A box transport rail 70 extending in the box transport direction Tb and a plurality of box transport shuttles 76 movably arranged on the box transport rail 70 to be movable in the box transport direction Tb, which is the movement direction of a packing box Bx, are provided. When located in the sheet feeder 81, the box transport shuttles 76 receive the sheet 9 while being apart from each other across an interval greater than the bottom sheet portion 91 of the sheet 9. During movement from the pushing unit 82 to the sealer 84, the box transport shuttle 76 arranged frontward in the box transport direction Tb is brought close to the bottom sheet portion 91 to reduce the angle of a part 93 frontward of the bottom sheet portion 91 in the box transport direction Tb relative to the bottom sheet portion 91.

A box transport rail 70 extending in the box transport direction Tb and a plurality of box transport shuttles 76 movably arranged on the box transport rail 70 to be movable in the box transport direction Tb, which is the movement direction of a packing box Bx, are provided. When located in the sheet feeder 81, the box transport shuttles 76 receive the sheet 9 while being apart from each other across an interval greater than the bottom sheet portion 91 of the sheet 9. During movement from the pushing unit 82 to the sealer 84, the box transport shuttle 76 arranged frontward in the box transport direction Tb is brought close to the bottom sheet portion 91 to reduce the angle of a part 93 frontward of the bottom sheet portion 91 in the box transport direction Tb relative to the bottom sheet portion 91.

A box forming carousel apparatus including a frame, a rotating carton retainer, a first side carton folding assembly, a second side carton folding assembly and an axle. The frame has a bottom, and first and second sides. The rotating carton retainer is rotatably coupled to the frame and has a plurality of slot assemblies radially spaced apart, each slot assembly having a leading wall, a following wall and a base wall. Each slot assembly structurally configured to retain a box therein. The first side carton folding assembly is structurally configured to fold a plurality of flaps of the box on a first side thereof. The second side carton folding assembly is structurally configured to fold a plurality of flaps of the box on a second side thereof. The axle extends between the first side and the second side of the frame spaced apart from the bottom of the frame.

A pharmaceutical pack and the method for making the same are provided. The pharmaceutical pack includes a blister layer and a lidding sheet disposed over the blister layer. The blister layer defines at least one opening. The lidding sheet includes a first layer and optionally a second layer. The first layer includes at least one hologram, and is disposed on the second layer, which is a plastic film. The blister layer and the lidding sheet define at least one cavity so as to hold at least one pharmaceutical dosage form therein.

A carrier (2) made of cardboard, paperboard or other lightweight foldable sheet material, comprises a top sheet (4) defining one or more pockets (20) for receiving one or more products and a bottom sheet (6) attached to the top sheet (4). The top sheet (4) comprises one or more respective sets (30) of flaps (32) for forming the respective pockets (20), each flap (32) being hingedly connected at a proximal end (36) to a top surface (38) of the top sheet (4) about a respective flap hinge line (40) defined around an upper edge (42) of the respective pocket (20) and folded about the respective flap hinge line (40) to define a pocket side wall. The top sheet (4) further comprises respective tabs (50) hingedly connected to distal ends (46) of the respective flaps (32) about respective tab fold lines (52) and folded about a respective tab fold line (52) so as to lie along a base of the pocket (20). The bottom sheet (6) is bonded to the respective tabs (50) in a face to face relationship to close at least a portion the base of the pocket (20).

A carrier (2) made of cardboard, paperboard or other lightweight foldable sheet material, comprises a top sheet (4) defining one or more pockets (20) for receiving one or more products and a bottom sheet (6) attached to the top sheet (4). The top sheet (4) comprises one or more respective sets (30) of flaps (32) for forming the respective pockets (20), each flap (32) being hingedly connected at a proximal end (36) to a top surface (38) of the top sheet (4) about a respective flap hinge line (40) defined around an upper edge (42) of the respective pocket (20) and folded about the respective flap hinge line (40) to define a pocket side wall. The top sheet (4) further comprises respective tabs (50) hingedly connected to distal ends (46) of the respective flaps (32) about respective tab fold lines (52) and folded about a respective tab fold line (52) so as to lie along a base of the pocket (20). The bottom sheet (6) is bonded to the respective tabs (50) in a face to face relationship to close at least a portion the base of the pocket (20).

A system for automatic packaging of shoes can include a first subsystem that can determine shoe type information from a shoe or pair of shoes to be packaged, a second subsystem that can automatically package the shoe, or pair of shoes, in a packaging container, and a third subsystem that can dynamically control the automatic packaging based at least in part on the determined shoe type information.

An envelope is configured to hold, support, and protect an article such as a blood bag during transportation under cryogenic temperatures. The envelope includes a single piece component (e.g., a monolithic component), including multiple panels that are configured to fold to form an enclosure that surrounds the article such as the blood bag for support and protection of the article such as the blood bag.

An order management system and method for automated logistics based on-demand box supplying is disclosed. The system pre-estimates a dimension required by all of the merchandise according to an order data, and selects a sheet material according to the size to form a finished container. The dimension of the unfolded sheet material before folding into the finished container is quite small. In terms of warehouse space utilization, a space required by a single finished and folded box is able to stack dozens of sheet materials, so that the warehousing efficiency is greatly improved. By integrating with a box folding module and a sealing module, fully automated logistics can be achieved with human intervention.

A carrier (2) made of cardboard, paperboard or other lightweight foldable sheet material, comprises a top sheet (4) defining one or more pockets (20) for receiving one or more products and a bottom sheet (6) attached to the top sheet (4). The top sheet (4) comprises one or more respective sets (30) of flaps (32) for forming the respective pockets (20), each flap (32) being hingedly connected at a proximal end (36) to a top surface (38) of the top sheet (4) about a respective flap hinge line (40) defined around an upper edge (42) of the respective pocket (20) and folded about the respective flap hinge line (40) to define a pocket side wall. The top sheet (4) further comprises respective tabs (50) hingedly connected to distal ends (46) of the respective flaps (32) about respective tab fold lines (52) and folded about a respective tab fold line (52) so as to lie along a base of the pocket (20). The bottom sheet (6) is bonded to the respective tabs (50) in a face to face relationship to close at least a portion the base of the pocket (20).