A cardboard blank for folding a box has a length and a width, wherein in the length direction five adjacent sections of panels are present, each panel of the first, third and fifth section having a length (H.sub.B) corresponding to the height of the box to be folded, and each panel of the second and forth section having a length (L.sub.B) corresponding to the length of the box to be folded, in the width direction (W) three adjacent rows of panels are present, each panel of the second row having a width (W.sub.B) corresponding to the width of the box to be folded, and each panel of the first and the third row having a width (H.sub.B) corresponding to the height of the box to be folded, between adjacent panels in the length direction (L) crease lines are provided, between panels of the second, the third and the forth section which are adjacent to each other in the width direction (W), crease lines are provided, adjacent panels of the first section are separated from each other by incisions, in the fifth section only a panel in the second row is present, between the panels of the second and the forth section in the first and the third row, a respective joint panel is provided, each of which being divided in triangular sections by crease lines between diagonally opposing corners of the each joint panel, the outer triangle being cut away.

A food container includes a bottom panel and sidewalls pivotally connected to the bottom panel. A lid is pivotally connected to at least one sidewall to open and close the food container. A divider panel having at least one slot is inserted into any one of a plurality of slots in a spacer panel to create an adjustable compartment arrangement inside an internal cavity of the food container. The divider panel includes a groove that provides a recess between the divider panel and a sidewall of the food container that can accommodate a lip of the lid.

A corrugated plastic box and a method for manufacturing a corrugated plastic box from a blank are provided. The method includes the steps of forming rounded edge seals on the perimeter edges of the blank, pre-sealing portions of the blank to form a plurality of areas in which major and minor flap slots and a glue tab are desired, ultrasonically scoring the blank to form a plurality of flap score lines, and cutting the blank through the plurality of pre-sealed flap slots and glue tab, leaving a sealed edge.

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

A foldable clamshell container is provided. The container may include a tray portion and a cover portion. The tray portion may include a front panel, rear panel, and side panels. The side panels may include triangular fold flaps on each end that are secured end flaps connected to the front and rear panels. The rear panel may have a height greater than the front and side panels and the cover portion may be foldably connected to an upper edge of the rear panel. The cover panel may include a cover panel, a front panel, and cover side panels with a triangular fold flap. The rear end flaps of the tray portion and the cover side panels may each include a curved edge portion. The container may be configured to transition between a folded-flattened configuration and an unfolded configuration by folding the triangular fold flaps of the tray and cover portions.

A foldable carton is provided. The carton includes a bottom panel, a front panel, a rear panel, end panels, each foldably connected to the edges of the bottom panel. The carton further includes front end flap panels connected to the lateral ends of the front panel and rear end flap panels connected to the lateral ends of the rear panel. Each front end flap panel includes a connecting end section and a triangular fold flap connected to the connected end section. The triangular fold flap is connected to a side edge of the adjacent end panel by a hinged fold line. The connecting end section is secured to the front panel in an overlying arrangement and the triangular fold flap is configured to about the hinged fold line to allow the front panel to freely move between a fully upright position and a partially upright position.

The invention relates to a container precursor comprising a sheetlike composite, wherein the sheetlike composite a) comprises a layer sequence comprising, as mutually superposed layers, from an inner face of the sheetlike composite to an outer face of the sheetlike composite, i) an inner polymer layer, ii) a barrier layer, and iii) a carrier layer; b) comprises a first longitudinal edge and a further longitudinal edge, wherein the first longitudinal edge is bonded to the further longitudinal edge forming a longitudinal seam of the container precursor; c) comprises, in the following sequence in the direction from the first longitudinal edge to the further longitudinal edge i) a first longitudinal groove, ii) a second longitudinal groove, iii) a third longitudinal groove, and iv) a fourth longitudinal groove, wherein the container precursor can be shaped to form a jacket structure by folding along the first longitudinal groove, the second longitudinal groove, the third longitudinal groove and the fourth longitudinal groove; wherein the container precursor is characterized by a shaping coefficient as per the test method described herein within a range from 8 to 30 m2/g. The invention further relates to a closed container, to a method, to an apparatus and to the use of the container precursor.

The invention relates to a container precursor comprising a sheetlike composite, wherein the sheetlike composite a) comprises a layer sequence comprising, as mutually superposed layers, from an inner face of the sheetlike composite to an outer face of the sheetlike composite, i) an inner polymer layer, ii) a barrier layer, and iii) a carrier layer; b) comprises a first longitudinal edge and a further longitudinal edge, wherein the first longitudinal edge is bonded to the further longitudinal edge forming a longitudinal seam of the container precursor; c) comprises, in the following sequence in the direction from the first longitudinal edge to the further longitudinal edge i) a first longitudinal groove, ii) a second longitudinal groove, iii) a third longitudinal groove, and iv) a fourth longitudinal groove, wherein the container precursor can be shaped to form a jacket structure by folding along the first longitudinal groove, the second longitudinal groove, the third longitudinal groove and the fourth longitudinal groove; wherein the container precursor is characterized by a shaping coefficient as per the test method described herein within a range from 8 to 30 m2/g. The invention further relates to a closed container, to a method, to an apparatus and to the use of the container precursor.

A pet toy, in combination, including a containment structure having a longitudinal axis and cross section defining an interior volume. The containment structure, which is preferably collapsible, includes a plurality of containment openings along its longitudinal axis exposing the interior volume to a pet during use of the pet toy, and an electronic component in the form of a hollow shell having a shell opening configured therein. A motor having a rotatable shaft extends toward the opening. A power supply for powering the motor and optional microprocessor, the motor, microprocessor and power supply being supported within the interior of the hollow shell. An attractant is affixed to the rotatable shaft and extends through the shell opening, the microprocessor being programmed to control operation of the motor to cause the attractant to rotate intermittently, the electronic component and attractant being visible to a pet during use of the pet toy.

A pet toy, in combination, including a containment structure having a longitudinal axis and cross section defining an interior volume. The containment structure, which is preferably collapsible, includes a plurality of containment openings along its longitudinal axis exposing the interior volume to a pet during use of the pet toy, and an electronic component in the form of a hollow shell having a shell opening configured therein. A motor having a rotatable shaft extends toward the opening. A power supply for powering the motor and optional microprocessor, the motor, microprocessor and power supply being supported within the interior of the hollow shell. An attractant is affixed to the rotatable shaft and extends through the shell opening, the microprocessor being programmed to control operation of the motor to cause the attractant to rotate intermittently, the electronic component and attractant being visible to a pet during use of the pet toy.