A system can include a display assembly that includes a display, a display side, a back side and a frame, where the back side includes a serial bus socket; and a camera assembly that includes a camera head unit coupled to an end of an arm, where an opposing end of the arm includes a serial bus connector receivable by the serial bus socket of the back side of the display assembly.

The invention relates to a riding saddle intended for being placed on the back of a horse, having at least one main mechanical connecting member, configured to engage with an auxiliary mechanical connecting member of a riding accessory and at least one electronic device. The riding saddle is characterized in that, as the auxiliary mechanical connecting member of the riding accessory comprises at least one auxiliary electrical connector, the main mechanical connecting member has at least one main electrical connector electrically connected to the electronic device by an electrical link, so as to ensure an electrical connection between the main electrical connector of the riding saddle and the auxiliary electrical connector of the riding accessory during the mechanical connection between the main mechanical connecting member of the riding saddle and the auxiliary mechanical connecting member of the riding accessory.

The fixing method involves the fixing, for example by screwing, of the electrical connector (202) to the electrical terminal (210). It also involves, before the fixing of the electrical connector (202) to the electrical terminal (210): fixing of the electrical terminal (210) to an intermediate support (206), and the engagement of the electrical connector (202) with at least one element (410, 416) of the intermediate support (206) in order to keep the electrical connector (202) in position with respect to the intermediate support (210).

The present disclosure provides descriptions of configurations for bonding washers used to facilitate the electrical bonding of metal structures. The bonding washer includes an electrically conductive body and at least one piercing member extending from a bottom surface of the body. An extended member extends from the electrically conductive body in a direction away from the bottom surface of the body.

A push-on fastener including: a conductive, annular push-on fastener body including a major surface and a radial edge defining a peripheral surface, the push-on fastener body forming an aperture defining a central axis; and a non-conductive sliding layer overlying the major surface of the push-on fastener body, where the major surface includes a void area free of non-conductive sliding layer adapted to contact an inner component or an outer component so as to provide electrical conductivity between the push-on fastener and a neighboring component.

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 tablet stand is disclosed which incorporates a near field antenna configuration which couples to a near field antenna in the back of a tablet and provides a near field antenna coupling region for near field communication at the front of the tablet. The stand may be completely passive and use conductive antenna elements and passive resonance matching circuit elements to provide efficient coupling. In another aspect a thin profile passive keyboard adapted for use with a near field enabled tablet is provided. In another aspect a mounting bracket or holder, embedded antenna, and passive keyboard combination is provided adapted for converting a tablet into a notebook type configuration.

An electrode plate (100) and a wearable defibrillation device are disclosed. The electrode plate (100) includes a hermetic shell (110), a capsule (120) and a sealing structure (130). The hermetic shell (110) has an inflation port (111) and an overflow aperture (112). The overflow aperture (112) is disposed in a conductive exposed surface (113) of the hermetic shell (110). The capsule (120) is provided in the hermetic shell (110) and defines a cavity (122) for storage of a conductive paste therein. The cavity (122) defines an inlet orifice (123) and an outlet orifice (124). The overflow aperture (112) is disposed at the outlet orifice (124). A sealing component (132) of the sealing structure (130) is positioned at the overflow aperture (112) and configured to close the overflow aperture (112) and the outlet orifice (124) when the hermetic shell (110) is not inflated. The force applying component (131) of the sealing structure (130) is disposed on the hermetic shell (110) and then is connected to the sealing component (132) after being inserted into the capsule (120) through the inlet orifice (123). The force applying component (131) is configured to pull the sealing component (132) as a result of inflation and expansion of the hermetic shell (110) and thus open the overflow aperture (112) and the outlet orifice (124) and bring them into communication. As a result, the conductive paste is allowed to flow through the outlet orifice (124) and the overflow aperture (112) onto the exposed surface (113). During cardiac defibrillation of the electrode plate (100), the conductive paste can automatically applied to provide a patient with timely protection, and the conductive paste can be released in a reliable and safe manner.

A mobile device mounting system includes a device case and a mount. The device case includes: an insert including a rectangular bore and defining a set of undercut sections about the rectangular bore; and a first set of magnetic elements arranged in a first pattern about the rectangular bore. The mount includes: a body; a polygonal boss extending from the body and configured to insert into the rectangular bore; a set of locking jaws arranged on the polygonal boss configured to transiently mate with the set of undercut sections to constrain the polygonal boss within the rectangular bore; and a second set of magnetic elements arranged in a second pattern about the polygonal boss and configured to transiently couple to the first set of magnetic elements to transiently retain the mount against the device case and to drive the set of locking jaws toward the set of undercut sections.