A buffer means includes a buffer unit that makes paper sheets temporarily stand by and a paper stacking unit that intermittently conveys paper sheets and sucks the trailing edges of the paper sheets to stack the paper sheets stepwise and make them temporarily stand by.

A corrugated paperboard sheet feeding apparatus comprises: a plurality of sheet feeding rollers; a grate formed with a plurality of opening portions for receiving the sheet feeding rollers and configured to switch between contact and non-contact states of the corrugated paperboard sheet with respect to the sheet feeding rollers; and a suction box configured to suck the corrugated paperboard sheet downwardly by gaps between the sheet feeding rollers and the opening portions, wherein each of the gaps is formed to be 10 mm or less, and wherein the apparatus further comprises a mat switch for detecting an entry of a person into an area in a sheet feeding section, and a control device for stopping movement of the sheet feeding rollers and/or the grate when the mat switch is turned on.

A feeding device includes a plurality of suction units, disposed above a conveyed medium stacked on a stacker, to attract the conveyed medium. At least one of the plurality of suction units includes a rotary fan including a board and a plurality of walls extending from the board; and a driver to rotate the rotary fan. The at least one of the plurality of suction units generates a vortex air with a side of the board with the plurality of walls directed to the conveyed medium. The at least one of the plurality of suction units being a suction unit generates a vortex air.

The invention relates to a method for automatically splicing a first article, unwound from a first reel, to a second article wound around a second reel, the articles being flexible and in the form of webs or strips. According to the invention, the method comprises steps consisting in: positioning an adhesive tape on an end that is to be spliced belonging to the second article; automatically moving a portion of the first article to a cutting plane situated facing the end that is to be spliced belonging to the second article; holding the portion of the first article downstream of the cutting plane with respect to the first reel; cutting the first article transversely; automatically moving the end that is to be spliced belonging to the second article as far as the cutting plane; and pressing a cut end of the first article at the cutting plane against the end that is to be spliced belonging to the second article in order to stick them together using the adhesive tape.

A corrugated paperboard sheet feeding apparatus comprises: a plurality of sheet feeding rollers; a grate formed with a plurality of opening portions for receiving the sheet feeding rollers and configured to switch between contact and non-contact states of the corrugated paperboard sheet with respect to the sheet feeding rollers; and a suction box configured to suck the corrugated paperboard sheet downwardly by gaps between the sheet feeding rollers and the opening portions, wherein each of the gaps is formed to be 10 mm or less, and wherein the apparatus further comprises a mat switch for detecting an entry of a person into an area in a sheet feeding section, and a control device for stopping movement of the sheet feeding rollers and/or the grate when the mat switch is turned on.

A corrugated box making machine has a vacuum transfer mechanism for moving corrugated boards along a path of conveyance including stations having printing and die cutter mechanisms which operate on the boards. The printing mechanisms include a print and impression cylinder, the latter being mounted in a vacuum housing that also holds drive rolls for moving the boards along the path during which the boards are held against the rolls by vacuum in the housing. The latter is movable substantially above the print cylinder to provide convenient access for maintenance of the print cylinder or replacement of its printing plates.

Examples include a processing machine for processing a substrate. At least one alignment segment is arranged before at least one processing unit of the processing machine. The at least one alignment segment includes a plurality of transport sections following one another in the transport direction. The at least one alignment segment includes a dedicated drive for axially adjusting at least one of the transport section. The at least one transport section includes at least one first transport sub-section and at least one second transport sub-section in the transverse direction. The first transport sub-section and the second transport sub-section are drivable relative to one another at differing speeds in the circumferential direction. The alignment segment includes a transport section that includes the dedicated drive for axially adjusting the transport section and the transport sub-sections that can be driven relative to one another at differing speeds.

Examples include activating at least one alignment segment of a processing machine. The at least one alignment segment is arranged before at least one processing unit of the processing machine that is activated. The at least one alignment segment includes a plurality of transport sections following one another in the transport direction. At least two transport sections, following one another in the transport direction, each have a basic position and at least one adjustment position. The at least one adjustment position in each case is offset relative to the basic position in the transverse direction. At least one transport section of the transport sections is axially adjusted. At least one dedicated drive axially adjusts the at least one transport section of the transport sections, and the at least one dedicated drive is designed as a direct drive.