Provided is a shock-absorbing packing box, in which a pair of inner shells are partially fused between a pair of outer shells to constitute a shock-absorbing packing material having a plurality of air cells, and when air is filled into the air cells, the plurality of air cells filled with the air are connected in an overall box-shaped structure.

A packaging assembly, including corrugated corner elements, each corrugated corner element having a first corner post element leg, extending from a vertex of the corrugated corner element and having one or more alternating ridges and grooves, and a second corner post element leg, extending from the vertex, away from the first corner post element leg, and having one or more alternating ridges and grooves; and at least two endcap elements, each comprising at least one tray layer attached or coupled to at least one support layer, wherein the tray layer extends to four corners and the support layer includes a corner recess formed proximate each corner of the tray layer, wherein each corner recess is formed so as to mateingly engage at least a portion of the first end portion or the second end portion of one of the corrugated corner elements at least partially therein.

A system and method of construction based on rods and coils, that includes multiple parts comprising: distinct apparatuses, one or more coil joints, a coil body, and one or more coil spines; wherein any combination of the above parts can result in a variety of distinct structures; wherein the coil joint has 360 degree rotation; wherein the rotation can be limited to simulate other types of joints; wherein this coil joint can be combined with other joint styles to create hybrid styles; wherein there are 2 bias actions, one is an extending action and the other is a contracting action; wherein the action of the coil results in a more life-like motion than not using the coil; wherein the coil body has a flexible shape that can be locked into place; wherein the coil body has a high strength to weight ratio, which leads to high dimensional stability; wherein there is also hollow space for storage and transport of a package inside of the coil body; wherein the coil spine simulates the spines of living beings; wherein the coil spine is a flexible yet robust structure.

A system and method of construction based on rods and coils that can create a mechanical hand; wherein the coil joints function as the equivalent to human joints; wherein there are rods that function as the equivalent to human bones; wherein the coil joints create a dampening effect that simulates the dampening effect in human hands; wherein there are coil bodies of the hand, that are used for transport and storage; wherein the fingers of the artificial hand can be replaced with tools that are of a similar size and not excessive weight; wherein the coil joints can be modified to simulate various human joints; where there is a bias in all coils and coil joints; wherein the bias of the coil joints increases the ability of the artificial hand to grasp; wherein the bias of the coil joint functions as tendon tension; wherein the bias of all the coils results in more life-like motion; wherein movement of the finger can be performed with a single wire opposing the bias of the coil; wherein the artificial hand can have autonomous motion by utilizing an actuator system.

A packaging structure for at least one article includes a pair of generally rectangular support structures with front, side, rear, and interior walls. The walls divide the rectangular support structure into a plurality of triangular sections. The front and interior walls contain a least one opening configured to correspond with the configuration of the article to hold and secure the article in place. The packaging structure is created from a rectangular blank made of foldable material that has a plurality of spaced vertical fold lines, panels, and aligned openings each configured to correspond with the configuration of the article. The packaging structure is formed by folding the blank along the fold lines and securing the blank in the folded condition. The blanks are formed first within computer aided design software by determining the dimensions and profile of a packaging structure, forming openings for an article in a packaging structure, unfolding the packaging structure within the design software into a flat pattern to form a master blank, and using the master blank to create cutting dies for forming additional blanks.

A packaging structure for at least one article includes a pair of generally rectangular support structures with front, side, rear, and interior walls. The walls divide the rectangular support structure into a plurality of triangular sections. The front and interior walls contain a least one opening configured to correspond with the configuration of the article to hold and secure the article in place. The packaging structure is created from a rectangular blank made of foldable material that has a plurality of spaced vertical fold lines, panels, and aligned openings each configured to correspond with the configuration of the article. The packaging structure is formed by folding the blank along the fold lines and securing the blank in the folded condition. The blanks are formed first within computer aided design software by determining the dimensions and profile of a packaging structure, forming openings for an article in a packaging structure, unfolding the packaging structure within the design software into a flat pattern to form a master blank, and using the master blank to create cutting dies for forming additional blanks.

A fixing frame includes an inner side portion having a shape corresponding to that of a side surface of a cake supported on a pedestal to be configured to support the side surface of the cake, an outer side portion having a shape corresponding to that of an inner side surface of a box for receiving the cake supported by the pedestal to be configured to support an inner side surface of the box and a connecting portion configured to connect an upper end of the inner side portion and an upper end of the outer side portion with each other. Thus, the fixing frame is to be provided between the side surface of the cake and the inner side surface of the box to support the side surface of the cake to prevent the cake from moving in the box.

An inflatable packaging element is disclosed herein. The inflatable packaging element includes a first film ply and second film ply overlayed on the first ply, and a seal pattern. The seal pattern has a plurality of seals sealing the first and second plies to each other to define an inflation chamber between the first and second plies. The inflation chamber is inflatable with and configured to contain a fluid. An aperture extends through at least one of the first or second ply, and the seal pattern separates opposite side of the aperture from the inflation chamber.

A collapsible dunnage adapted for being positioned in a box for transporting parts that includes a plurality of top-opening pockets for receiving the parts to be transported and formed of a flexible web positioned in side-by-side registration with each other and movable between an expanded use position and a collapsed storage position while being maintained in the same side-by-side registration position. Fastener elements are attached to the dunnage and adapted for fastening the dunnage to complementary fastener elements carried by a box in which the dunnage is adapted to be positioned for use and storage. The box is collapsible and includes features that permit convenient storage of the collapsed accordion dunnage in the collapsed box.

A collapsible dunnage adapted for being positioned in a box for transporting parts that includes a plurality of top-opening pockets for receiving the parts to be transported and formed of a flexible web positioned in side-by-side registration with each other and movable between an expanded use position and a collapsed storage position while being maintained in the same side-by-side registration position. Fastener elements are attached to the dunnage and adapted for fastening the dunnage to complementary fastener elements carried by a box in which the dunnage is adapted to be positioned for use and storage. The box is collapsible and includes features that permit convenient storage of the collapsed accordion dunnage in the collapsed box.

A collapsible dunnage box is provided that includes a box base and first and second opposed base sidewalls attached to the box base on opposing sides of the box. First and second opposed top sidewalls are pivotally attached to the top edge of respective ones of the base sidewalls. First and second opposed top endwalls are provided to form a box enclosure. The base endwalls are pivotally-mounted to the top endwalls and are moveable between a lowered, vertical deployed position enclosing respective ends of the box and a raised, horizontal stowed position to contain and store dunnage positioned in an upper portion of the box.