The present invention provides a crossed staggered and stacked-type air packaging device and a manufacturing method therefor. The crossed staged and stacked-type air packaging device includes at least two inflation packaging main body layers, so as to form an accommodation cavity used for storing an article to be packaged. Each inflation packaging main body layer includes at least one sub-inflation unit. The sub-inflation units of at least two adjacent inflation packaging main body layers have different extending directions, so that at least two adjacent inflation packaging main body layers are arranged in a crossed and staggered manner.

The application discloses a packaging structure, which includes an upper cover and a lower cover. The upper cover includes a first base plate, a first packaging part, and a second packaging part. The first base plate is divided into a first portion and a second portion by a first folding part. The first packaging part is disposed on the first portion, and has a plurality of first separation troughs. The second packaging part is disposed on the second portion, and has a plurality of second separation troughs. The first separation troughs can be respectively in communication with the second separation troughs to form a plurality of first accommodating slots. First ends of a plurality of objects can be respectively accommodated in the first accommodating slots, and second ends of the objects can be respectively accommodated in a plurality of second accommodating slots of the lower cover.

A device for protecting an inner container and the sample or contents in the inner container. The device for protecting an inner container and sample includes an inner container and an outer protective body. The inner container can receive a sample for applications such as biomedical, health care, dentistry, agricultural, industrial, and veterinary. The inner container can be received into the outer protective body for protection. A lid secures over the inner container forming a seal to prevent leakage and contamination of the sample or inner container contents. The outer protective body is breakage-resistant for protection if the apparatus is dropped.

A bottom surface member (12) of a container (100) defines an xy-plane, and a side surface member (14) defines an xz-plane and a yz-plane. A protective member includes a receiving part (22R) that has a first receiving surface (24) parallel to the xz-plane and a second receiving surface (23) parallel to the yz-plane, and a supporting part (22S) integrally formed with the receiving part. The supporting part has a first flat plate section (22Sa) parallel to the xz-plane, a second flat plate section (22Sb) parallel to the yz-plane, and a third flat plate section (22Sc) that is provided on the first flat plate section and the second flat plate section and is parallel to the xy-plane. The receiving part has a fourth flat plate section (22Ra) that has the first receiving surface and is parallel to the xz-plane, a fifth flat plate section (22Rb) parallel to the yz-plane, a sixth flat plate section (22Rc) facing the fourth flat plate section with a gap therebetween, and a seventh flat plate section (22Rd) that has the second receiving surface and is parallel to the yz-plane. A gap (22G) is formed between the seventh flat plate section that has the second receiving surface and the fourth flat plate section that has the first receiving surface.

A product packaging system in one embodiment includes a stack of products defining a pair of opposing major side surfaces, a top surface, a bottom surface, and pair of opposing end surfaces; protective corrugated sheets covering two or more of the stack side, top, and bottom surfaces; and a protective end pad covering each of the stack end surfaces. Each protective corrugated sheet includes a pair of longitudinally-extending and protruding corner reinforcement structures disposed along corner regions of the stack. The reinforcement structures are three-dimensional structures having different possible configurations which provide crush-resistance in the assembled product package. The product package collectively comprising the foregoing components is insertable into an outer shipping carton for transit. Some embodiments include banding which holds the stack of products together. In one embodiment, the products may be mirrors.

A standing-type air-filled packaging apparatus and a manufacturing method therefor are provided. The apparatus includes an inflatable body and an inflation valve. The inflatable body includes multiple inflatable units that are formed by stacking together at least two layers of air chamber films and are connected with each other. The inflatable units are heat-sealed and bent to form an air-filled packaging apparatus provided with at least one accommodating chamber used for accommodating an item to be packaged. The inflation valve is mounted on the inflatable body to inflate the inflatable body. At least one distal side of the solid air-filled packaging apparatus forms an annular support part. When the air-filled packaging apparatus is inflated, the annular support part is suitable for standing on a surrounding surface, thus allowing the packaging apparatus to be in a firm standing state.

A shipping system for shipping planar substrates includes a plurality of planar substrates stacked to form a pack and a plurality of interleaving material including substantially spherical beads positioned between the substrates of the pack and configured to carry a load. Substantially all of the beads have a diameter within 25% of D.sub.max, where D.sub.max is a diameter corresponding to a size of an opening of an upper limit sieve used in the shipping system. Also disclosed are a spacer for use in a shipping system for shipping planar substrates, a wrapped system for shipping planar substrates, a method of wrapping a system for shipping planar substrates, and a powder applicator.

The invention is directed to a foldable and biodegradable cushioning sheet comprising a plurality of cushions, which sheet comprises a flexible base film and a plurality of cushions located on the top surface of the flexible base film; and wherein the cushioning sheet can be folded to provide a sturdy inside corner, wherein an object can be placed, such that the object is protected and if needed immobilized, for example during packing and transporting.

A shipping system for shipping planar substrates includes a plurality of planar substrates stacked to form a pack and a plurality of interleaving material including substantially spherical beads positioned between the substrates of the pack and configured to carry a load. Substantially all of the beads have a diameter within 25% of D.sub.max, where D.sub.max is a diameter corresponding to a size of an opening of an upper limit sieve used in the shipping system. Also disclosed are a spacer for use in a shipping system for shipping planar substrates, a wrapped system for shipping planar substrates, a method of wrapping a system for shipping planar substrates, and a powder applicator.

A deployable paper roll cushion according to the invention is provided and comprises, a top layer having an elongated raised member composed of a cushion material. Further, comprising a bottom layer having a composition composed of ferromagnetic material which is layered to a rear face of the top layer. Moreover, comprising a wrap layer in which an exposed area of the top layer and an exposed area of the bottom layer are covered, and a front face of the top layer receives a downward force from a paper roll while the paper roll is in contact with the wrap layer.