Provided is a cushioning material for being put into a packing box configured for encasement of electronic equipment. The cushioning material absorbs external stress applied to the electronic equipment encased in the packing box. The cushioning material includes: a holder including a first plate having a first opening and configured to face the electronic equipment, and a second plate having a second opening and configured to face an inner wall surface of the packing box; and a first cushioning block held by the holder between the first plate and the second plate. The first cushioning block includes a first cushioning portion protruding through the first opening in a first direction going from the first plate toward the electronic equipment and configured to be in contact with the electronic equipment, a second cushioning portion protruding through the second opening in a second direction going from the second plate toward the inner wall surface of the packing box and configured to be in contact with the inner wall surface of the packing box, and a first link portion provided between the first plate and the second plate and linking the first cushioning portion and the second cushioning portion to each other. The first link portion is longer than the first opening and the second opening in a first holding direction intersecting with the first direction and the second direction.

A carrier and related methods of use are provided for packaging irregular-shaped products. The carrier has a footing and a vertical support member partially enclosing at least one irregular-shaped product. The vertical support member has: (1) a pair of sidewalls facing one another and having lower tabs joined to opposite ends of the footing, and (2) a rear wall with edges along the junctures with the sidewalls and a lower edge along the juncture with the footing. A wrap encloses the irregular-shaped product(s) and the carrier. The method includes uniformly aligning the irregular-shaped product(s) in the carrier and securing the carrier and product(s) by enclosing them with a wrap.

A carrier and related methods of use are provided for packaging irregular-shaped products. The carrier has a footing and a vertical support member partially enclosing at least one irregular-shaped product. The vertical support member has: (1) a pair of sidewalls facing one another and having lower tabs joined to opposite ends of the footing, and (2) a rear wall with edges along the junctures with the sidewalls and a lower edge along the juncture with the footing. A wrap encloses the irregular-shaped product(s) and the carrier. The method includes uniformly aligning the irregular-shaped product(s) in the carrier and securing the carrier and product(s) by enclosing them with a wrap.

Packaging for a weapon sight and associated components and methods. The weapon sight may comprise a telescopic sight or scope and include a sighting axis along which a user looks to use the optical sighting device. The packaging comprises a package defining an interior sized and shaped to fit the sight. The packaging is configured to permit the user to view the optical sighting device through the cover and to look through the sight along the sighting axis.

Packaging for a weapon sight and associated components and methods. The weapon sight may comprise a telescopic sight or scope and include a sighting axis along which a user looks to use the optical sighting device. The packaging comprises a package defining an interior sized and shaped to fit the sight. The packaging is configured to permit the user to view the optical sighting device through the cover and to look through the sight along the sighting axis.

A packaging and shipping system for dry charged batteries. The packaging system includes a shipping crate having a lower section that defines an open interior. The open interior is sized to receive a dry charged battery and a plurality of electrolyte bottles. Each of the electrolyte bottles contains a volume of electrolyte sufficient to fill one of the individual cells of the dry charged battery. Each of the electrolyte bottles are separately packaged and positioned within the open interior of the shipping crate. Upon reaching the desired destination, the shipping crate can be stored. When the dry charged battery is to be placed into use, the shipping crate is opened and the individual cells of the dry charged battery are filled with electrolyte from the plurality of electrolyte bottles. Once the dry charged battery has been activated, the empty electrolyte bottles can be placed back into the shipping crate and returned for recycling.

A packaging and shipping system for dry charged batteries. The packaging system includes a shipping crate having a lower section that defines an open interior. The open interior is sized to receive a dry charged battery and a plurality of electrolyte bottles. Each of the electrolyte bottles contains a volume of electrolyte sufficient to fill one of the individual cells of the dry charged battery. Each of the electrolyte bottles are separately packaged and positioned within the open interior of the shipping crate. Upon reaching the desired destination, the shipping crate can be stored. When the dry charged battery is to be placed into use, the shipping crate is opened and the individual cells of the dry charged battery are filled with electrolyte from the plurality of electrolyte bottles. Once the dry charged battery has been activated, the empty electrolyte bottles can be placed back into the shipping crate and returned for recycling.

Provided is a package body for ceramic separation membranes, comprising: a packaging box which stores a plurality of ceramic separation membranes in parallel in a width direction and a height direction; and a plurality of partition packs, wherein each of the partition packs has a thickness equal to or larger than a thickness of each of the ceramic separation membranes, and has a plurality of storing parts, with intervals therebetween in the width direction, which are through holes of a size including a projection shape of the ceramic separation membrane, and the packaging box stores at least two kinds of the partition packs stacked in the height direction with the plurality of storing parts arranged in the width direction in a staggered manner.

Provided is a package body for ceramic separation membranes, comprising: a packaging box which stores a plurality of ceramic separation membranes in parallel in a width direction and a height direction; and a plurality of partition packs, wherein each of the partition packs has a thickness equal to or larger than a thickness of each of the ceramic separation membranes, and has a plurality of storing parts, with intervals therebetween in the width direction, which are through holes of a size including a projection shape of the ceramic separation membrane, and the packaging box stores at least two kinds of the partition packs stacked in the height direction with the plurality of storing parts arranged in the width direction in a staggered manner.

A separating layer for the transport of pharmaceutical secondary packagings and to a transport system for transporting pharmaceutical secondary packagings which comprises the separating layer are provided. The separating layer is a polymer layer having a planar section extending in an axial direction along a longitudinal axis and an elevation extending normal to the longitudinal axis. The separating layer has in the axial direction a normal spring force that is 0.2 to 5 N.