A method for erecting a box includes positioning an unerected box in an automated erecting apparatus. The method further includes bending major and minor flaps on the unerected box relative to sides of the unerected box. The method further includes, while the major and minor flaps are bent relative to the sides of the unerected box, performing an automated opening operation on the unerected box, wherein the unerected box comprises a stacking fold.

A method for erecting a box includes positioning an unerected box in an automated erecting apparatus. The method further includes bending major and minor flaps on the unerected box relative to sides of the unerected box. The method further includes, while the major and minor flaps are bent relative to the sides of the unerected box, performing an automated opening operation on the unerected box, wherein the unerected box comprises a stacking fold.

A device for shaping the gable surfaces of packages with a slanted gable is shown and described, including: a conveyor system with cells fixed to it to receive the packages, at least one gable folder to fold a fin seam in the gable region of the packages and at least two ear folders to fold ears in the gable region of the packages. In order to enable rapid and reliable shaping of the gable even in packages with slanted gables, it is proposed that both the gable folder and the ear folders be mounted movably relative to the conveyor system and the packages to be transported therewith. A method for shaping the gable surfaces of packages with a slanted gable is also shown and described.

A modular case system and method of use provide for a case former having a base, interchangeable case gages and forming heads. Contained within the interior of the base are slide blocks mounted on slide rails and assemblies in such a manner as to allow the slide blocks to be slidingly reconfigured to form a case forming cavity of varicose sizes and shapes. The size and shape of the case forming cavity is established and maintained by a template opening, defined by, and potentially unique to, each case gage. The size and shape of the forming head corresponds to the size and shape of the template opening. The slide blocks are secured to the case gage by removable locking pins.

A customizable case former and it system and method of use provide for a case former having a base, interchangeable case gages and forming heads. Contained within the interior of the base are slide blocks mounted on slide rails and assemblies in such a manner as to allow the slide blocks to be slidingly reconfigured to form a case forming cavity of varicose sizes and shapes. The size and shape of the case forming cavity is established and maintained by a template opening, defined by, and potentially unique to, each case gage. The size and shape of the forming head corresponds to the size and shape of the template opening. The slide blocks are secured to the case gage by removable locking pins.

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.

A customizable case former and it system and method of use provide for a case former having a base, interchangeable case gages and forming heads. Contained within the interior of the base are slide blocks mounted on slide rails and assemblies in such a manner as to allow the slide blocks to be slidingly reconfigured to form a case forming cavity of varicose sizes and shapes. The size and shape of the case forming cavity is established and maintained by a template opening, defined by, and potentially unique to, each case gage. The size and shape of the forming head corresponds to the size and shape of the template opening. The slide blocks are secured to the case gage by removable locking pins.

An automatic carton forming device includes a supporting table, a storage rack, a limiting part, a transporting part, and a folding part. The storage rack is configured to store folded paper boards, the limiting part is configured to limit the folded paper boards, the transporting part includes a moving base and a driving unit for driving the moving base to move. At least one first vacuum suction cup is disposed on the moving base, the limiting part includes an adsorbing base disposed on one end of the supporting table, at least one second vacuum suction cup is disposed on the adsorbing base. The folding part includes a first overturning plate, a vertical folding unit, a transverse folding unit, and a transmitting unit, and the transmitting unit drives the first overturning plate, the vertical folding unit, and the transverse folding unit to perform folding action.

An automatic carton forming device includes a supporting table, a storage rack, a limiting part, a transporting part, and a folding part. The storage rack is configured to store folded paper boards, the limiting part is configured to limit the folded paper boards, the transporting part includes a moving base and a driving unit for driving the moving base to move. At least one first vacuum suction cup is disposed on the moving base, the limiting part includes an adsorbing base disposed on one end of the supporting table, at least one second vacuum suction cup is disposed on the adsorbing base. The folding part includes a first overturning plate, a vertical folding unit, a transverse folding unit, and a transmitting unit, and the transmitting unit drives the first overturning plate, the vertical folding unit, and the transverse folding unit to perform folding action.

A container includes a plurality of panels connected together at fold lines configured for extending at least partially around an interior space. The panels include a front panel, a first side panel, a back panel and a second side panel. The back panel includes a first back portion and a second back portion. At least one of the first back portion or the second back portion is free from openings. A shelf panel is foldably connected to the front panel. The first back portion is adhered to the shelf panel.