A packaging assembly is provided with a base that is sized to receive at least one shower door glass pane. At least one shower door glass pane is received within the base. A handle is mounted to the base. A plurality of projections extends from a bottom surface of the base to rest upon an underlying support surface and to reduce friction between the packaging assembly and the underlying support surface. The base includes a box with an opening formed in opposed surfaces of the box to expose a portion of the at least one shower door glass pane.

A container for packaging a welding wire on a spool includes a box with opposed first and second face panels that are separated by four vertical side walls. At least one aperture on the four vertical side walls is defined by a frangible connection so that the interior of the box is initially inaccessible. At least one corner blocking insert includes an outer profile that corresponds to the spool of welding wire located within said box. After said frangible connection of the aperture is breached, the corner blocking is inserted into the interior of the box via said aperture and engages at least one of an outer perimeter rim of said spool containing a coil of welding wire, or an outer perimeter of the coil of welding wire. In various examples, the corner blocking insert is an expanding foam package, or a folded cardboard insert.

A container comprised a container body having a first cavity for receiving a product therein, the container body having a front surface, back surface, first sidewall and second sidewall, and a cover having an opening extending thereinto, said opening configured to receive said container body therein, the cover comprising an outer wall, an inner wall and a second cavity defined between said outer wall and inner wall, said second cavity housing a protective material therein. The protective material moves the cover from a first configuration defining a first inner profile of the inner wall of the cover to a second configuration defining a second inner profile of the cover, said second inner profile being smaller than the first inner profile.

A flexible, sterilizable pouch includes a first wall coupled to a second wall and a cavity defined between the first wall and the second wall. The cavity is configured to receive a medical device, and the pouch is configured to seal the medical device within the cavity. At least one of the first wall and the second wall of the pouch includes two layers. Each layer is coupled to the adjacent layer such that a breach in any one layer of the multi-layered wall will not breach the seal of the pouch. A pocket may be formed between the layers of the multi-layered wall and may include a gas under pressure to inflate the corresponding wall to an inflated state.

A portable electronic device includes one or more bumpers that are operable to transition between a stowed position and a deployed position. In the deployed position, the bumpers may be proud of one or more surfaces of the portable electronic device that the bumpers are not proud of in the stowed position. The bumpers may protect the surfaces from impact when proud of those surfaces if the portable electronic device contacts a surface, such as when the portable electronic device is dropped. The bumpers may form portions of side corners or other portions of the portable electronic device in the stowed position. In transitioning from the stowed position to the deployed position, the bumpers may rotate and/or translate.

A bioimplant package according to an embodiment of the present invention includes a sealing body to vacuum seal a bioimplant therein, and an inner box to accommodate the sealing body therein. The sealing body vacuum seals the bioimplant so that the bioimplant is located at a middle part of the sealing body. The inner box is made of an approximately rectangular-shaped sheet material divided into a mounting part to mount thereon the middle part of the sealing body, and a pair of winding parts which windingly fix a side part of the sealing body extending outward from the mounting part and come into linear contact with the sealing body in the vicinity of a boundary part with the mounting part. A bioimplant packaging method according to an embodiment of the present invention is a method for packaging a bioimplant by using a bioimplant package according to the above embodiment.

A bioimplant package according to an embodiment of the present invention includes a sealing body to vacuum seal a bioimplant therein, and an inner box to accommodate the sealing body therein. The sealing body vacuum seals the bioimplant so that the bioimplant is located at a middle part of the sealing body. The inner box is made of an approximately rectangular-shaped sheet material divided into a mounting part to mount thereon the middle part of the sealing body, and a pair of winding parts which windingly fix a side part of the sealing body extending outward from the mounting part and come into linear contact with the sealing body in the vicinity of a boundary part with the mounting part. A bioimplant packaging method according to an embodiment of the present invention is a method for packaging a bioimplant by using a bioimplant package according to the above embodiment.

Provided is an inexpensive packaging member whereby musical drums can be packaged for transportation, in a short time and in the most compact manner, and can be safely transported. The packaging member can be inexpensively produced using a simple structure whereby cardboard or other sheet member is cut in a predefined shape and perforations are made therein. Furthermore, the packaging member is flat-packed and therefore does not occupy space during transportation and storage. In addition, packaging time can be shortened and drums can be safely transported. The flat-packed packaging member can be reused countless times if the contents are the same size.

Provided is an inexpensive packaging member whereby musical drums can be packaged for transportation, in a short time and in the most compact manner, and can be safely transported. The packaging member can be inexpensively produced using a simple structure whereby cardboard or other sheet member is cut in a predefined shape and perforations are made therein. Furthermore, the packaging member is flat-packed and therefore does not occupy space during transportation and storage. In addition, packaging time can be shortened and drums can be safely transported. The flat-packed packaging member can be reused countless times if the contents are the same size.

A packaging box is formed of corrugated cardboard, wherein end portions of the packaging box are protruded relative to a middle portion of the packaging box so that the packaging box has a curved shape, and a corrugation direction of the corrugated cardboard is parallel to a longitudinal direction of the packaging box.