A rotary-tool mandrel for a unit for converting a flat substrate, on which a sleeve (13) is intended to be fitted, the mandrel includes a cylindrical core (14), a peripheral wall (17) that is able to take up a rest position and a locking position by exerting a radial pressure on the sleeve (13) in order to lock it in position on the mandrel (12), a pressure fluid circuit (21) provided between the peripheral wall (17) and the cylindrical core (14) for exerting the radial pressure on the sleeve (13), and a cooling fluid circuit (24) for allowing a fluid to flow in the region of the cylindrical core (14) and for cooling the mandrel (12).

A pressed crease-forming member includes a strip-shaped member having a crease-forming portion formed with three or a larger-than-three odd number of ribs extending in the longitudinal direction of the strip-shaped member with one of the ribs located at the widthwise center of the crease-forming portion and each half of the remaining even number of ribs arranged on either side of the center rib. At least the top of the center rib, namely, the rib located at the widthwise center of the crease-forming portion, is chamfered. Grooves are formed between the adjacent ribs. The ribs are arranged such that the tops of the ribs are formed, as a whole, into a convex shape. The bottom of each groove is recessed beyond the tops of the ribs on both sides of the groove.

A carton defines a bottom wall, a first side wall coupled to the bottom wall, a second side wall disposed opposite the first side wall and coupled to the bottom wall, a first end wall coupled to both the bottom wall and first and second side walls, and a second end wall disposed opposite the first end wall and coupled to both the bottom wall and the first and second side walls. The carton is formed from a blank having a first side and a second side disposed opposite said first side. The first side defines the interior surface of the bottom wall and the interior and exterior surfaces of the first and second side walls and the first and second end walls.

A container with a non-heat-seal window and a process for fabricating a low surface energy container with a non-heat-seal window. The process comprises forming a container template and cutting an opening in the container template. A window comprising a window stock material, a releasable liner, and an adhesive positioned between the window stock material and the releasable liner is sized to overlap the opening. A portion of the adhesive is exposed and the window is positioned over the opening. The window is then secured to the container template over the opening without the need to apply heat, and the container template is folded into the low surface energy container with the window.

The invention relates to a method for folding a corrugated cardboard blank (1) intended to form a folded box, the method comprising the following series of steps: i) supplying a blank (1) comprising at least one longitudinal crease (11); ii) applying a liquid to the longitudinal crease (11) so as to make the corrugated cardboard more flexible at the location of the longitudinal crease (11), the application being performed by means of a liquid application arrangement (130) comprising a liquid-ejection nozzle (134) provided with a liquid outlet; iii) folding the blank (1) around the longitudinal crease (11); wherein an aspiration of liquid is produced inside an aspiration compartment (163) of the liquid application arrangement (130) during step ii). The aspiration making it possible to remove any excess liquid which might not have been absorbed by the cardboard and/or the cardboard dust produced.

A system for creating custom-sized cardboard blanks for folding packagings comprises a first and at least a second supply for fanfold cardboard, a control unit (e.g., microprocessor) that calculates, based on order information regarding the desired minimum dimensions of a current packaging, under predefined optimization criteria a first blank layout for folding the packaging, said blank layout comprising a leading edge and an ending edge and transverse and longitudinal crease lines dividing the blank having a desired length and width into panels, defines, based on predefined criteria, areas around the transverse crease lines and the leading and ending edges, in which no transverse folds from fanfolding the cardboard should be present, sensors communicatively coupled with said control unit that sense information indicative of a presence of transverse folds in cardboard, a cutter to cut-off the piece of cardboard from the first or the second web and form the desired blank.

A tray made from cardboard sheet material comprising a rectangular bottom and a ring of side walls, i.e., two first opposing side walls, referred to as first walls, at least one of the first walls being connected on either side by first fold lines to end flaps referred to as first flaps, which may or may not themselves be connected respectively at the top part of same to a second flap by a second fold line, and two second opposing side walls, referred to as second walls. The second walls each comprise a rectangular central panel of which the length is less than the length of the bottom, the panel being connected, at each of the lateral ends of same, by a third fold line to a reinforcing member forming a pillar folded and glued to the central panel, and/or to the first flap of the adjacent first wall, i.e., a first reinforcing element located entirely separated from the adjacent first wall, and a second reinforcing element.

A foldable container moveable between a stowed configuration and a deployed configuration defining an interior area for holding bulk material is provided. The container includes opposed side panels and a bottom flap extending from a bottom edge of each side panel. A tab member extends from a distal end of each bottom flap and a tab finger extends from each tab member so as to define a hook at a distal end of each bottom flap. The hooks are interconnected so as to hingedly connect the distal ends of the bottom flaps together, thereby causing the bottom flaps to rotate between their respective stowed and deployed configuration positions as the end panels are translated between their respective stowed and deployed configuration positions. Locking tabs extending from distal ends of end flaps extend into the interior area of the container to secure the container in the deployed configuration.

By the method, a case having four sidewalls and at least four flaps at the bottom of the case is erected from a blank in a number of steps. The automated case erecting unit for use in erecting case blanks comprises a supporting device (9) and a picking and handling device (2), said picking and handling device being a robot with a robotic arm, wherein said robotic arm comprising a picking member (3) with a first leg and a second leg, which are placed perpendicularly and are locked in relation to each other, each leg comprising gripping means for picking up case blanks.

The package includes a front panel, a back panel opposing the front panel, the back panel defining at least one first cut line in a semi-circular shape at an upper portion of the back panel, a bottom panel forming a lower end of the package, a first side panel forming a first side of the package, a second side panel forming a second side of the package, and an upper panel forming a top end of the package. The first cut line is configured to form a tear line on an outermost surface of the package, the tear line being configured to be torn to open the top end of the package. The blank is capable of being assembled into the package. The method includes providing a blank, and assembling the package from the blank.