In erecting a carton from a knock-down carton blank, the blank is placed on a base of a bed of a shuttle such that a bottom side panel of the blank abuts the base. The bottom side panel of the blank is then gripped with a gripper of the base and a top side panel of the blank is raised while advancing the shuttle in a horizontal direction so as to open said knock-down carton blank into a carton sleeve.

A system is claimed for forming a container from a tubular blank comprising a plurality of panels and flaps interconnected to provide a generally flattened tubular configuration. A first and second panels are provided with the second panel being rotatable relative to the first panel. The system may comprise a first engagement device for engaging the first panel and a second engagement device for engaging the second panel, and being located on a panel rotating apparatus operable to rotate the second panel from an orientation generally parallel to the first panel to a second orientation at an angle to the first panel. The generally flattened tubular blank may be reconfigured from a generally flattened configuration to an open configuration.

In erecting a carton from a knock-down carton blank, the blank is placed on a base of a bed of a shuttle such that a bottom side panel of the blank abuts the base. The bottom side panel of the blank is then gripped with a gripper of the base and a top side panel of the blank is raised while advancing the shuttle in a horizontal direction so as to open said knock-down carton blank into a carton sleeve.

A box erecting machine includes a transport mechanism that can move an un-erected box from an entry portion of the box erecting machine to a forward portion of the box erecting machine. The transport mechanism can include pivot arm(s) and clamp(s) for securing and moving the un-erected box. The machine can also include a box erecting assembly that erects the un-erected box. The box erecting assembly can include an opening or unfolding mechanism that opens or unfolds the un-erected box into a generally rectangular tube. The machine can also include a folding mechanism and a closure mechanism for folding and securing the bottom flaps of the box.

Techniques for corrugate and chipboard knocked-down case inspection and manufacturing are described. In an example, a piece of cardboard is cut according to a shape of a knocked-down case, and a first plurality of measurements are made. The piece of cut cardboard is scored to create a plurality of fold-lines, based at least in part on the first plurality of measurements, and a second plurality of measurements are made. A fold-line between a major panel and a minor panel is folded, based at least in part on the second plurality of measurements, and a third plurality of measurements are made. A fold-line of a tab of the piece of cut cardboard is folded, based at least in part on the third plurality of measured distances. The tab is glued to a panel of the piece of cardboard to form a knocked-down case.

An automated case erector for erecting a one-piece insulating container and a method of automated case erecting are provided. The automated erector includes a case blank feeder for sequentially feeding a series of flat case blanks onto a conveyor, an insulation securing station for securing insulating members to the case blank, and a case erecting assembly for forming the combination of case blanks and insulating members secured thereto into a fully erected, three-dimensional container by simultaneously folding the combination of case blanks and insulating members.

Systems and methods for processing a sheet having a printed underside. A gap between a feeder and a processing machine provides visibility to the printed underside, cameras capture images of the printed graphics through the gap, and a processor stitches the captured images together into a continuous image of the printed underside, including registration marks, corners or edges, and a sheet identifier. Processing instructions are retrieved from storage using the detected sheet identifier and are executed along processing paths calculated from detected information regarding locations of the registration marks and the corners or edges. A material guide positioned above the material path may be configured to constrain the sheet vertically as it passes over the gap and to reduce overhead light from interfering with the image capture.

A thermoform packaging machine comprising a forming station. The forming station comprises at least one forming tool lower part, the forming tool lower part may be movable transversely to an operating direction of the thermoform packaging machine. The forming tool lower part may comprise at least one reception unit with one or a plurality of troughs for receiving cardboard elements. At a forming position the forming tool lower parts are in contact with the forming tool upper parts such that the first film web may be formed-in into the forming tool lower parts. Further, the first film web may be formed-in into the cardboard elements during the forming process and, in the case of a skin film, an adhering or an adhesive connection may be established between the skin film and the inner surfaces of the cardboard elements.

The invention relates to a device (410; 410′) for driving a stamping foil over a path through a stamping machine, the driving device (410; 410′) comprising two foil-introduction chain-like elements (420a, 420b) and a drive member (440) coupled to the foil-introduction chain-like elements (420a, 420b) for driving the foil-introduction chain-like elements (420a, 420b) notably through a platen press (310) of the stamping machine (1), characterized in that it further comprises at least one first load-measurement device (3a; 3a′) comprising a first detector (7a) configured to measure a parameter indicative of the load applied by the drive member (440) for driving the foil-introduction chain-like elements (420a, 420b) in a first direction, the at least one first load-measurement device (3a; 3a′) being connected to a stamping-machine (1) control unit (4) configured to stop the driving by the drive member (440) when the parameter indicative of the load applied by the drive member (440) and measured by the first detector (7a) crosses a threshold.

The present invention also relates to a stamping station and machine comprising the driving device. The present invention also relates to a method for controlling the driving of a stamping foil.

In erecting a carton from a knock-down carton blank, the blank is placed on a base of a bed of a shuttle such that a bottom side panel of the blank abuts the base. The bottom side panel of the blank is then gripped with a gripper of the base and a top side panel of the blank is raised while advancing the shuttle in a horizontal direction so as to open said knock-down carton blank into a carton sleeve.