A firearm storage system is provided. It can include an enclosure device adapted for having a firearm mounting device mounted to a support member, such as a generally vertically disposed panel or wall. The mounting device includes a notch forming member forming a series of notches and loops in an alternating pattern, such that a long firearm can be stored next to a short firearm, utilizing space between adjacent long firearms for the storage of the short firearm. The barrels of the firearms are generally vertically disposed during storage and can be angled to apply a force on the firearms, and, in particular, on the long firearm to help retain the firearms in their respective portions of the mounting device.

A firearm storage system is provided. It can include an enclosure device adapted for having a firearm mounting device mounted to a support member, such as a generally vertically disposed panel or wall. The mounting device includes a notch forming member forming a series of notches and loops in an alternating pattern, such that a long firearm can be stored next to a short firearm, utilizing space between adjacent long firearms for the storage of the short firearm. The barrels of the firearms are generally vertically disposed during storage and can be angled to apply a force on the firearms, and, in particular, on the long firearm to help retain the firearms in their respective portions of the mounting device.

The invention relates to a method for installing metallic fastener (10; 40) for the interference fit assembly of at least two structural elements (20, 22) comprising a through hole, the fastener comprising an enlarged head (12; 42), a shaft (14; 44) having an external diameter before installation that is greater than an internal diameter of the hole, said shaft comprising a conductive surface (26; 56). Before installation, at least the conductive surface (26; 56) is coated with a lubricating layer (30), which comprises a mixture of at least one polyolefin and one polytetrafluoroethylene, for example, having sufficient adherence to prevent its abrasion by manual manipulation of the fastener and being weak enough to be at least partly stripped from the conductive surface during the interference fit assembly of the fastener. The invention is applicable to the assembly of aircraft structures.

A cable-to-pipe connector is provided. A cable-to-pipe connector for providing continuous transfer of current from a cable to a utility pipe in above grade and below grade systems, comprising a conductive lug comprising a head at a top end of the conductive lug affixed to a noncircular neck that is further affixed to a body in a linear formation, the head, the neck, and the body having decreasing diameters respectively. An insulating shell partially encasing by the conductive lug. A horizontal aperture at a midway point of the head. A first fastener extending from above a top of the head through the horizontal aperture. A threaded member at a base end of the conductive lug and a bottom end of the insulation shell.

A cable-to-pipe connector is provided. A cable-to-pipe connector for providing continuous transfer of current from a cable to a utility pipe in above grade and below grade systems, comprising a conductive lug comprising a head at a top end of the conductive lug affixed to a noncircular neck that is further affixed to a body in a linear formation, the head, the neck, and the body having decreasing diameters respectively. An insulating shell partially encasing by the conductive lug. A horizontal aperture at a midway point of the head. A first fastener extending from above a top of the head through the horizontal aperture. A threaded member at a base end of the conductive lug and a bottom end of the insulation shell.

The present invention provides a lamination method for a special-shaped glass cover plate, including following steps. Step S1: forming a magnetic layer on a display panel. Step S2: arranging a first solenoid and a second solenoid at a regular-shaped portion and a special-shaped portion of the special-shaped glass cover plate, respectively. Step S3: supplying opposite electric currents to the first solenoid and the second solenoid. Step S4: changing magnitude of an electric current from the regular-shaped portion to the special-shaped portion. Step S5: when to attach the display panel to the special-shaped portion of the special-shaped glass cover plate, changing magnitude of the electric current of the second solenoid and a direction of the second solenoid to attach the display panel along the special-shaped portion.

The present invention provides a lamination method for a special-shaped glass cover plate, including following steps. Step S1: forming a magnetic layer on a display panel. Step S2: arranging a first solenoid and a second solenoid at a regular-shaped portion and a special-shaped portion of the special-shaped glass cover plate, respectively. Step S3: supplying opposite electric currents to the first solenoid and the second solenoid. Step S4: changing magnitude of an electric current from the regular-shaped portion to the special-shaped portion. Step S5: when to attach the display panel to the special-shaped portion of the special-shaped glass cover plate, changing magnitude of the electric current of the second solenoid and a direction of the second solenoid to attach the display panel along the special-shaped portion.

An apparatus for holding and releasing a pin in a controlled manner comprises a base, a pin holding element supported at the base, a plurality of rod-shaped release elements made of a shape memory alloy and supported at the base, a holding force application device supported at the base for applying an elastic holding force, and a force transfer element. The force transfer element is subjected to the elastic holding force and, against the elastic holding force, supported at the base via a parallel arrangement of the pin holding element and the release elements. The release elements are arranged with radial play in blind holes in the base, which are arranged around the pin holding element. The pin holding element is deactivatable by heating up the release elements beyond a transition temperature of their shape memory alloy and by a resulting recovery of the release elements to straight memory shapes.

An anchor including shape memory metals, shape memory polymers or a combination thereof. The anchor has surgical and nonsurgical uses.

A pivoting fastener assembly for securely fastening a panel in spaced relation to a support backing, and a method of manufacturing the same. The fastener assembly includes: a magnet-carrier assembly that includes a magnet that is fixed to a carrier member; and a base member that includes a base portion and a pivoting portion. The pivoting portion includes a head, a trunk, and an extension portion that is connected to the base portion. The extension portion includes a top side that connects a first peripheral surface to a second peripheral surface of the extension portion. A first end of the trunk is connected to the top side of the extension portion and a second end of the trunk is connected to the head. The base member is a unitary piece, and the head of the pivoting portion engages and retains the carrier member of the magnet-carrier assembly.