A stack of laminar material for forming packages, the stack including full panels having a predetermined total length and formed with transverse creases along which the full panels are folded in accordion-like pleats. The stack includes at least one longitudinal cut on each full panel to form at least two transversely adjacent stacks of partial panels having respective partial widths, which are less than the total width. The at least one cut is incomplete, so that each partial panel of a respective stack and the partial panel of the stack adjacent thereto will have at least one connecting section therebetween, having a predetermined minimum length, for holding the partial panels of the adjacent stacks together, to thereby keep the adjacent stacks substantially aligned while facilitating the separation of each of the partial panels as they are unwound by a pulling action from each adjacent stack.

In a method of handling a tubular carton blank, one side of an erected tubular carton blank is gripped with a gripper mounted to a pivot such that a fold line of a flap of the one side is aligned with an axis of rotation of the pivot. The gripper, and thereby the erected tubular carton blank, is then pivoted about the pivot. The flap is brought into abutting relation with an abutment during the pivoting so that the flap is progressively folded about the fold line by the abutment during the pivoting.

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.

A packaging box, cutouts, method and device for producing corrugated cardboard boxes comprising walls, a base (6) and a cover (7), the inner face of the base being provided with at least two recesses (33) and the cover comprising at least two tabs (38) adhered to the upper face thereof, directly above the recesses of complementary shape. The recesses and/or the tabs are situated fully inside the corresponding face or faces (31, 32).

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.

A carton forming machine includes a carton blank push up device that receives a substantially horizontal folded carton blank and reorients the folded carton blank from the substantially horizontal orientation to an upright orientation below and in a first direction alignment with a carton opening mechanism. A carton blank positioning apparatus shifts the upright folded carton blank in a second direction, transverse to the first direction, below the carton opening mechanism to define a second direction position of the upright carton blank below the carton opening mechanism before the carton opening mechanism engages the upright carton blank for opening of the upright carton blank.

The object of the disclosure is a method and an apparatus for forming a package box. In the first phase of the method, a box blank is placed at the start of the box-forming process and is brought to the conveying motion. In the next phase, the markings of the package boxes are formed. In the third phase, the box blank is folded around an inner support and its ends are fastened together into one tubular blank component. In the fourth phase, a base panel is affixed to the box frames. In a fifth phase, the package boxes are transferred for further processing according to the order. The different phases of the method also comprise at least the following actions to be taken on the basis of online data coming from the picking system: In the first phase, a box blank is selected, which forms a box frame for one or more package boxes, the width of which box frame corresponds most suitably to the online data; or a box blank is cut to the correct width according to online data. In the next phase, the necessary fold lines are formed in the box blank on the basis of online data and the necessary markings are made on each box frame to be formed from a box blank. In the third phase, the box blank is cut by means of the cutting device on the basis of online data into box frames of the height of the package boxes to be formed.

The object of the disclosure is a method and an apparatus for mechanically forming a product package box. According to the disclosure, a product package box is formed with a box-forming apparatus from a tubular sleeve folded flat, which sleeve is mechanically opened into the correct shape of the product package box and to which is affixed an essentially integral base panel. On the basis of online data coming from a picking system, for each product package box, a sleeve is selected from a sleeve bundle, the height of which sleeve corresponds most suitably to the online data, or a sleeve of suitable height is cut from a sleeve blank.

A cartoning machine including a carton supply station (e.g., a rotary carton supply station, a linear carton supply station, a non-linear carton supply station, or the like) and a handling station operatively coupled to the carton supply station. The carton supply station provides, on a selective basis, cartons, such as carton blanks, pre-formed cartons, or the like. The carton supply station of the cartoning machine provides for movement of magazines with respect to a robot in the handling station that may have a distal end secured in a stationary and fixed location. As such, different magazines with dissimilar cartons may be moved to a picking location adjacent the robot, as dissimilar cartons are required. Further, the cartons within the magazines may be moved to a pre-determined pick-up location such that the robot is repeatably picking a carton from the pre-determine pick-up location.

A personalized packaging production system includes an in-feed tray, an out-feed tray, a cutting table disposed intermediate the in-feed tray and the out-feed tray and an interchangeable cutting/creasing assembly. A sheet feeder is positioned between the in-feed tray and the cutting table to feed media sheets from the in-feed tray to the cutting table, and an exit nip is positioned between the out-feed tray and the cutting table to remove media sheets from the cutting table to the out-feed tray.