The invention relates to a polygonal container comprising a tubular polygonal body (10) with an even number of flat faces (11) numbering more than four, which is formed by a strip of corrugated cardboard (19) rolled up at least two full turns and adhered to itself by means of lines of glue (30) transverse to the channels of the corrugated cardboard, forming a multilayer wall (13); a base body (20) defined by a base panel of cut and folded stiff double-faced corrugated cardboard (24) attached around an end portion of the tubular polygonal body (10). The method comprises forming the tubular polygonal body by means of rolling the strip of corrugated cardboard around a polygonal rotary drum (51) and subsequently attaching to a base body (20).

An environmentally-friendly cup and method of making the same are provided. The environmentally-friendly cup includes a cup body and a cup base. The cup body is formed by curling a paper material that has a first and a second portion. The second portion has a first and a second straight side. The first portion is connected to the first straight side of the second portion and is curled into a straw. The straw is adhesively bonded to the second straight side of the second portion such that the second portion is curled into a tubular wall with a top opening and a bottom opening. The top end of the straw juts out of the top opening. The straw is directly formed on the cup body and therefore can be easily carried as an integral part of the environmentally-friendly cup without getting lost.

An assembly system for wrapping an outer wrapper to an inner sleeve to form an outer wall of a double-wall container can include a suction arm. The suction arm can be configured to couple to a suction source and can have a portion defining a suction surface. At least one suction opening can be provided within the suction surface and fluidly coupled to the suction source. A sealing edge can circumscribe at least a portion of the suction surface.

A squeeze tube includes a fluid-discharge container and a fluid-discharge closure mated to the fluid-storage container. The fluid-discharge closure is coupled to one end of the fluid-storage container and configured to discharge selectively fluid stored in a product-storage region formed in the fluid-storage container.

A container is formed to include and interior region that is configured to receive a product therein and the container is insulated.

A box formed from a plastic corrugated material with soft score lines is provided. The soft score lines are formed to enable the top flaps of the box to lay substantially flat against the outer surface of the box when folded to an open position.

A bulk bin forming system configured as a container forming cell includes a multi-axis robot to which is attached a multifunction tool. One or more collapsed card board boxes are located at a first station of the container forming cell adjacent the robot. The robot and multifunction tool are configured to operate to grasp and move an individual box, orient and pre-form the box by folding flaps at a second station of the cell, and then move the box to a third station of the cell to mount the box to a support configured as a pallet to thereby form a bulk bin or bulk box container referred to as a gaylord container. The tool may include vacuum grippers for grasping the boxes and staplers for securing the formed box to the pallet, and may also be used to fold the bottom flaps prior to mounting the box to the pallet.

A body portion (120A) that is a cylindrical body has one end portion, such as a lower end portion or the body portion (120A) or a first part (126) of a body portion (120), that is folded back inwardly. The body portion (120A) has at least one planar-shaped flat section, such as a second flat section (122) or a fourth flat section (124). A notch, such as a notch (K1) or a notch (K2), is provided at one end, such as a lower end, of the flat section. The one end portion includes a portion provided with the notch, such as by providing the notch (K1) or (K2) at a lower end of the lower end portion of the body portion (120A) or at a distal end of the first part (126A) of the body portion (120).

Described and illustrated is a device for at least partially unfolding package sleeves, having a magazine comprising a stack formed from package sleeves, wherein the package sleeves of the stack are folded flat around at least two folding edges extending in the longitudinal direction of the package sleeves and wherein a gripper is provided for gripping a side of the package sleeves facing away from the stack and for moving, in particular pulling, the package sleeves along a withdrawal transport path with the folding edges into grooves of at least one receptacle of a moulding station and wherein the grooves are spaced so that the folding edges of the package sleeves are spaced apart further in the magazine than in the grooves. In order to further prevent operational malfunctions and allow a more reliable and largely malfunction-free production of packaging bodies which are open on one side from package sleeves which are open on both sides, it is provided that a drive is assigned to the gripper and/or the grooves for moving the package sleeve section gripped by the gripper first along the withdrawal transport path across a groove plane which connects the grooves, then back against the withdrawal transport path across the groove plane, and then again along the withdrawal transport path across the groove plane.

A squeeze tube includes a fluid-discharge container and a fluid-discharge closure mated to the fluid-storage container. The fluid-discharge closure is coupled to one end of the fluid-storage container and configured to discharge selectively fluid stored in a product-storage region formed in the fluid-storage container.