A suction roll of a web, or sheet, of paper, includes a tubular body that rotates about a longitudinal rotation axis. External and internal lateral surfaces of the suction roll pneumatically communicate with each other through suction holes. The roll includes a suction chamber pneumatically connected to a vacuum generation device for generating a predetermined vacuum degree. A vacuum distribution device selectively puts into pneumatic communication the suction chamber with at least one row of suction holes, at determined angular positions of the tubular body and causes the processed sheet or web of paper to be sucked, and to adhere at a corresponding portion of the external lateral surface arranged between a catching point and a releasing point having determined angular positions. A displacement device moves the vacuum distribution device to change the angular position of the catching or releasing point of the web or sheet of paper.

The interfolding machine includes a first interfolding roller rotating around a first rotation axis and a second interfolding roller rotating around a second rotation axis parallel to the first rotation axis; wherein the first interfolding roller and the second interfolding roller form an interfolding nip therebetween. The interfolding machine further includes a first set of separation fingers associated with the first interfolding roller and arranged for reciprocatingly pivoting around a first pivoting axis parallel to the first rotation axis. The reciprocating pivoting movement of the first set of separation fingers is controlled by a first actuation mechanism including a first desmodromic cam. The interfolding machine also includes a second set of separation fingers associated with the second interfolding roller and arranged for reciprocatingly pivoting around a second pivoting axis parallel to the second rotation axis. The reciprocating pivoting movement of the second set of separation fingers is controlled by a second actuation mechanism including a second desmodromic.

A suction mechanism for suctioning a loop transporting belt a medium processed by a processing unit, a rotation mechanism for rotating the transporting belt, a stacker for stacking the medium transported by the transporting belt, and a change mechanism for changing a movable area are included. The rotation mechanism, after suctioning the medium to the transporting belt to rotate in a first rotation direction to transport the medium in a first transport direction, rotates the transporting belt in a second rotation direction to transport the medium in a second transport direction to stack the medium on a stacker. The change mechanism narrows a movable area when the medium is transported in the second transport direction compared to an area when the medium is transported in the first transport direction.

A resin film is released from a supporting substrate without using light irradiation, with ease, and without damaging the resin film or the like. Preparation for separating the supporting substrate on which the resin film is cohesively formed into a first part and a second part; and at least one of the first part and the second part is allowed or caused to move in a direction parallel to an one surface of the first part while the first part of the supporting substrate and at least an edge of the second part facing the first part being moved with respect to one another, while a close contact between the resin film and an one surface of the second part of the supporting substrate being maintained, such that the first part and the edge of the second part are separated along a perpendicular direction to the one surface of the first part.

A resin film is released from a supporting substrate without using light irradiation, with ease, and without damaging the resin film or the like. Preparation for separating the supporting substrate on which the resin film is cohesively formed into a first part and a second part; and at least one of the first part and the second part is allowed or caused to move in a direction parallel to an one surface of the first part while the first part of the supporting substrate and at least an edge of the second part facing the first part being moved with respect to one another, while a close contact between the resin film and an one surface of the second part of the supporting substrate being maintained, such that the first part and the edge of the second part are separated along a perpendicular direction to the one surface of the first part.

A protruding portion protruding in a rotation axis direction of an image bearing member is provided at a position between the tip of a separation claw and an apex of the separation claw, when the apex of the separation claw is disposed at a position farthest from the surface of the image bearing member in a direction perpendicular to a straight line connecting the tip and the rotation center of a shaft portion of the separation claw.

A protruding portion protruding in a rotation axis direction of an image bearing member is provided at a position between the tip of a separation claw and an apex of the separation claw, when the apex of the separation claw is disposed at a position farthest from the surface of the image bearing member in a direction perpendicular to a straight line connecting the tip and the rotation center of a shaft portion of the separation claw.

A medium transporting apparatus includes a transport belt that has a loop shaped, an clinging mechanism that causes a medium to cling to the transport belt, a rotation mechanism that rotates the transport belt in a first and second rotation direction, and an intermediate stacker on which the medium transported by the transport belt is stacked, in which the clinging mechanism cling an upper surface that is opposite to a lower surface of the medium on the intermediate stacker side, and after rotating the transport belt, to which the medium is cling, in the first rotation direction to transport the medium in a first transport direction, the rotation mechanism rotates the transport belt in the second rotation direction to transport the medium in a second transport direction that is opposite to the first transport direction so as to stack the medium on the intermediate stacker.

A medium transporting apparatus includes a transport belt that has a loop shaped, an clinging mechanism that causes a medium to cling to the transport belt, a rotation mechanism that rotates the transport belt in a first and second rotation direction, and an intermediate stacker on which the medium transported by the transport belt is stacked, in which the clinging mechanism cling an upper surface that is opposite to a lower surface of the medium on the intermediate stacker side, and after rotating the transport belt, to which the medium is cling, in the first rotation direction to transport the medium in a first transport direction, the rotation mechanism rotates the transport belt in the second rotation direction to transport the medium in a second transport direction that is opposite to the first transport direction so as to stack the medium on the intermediate stacker.

The invention relates to a sheet depositing arrangement. The sheet depositing arrangement comprises at least one sheet depositing apparatus having a sheet stacking chamber for creating a sheet stack, and a sheet extraction device which in turn has a sheet transporting means that is drivable in a direction of circulation, a sheet delivery region for delivering the sheets to be stacked to the sheet stacking chamber, a sheet stacking region, provided downstream of the sheet delivery region, for stacking the sheets to be stacked into the sheet stacking chamber, and a return region, provided downstream of the sheet stacking region. Furthermore, the sheet depositing apparatus has a sheet retaining device with at least one sheet retaining element, arranged adjacent to the sheet stacking region, for preventing at least one sheet to be stacked from being drawn into the sheet extraction device from the sheet stacking chamber by the sheet transporting means.