Protective covers for rotors are disclosed. The protective covers may include a first liner portion contacting and covering a first portion of the rotor, and a second liner portion positioned adjacent and at least partially aligned circumferentially with the first liner portion. The second liner portion may contact and cover a second portion of the rotor. The protective covers may also include an outer casing covering the first liner portion and the second liner portion.

An accommodating body includes: a first accommodating body that has a first bottom portion; and a first buffering material that has a first pressure receiving surface coming into contact with an accommodated article accommodated in the first accommodating body and that has at least one first sheet-shaped web that contains fibers and a bonding material that bonds the fibers, and in which in the first sheet-shaped web, the fibers are oriented in a plane direction of the first sheet-shaped web, and the first buffering material is used in an orientation with which an end surface of the first sheet-shaped web serves as the first pressure receiving surface.

A bag for producing a foam-in-bag dunnage material comprises a closed edge portion and, in a non-sealed state of the bag, an open edge portion, the closed and open edge portions delimiting an inner bag volume. The invention proposes that a bag structure of the bag comprises a mixing chamber which is adapted to receive foam precursor substances, which is arranged within the inner bag volume, which is at least partially and initially delimited against the remainder of the inner bag volume, and which in the non-sealed state of the bag is connected to the open edge portion.

A shock absorbing container to protect cryogenically frozen biological material includes an outer case, which includes a first outer panel and a second outer panel, the first outer panel and the second outer panel movable relative to each other between a closed position and an open position, the first outer panel and the second outer panel defining a storage space in the closed position, the first outer panel having a first side facing the storage space, the second outer panel having a first side facing the storage space, wherein moving the first outer panel and the second outer panel into the open position creates or enlarges an opening to access the storage space. A first foam panel is on the first side of the first outer panel, and a second foam panel on the first side of the second outer panel.

A protective carrying case for a firearm is disclosed, wherein the protective carrying case includes a top component, a bottom component, and semi-hexagonal ends, wherein the top component and the bottom component are constructed from carbon fiber. The protective carrying case additionally includes a retaining element with vacuum split functionality to retain elements within the case.

A more robust packaging structure for maintaining the integrity of compressible biologically active materials during storage and especially during transportation is provided. These containers protect the materials from shock, vibration, deformation, or separation from agitation. The compressible materials may be in the form of synthetic fibers, and may include a composite of fibers and beads or granules. Suitable materials that may benefit from such a robust packaging structure include synthetic materials that comprise a biologically active ceramic or glass.

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 container for transporting satellite equipment and other equipment into low-orbit and deep space includes vacuum rigidizing structures covering the interior of each side wall and base of the container. The vacuum rigidizing structures contain microbeads and is connected to a pump mechanism able to transfer air into or out of the vacuum rigidizing structures. Before the equipment is added to the container, air is released from the vacuum rigidizing structures. After the equipment is added, the vacuum rigidizing structures are able to be inflated enough such that the microbeads compactly conform around the equipment, preventing movement while applying minimal pressure to the equipment. The container is capped with a lid lined with aerospace-grade foam.

A protective carrying case for medical supplies is disclosed, wherein the protective carrying case includes a top component, a bottom component, and semi-hexagonal ends, wherein the top component and the bottom component are constructed from carbon fiber. The protective carrying case additionally includes a retaining element with vacuum split functionality to retain elements within the case. The retaining element includes a flexible bag with an outer antimicrobial layer for safe and sanitary transport of the medical supplies.

A packaging combination is disclosed that includes a box and at least first and second planar objects in the box. At least first and second shock absorbing clips are attached to the planar objects in the box. At least one of the first clips is fastened to the first planar object and the clip is positioned between one wall of the box and the second planar object. At least one of the second clips is fastened to both planar objects and is positioned between opposite walls of the box.