a plurality of processing stations for processing sheets. The plurality of processing stations are arranged one after another in a transport direction of the sheets for in-line processing of the sheets. At least one of the processing stations is configured as a non-impact printing device. A transfer device, which is arranged upstream of the active region of the non-impact printing device, is provided for transferring the sheets from a first processing station, which is arranged upstream of the non-impact printing device, to the non-impact printing device. The transfer device aligns, in each case, at least one of the axial register and the circumferential register and the diagonal register of each of the sheets in register relative to the printing position of the non-impact printing device.

A conveyance mechanism includes a lower conveyance guide below an inclined conveyance path having upward or downward inclinations with which a sheet material is to be conveyed, that guides a lower surface of the sheet material; an upper conveyance guide above the inclined conveyance path, that guides an upper surface of the sheet-shaped material, the upper conveyance guide being openable and closable about a rotation shaft, which is on a side of the inclined conveyance path in a direction of a width of the inclined conveyance path to extend along the inclined conveyance path; and a first urging member to urge a portion of the upper conveyance guide away from the rotation shaft in the direction of the width of the inclined conveyance path toward the rotation shaft, the portion of the upper conveyance guide being at an upper end of the upper conveyance guide in an inclined direction.

A delivery system is used for delivering printed sheets which can be fed in a region of an inlet side of a delivery device. The delivery device includes at least one first discharge station and one second discharge station which is mounted downstream of the first discharge station, which is upstream in the transport path. The delivery stations are associated respectively with a format or transport-relevant device which can be controlled by a drive including a control element for adapting or correcting the guiding and delivery of the sheets in the relevant discharge station. At a delivery device level upstream of a lateral inlet in a stacking space of the upstream second discharge station, at least one operator interface, with at least one actuating device is provided. The at least one actuating device can be permanently connected to a signal or can be activated by an additional actuating device, with the control element of the at least one format- or transport-relevant device of the first discharge station and which allows or which can allow, during actuation, the control element of the system of the first discharge station which can vary with regard to the format- or transport-relevant size format, to be controlled.