The present disclosure is directed to dunnage bags formed using polyethylene terephthalate (PET) and processes for manufacturing these PET dunnage bags. Generally, the PET dunnage bags of the present disclosure include a PET outer bag, an inner bladder enclosed within the PET outer bag, and a valve assembly that enables air to be introduced into (or escape out of) the inner bladder to inflate (or deflate) the inner bladder, thereby inflating (or deflating) the PET dunnage bag.

A shipping package and method of making a shipping package having a flexible inner sheet having a first surface and a second surface. The method includes providing one or more sheets of flexible material, joining the sheet(s) to form an article reservoir for accepting an article to be shipped, one or more expansion chambers, and an article retrieval feature. The expansion chambers can be inflated or otherwise expanded to provide structure to the package and to protect the article in the article reservoir.

A packaging material includes: an outer box that accommodates an article to be packaged; and a cushioning material including: a sealed bag body with gas confined inside; a partition that divides an inside of the bag body into a first chamber and a second chamber each in an equal volume; and a ventilation passage communicating the first and second chambers, the cushioning material being disposed in a gap between an outer surface of the article and an inner wall of the outer 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 cushioning member includes a medium-filled cushioning component and a surrounding member. The medium-filled cushioning component includes a first cushioning portion and a second cushioning portion. The surrounding member includes a first tubular portion, a second tubular portion, and a connecting portion that connects an end of the first tubular portion in a direction parallel to a first central axis and an end of the second tubular portion in a direction parallel to a second central axis. The connecting portion is bendable such that a posture of the first tubular portion and the second tubular portion is changed between a parallel posture in which the first central axis is parallel to the second central axis and an intersecting posture in which the first central axis intersects the second central axis.

Inflatable structures, or aeromorphs, are provided with reinforcing member shape controlling features. The inflatable structure includes a bladder formed of a programmable substrate and defining an outer perimeter. The bladder includes a plurality of seams and a plurality of foldable segments defined by the plurality of seams. At least one hinge is provided, located adjacent each foldable segment. The hinge is configured to permit a folding movement of the respective foldable segment. At least one reinforcing member is provided, secured to the bladder and configured to guide a directional movement of at least one of the plurality of foldable segments, control a shape of the inflatable structure, and determine a sequence of folding. In various aspects, the reinforcing member includes a thermoplastic polyurethane, and is secured to a surface of the bladder with additive manufacturing techniques, such as 3-D printing.

A sealing structure including a first inner layer unit, a second inner layer unit, a first outer layer unit, and a second outer layer unit is provided. The second inner layer unit and the first inner layer unit are partially connected to each other through a connection manner, so as to form a gas delivery structure that includes a plurality of first stop barriers, a plurality of second stop barriers, and a runner. The second outer layer unit and the first outer layer unit are partially connected to each other through the connection manner, so as to form a first closed pattern, a second closed pattern, a plurality of interval patterns and a plurality of non-continuous patterns. Each of the plurality of first stop barriers and each of the plurality of second stop barriers are connected to one of the plurality of interval patterns respectively.

A reusable packaging device that in a use state is a rhomboid outer structure with an internal inflatable and reusable vessel that surrounds and protects a payload, that can be converted into a storage state by deflating the vessel and folding the outer structure flat in order that it may be stacked.

A packaging part (1) for securing an item to be packaged in an outer packaging, has at least one supporting body (2, 16) that acts as a decoupling element. The supporting body is formed as a hollow body and projects from a bearing base. The supporting body (2, 16) has a base with a relatively large cross-section in the area of the bearing base and tapers in a direction away from the bearing base. The supporting body (2, 16) further has in its shell surface at least one line of weakness (14) that divides the supporting body into an upper part and a lower part. The upper part of the supporting body (2, 16) can be pressed along the line of weakness (14), preferably completely, into the lower part under load.

A packing box is provided. The packing box is formed by several splicing materials of a standard model. The splicing material on the top of the packing box is provided with an air pump with automatic pumping and the pressure monitoring functions. The inner side of each splicing material is provided with an air bag, and the air bags are inflatable and connected to one another via connection tubes. The air bags are able to be spliced or separated with one another, and the shape of each air bag is subject to the outline dimension of a packaged object when the air bags are inflated. The size and shape of the packing box can be determined according to the size and shape of the packaged object, so is applicable to the objects with any sizes and shapes. The packing box does not need additional fillers and is recyclable.