An apparatus for forming an upper edge of a paperboard container includes a pocket including a shell having a cavity with a mouth configured to receive the container along an axis such that the rim extends beyond the mouth. A workstation includes a forming member having a first forming surface which is actuatable toward the axis from a retracted position spaced from the rim to an extended position lying adjacent an upper end of the rim, and a forming segment having a second forming surface which is actuatable along the axis and the forming member in response to axial movement thereof such that the second forming surface is positioned spaced from a lower end of the rim. The second forming surface is actuatable along the axis towards the first forming surface to form the rim therebetween.

The composite structure includes a fiber-containing layer, such as a fiberboard layer or other layer having fibers from natural and/or synthetic sources, and a mineral-containing layer covering the fiber-containing layer. The fiber-containing layer and mineral-containing layer can be shaped, sized and manufactured such that the composite structure formed therefrom is capable of being machined to form a storage article. The composite structure has advantages in that it can improve whiteness, opacity, ink adhesion, materials reduction, barrier properties, recyclability, and printability. The composite can reduce polymer mass requirements for heat seal, barrier, and fiber adhesion. Further improvements include economics, pliability, and flexibility that is increased over the pliability of the fiber-containing layer alone.

A device for processing workpiece sheets for packaging, includes a processing station through which the workpiece sheets are transported in succession, at least one changeable tool (2, 10, 18) that is specific to the processing and is moved against the sheet introduced in the processing station to process the sheet, at least one holder (11) on the device side for the changeable tool (2, 10, 18), the holder being adjustable for aligning the changeable tool (2, 10, 18), a central electronic control unit (37) for controlling the device, the control unit (37) having a memory for storing specific setting position data for each individual specific changeable tool (2, 10, 18), electronic digital sensors (36) for determining the current position of the holder (11), which sensors are coupled to the control unit (37), and digital display devices (38) that are coupled to the control unit (37) and display the target position and the actual position of the holder (11) or of parts coupled thereto, or display the relation of the target position and the actual position for the individual specific changeable tool (2, 10, 18).

A method to form cardboard boxes by gluing into a box-forming machine from sheets, said machine, a computer program with instructions for said machine to execute said method, and a computer-readable device that has stored said computer program. In this method, a stage of the movement of inserting a pintle into a mold starts with a controlling element when the position of a drag element of sheet to a delivery position, where you place a sheet aligned between said pintle and mold, it corresponds to a second intermediate position between a source position and said delivery position; and a stage of activation of a supplying actuator starts with a controlling element to supply a sheet subsequent to the source position, when the position of said drag element corresponds to a third intermediate position between said source position and said second position.

A system and method for forming knock-down blanks from die-cut flat blanks used for forming shipping cartons or cases, comprising positioning a flat blank in a forming device, wherein the flat blank has four panels each with a middle portion, a top flap hingeably connected to the middle portion and a bottom flap hingeably connected to the middle portion, wherein the fourth panel has a tab formed on the outer edge of its middle portion, wherein the forming device includes a first mechanically operated arm and a second mechanically operated arm, wherein the first arm contacts the first panel, and wherein the second arm contacts the fourth panel; applying adhesive to the tab; and using the first and second arms to fold the first and fourth panels 180° inward, wherein the adhesive on the tab joins the first and fourth panels together.

The invention is directed to straight, consistent body scores on plastic corrugated boxes and a process for making the body scores.

A system and method for forming knock-down blanks from die-cut flat blanks used for forming shipping cartons or cases, comprising positioning a flat blank in a forming device, wherein the flat blank has four panels each with a middle portion, a top flap hingeably connected to the middle portion and a bottom flap hingeably connected to the middle portion, wherein the fourth panel has a tab formed on the outer edge of its middle portion, wherein the forming device includes a first mechanically operated arm and a second mechanically operated arm, wherein the first arm contacts the first panel, and wherein the second arm contacts the fourth panel; applying adhesive to the tab; and using the first and second arms to fold the first and fourth panels 180° inward, wherein the adhesive on the tab joins the first and fourth panels together.

A leakproof and liquid-tight packaging box of corrugated board, which box is erected mechanically using glueing as an aid. What is essential in the invention is that the corner surfaces of the structurally strong, torsionally rigid, leakproof and liquid-tight packaging box stackable one on top of another are folded and glued to the outer surface of the vertical surface of the short side. In addition, it comprises an inward-formed cone structure of the vertical surface of the long side of the box, and a rigid and load-resistant beam structure is formed on all sides of the packaging box.

A folded 3D shaped packaging product (30) is folded at at least one crease (22A, 22B, 22C, 22D, 22E) constituting a folding line in a 3D shaped product (20) formed by hot pressing of an air-laid blank (10) comprising natural fibers at a concentration of at least 70% by weight of the air-laid blank (10) and a thermoplastic polymer binder at a concentration selected within an interval of from 4 up to 30% by weight of the air-laid blank (10). The folded 3D shaped packaging product (30) is useful for cushioning and/or thermal insulation of packaged goods and can protect multiple sides of the packaged goods.

A blank has an upper surface and a reverse surface. The upper surface is printed in a conventional manner and includes outer side panels and inner side panels. Attachment regions are provided on the inner side panels of the outer surface, and corresponding attachment regions are provided on the outer side panels of the reverse surface. During assembly the respective attachment regions are arranged to face one another and an adhesive is provided therebetween. In the present method, the attachment regions of the upper surface initially have a surface tension in the range from around 34 dynes/cm to 60 dynes/cm before the upper surface is printed. The attachment regions are treated in order to maintain a surface tension in the desired range of 34 dynes/cm to 60 dynes/cm, following printing and before any adhesive is applied. This is achieved by applying an auxiliary printing medium to the attachment regions.