A printing platform includes a printing engine with one or more printheads arranged such that the ink drops are jetted vertically upwards against the action of gravity; and a substrate transportation system where the normal to the surface in contact with the substrate is parallel and with opposite direction to the travelling direction of the jetted ink drops. It is necessary to counteract the weight of the substrate during the printing process to avoid it from falling under the action of gravity. This is achieved through any of a mechanical element that interferes with the falling of the substrate and that keeps it in place; or a system that generates adhesion forces between the element that transmits the motion to the substrate, typically a conveyor belt, and the substrate through the action of electrostatic forces, an air pressure differential between both faces of the substrate, or any other suitable mechanism.

A printing device, a printing machine, and a box making machine are provided with printing cylinders on which printing plates can be mounted, ink supply rolls that are placed on the upstream or downstream sides of the printing cylinders in a sheet-conveying direction and that can be in contact with the printing cylinders, ink supply units that can supply ink to the ink supply rolls, first covers that cover the upper parts of the printing cylinders in the vertical direction and that can be opened and closed, and footholds that cover the vertically upper parts of the ink supply rolls and that can be operated by an operator.

The repositioning station (200) allows a continuous shingled stream (120) of overlapping semirigid planar articles (100) to be transported on an incoming conveyor (122) along a transport circuit (204) onto an outgoing conveyor (302) so as to form a stack that can be carried away upon the outgoing conveyor (302). The repositioning station (200) includes a lateral deviation assembly (210) and may also include a final positioning assembly (212). The transport circuit (204) within the lateral deviation assembly (210) follows a generally ellipsoidal deviation path to veer the shingled stream (120) and also to pivot the articles (100) therein about a curvilinear axis (206) from a facedown position to an upright position. The outgoing conveyor (302) can carry the cartons (100) in a direction that is parallel to that of the incoming conveyor (122).

The repositioning station (200) allows a continuous shingled stream (120) of overlapping semirigid planar articles (100) to be transported on an incoming conveyor (122) along a transport circuit (204) onto an outgoing conveyor (302) so as to form a stack that can be carried away upon the outgoing conveyor (302). The repositioning station (200) includes a lateral deviation assembly (210) and may also include a final positioning assembly (212). The transport circuit (204) within the lateral deviation assembly (210) follows a generally ellipsoidal deviation path to veer the shingled stream (120) and also to pivot the articles (100) therein about a curvilinear axis (206) from a facedown position to an upright position. The outgoing conveyor (302) can carry the cartons (100) in a direction that is parallel to that of the incoming conveyor (122).

The present invention relates to a transfer module (26) for a folder-gluer machine (1), the transfer module comprising a lower conveyor (36) and an upper conveyor (38) adapted to receive a folding box (2) therebetween and to transport the folding box in a direction of transportation (D) towards a downstream-located loading surface (90) in a stacker module. The upper conveyor (36) of the transfer module extends further in the direction of transportation than the lower conveyor (38) and the lower conveyor comprises a first conveyor belt (38a) and second conveyor belt (38b), each having an inlet end (67a, 67b) and an outlet end (65a, 65b), and wherein the outlet ends are displaceable in the direction of transportation.

The present invention relates to a transfer module (26) for a folder-gluer machine (1), the transfer module comprising a lower conveyor (36) and an upper conveyor (38) adapted to receive a folding box (2) therebetween and to transport the folding box in a direction of transportation (D) towards a downstream-located loading surface (90) in a stacker module. The upper conveyor (36) of the transfer module extends further in the direction of transportation than the lower conveyor (38) and the lower conveyor comprises a first conveyor belt (38a) and second conveyor belt (38b), each having an inlet end (67a, 67b) and an outlet end (65a, 65b), and wherein the outlet ends are displaceable in the direction of transportation.

A device for setting up containers along fold lines from flat blanks, having a forming station including a forming tool having a displaceable forming punch, and a backing device for setting up the containers from the blanks, and having a discharging device for carrying away the set-up containers from the forming station. The forming station is designed for folding a circumferential functional edge. The device is designed for turning the set-up containers after the forming station and for pushing the containers over preceding containers for forming a container stack having the container openings thereof facing forward.

A device for setting up containers along fold lines from flat blanks, having a forming station including a forming tool having a displaceable forming punch, and a backing device for setting up the containers from the blanks, and having a discharging device for carrying away the set-up containers from the forming station. The forming station is designed for folding a circumferential functional edge. The device is designed for turning the set-up containers after the forming station and for pushing the containers over preceding containers for forming a container stack having the container openings thereof facing forward.

In an apparatus (1) and a method for creasing and cutting sheets of material for packaging or display, or corrugated carton structure material such as cardboard or corrugated cardboard, a sheet S.sub.x to be processed is fed sequentially through an optical station (100), a creasing module (200) and a laser cutting module (300) for being sequentially creased and cut, and wherein the creasing and cutting status work profiles are input by a programming logic controller (PLC) by way of a Job Processor, and wherein the speeds of the conveyor belts that convey the sheets, are adjusted automatically by a processing unit based on parameters of the creasing and cutting operations.

In an apparatus (1) and a method for creasing and cutting sheets of material for packaging or display, or corrugated carton structure material such as cardboard or corrugated cardboard, a sheet S.sub.x to be processed is fed sequentially through an optical station (100), a creasing module (200) and a laser cutting module (300) for being sequentially creased and cut, and wherein the creasing and cutting status work profiles are input by a programming logic controller (PLC) by way of a Job Processor, and wherein the speeds of the conveyor belts that convey the sheets, are adjusted automatically by a processing unit based on parameters of the creasing and cutting operations.