A contact assembly is for a vacuum switching apparatus. The vacuum switching apparatus includes a vacuum envelope. The vacuum envelope has an interior. The contact assembly includes: a number of electrical contacts located in the interior of the vacuum envelope, at least one electrical contact having a hole; and a number of electrodes each engaging a corresponding one of the number of electrical contacts, at least one electrode including a base and a protrusion. The protrusion extends from the base into the hole of the electrical contact in order to secure the electrical contact to the electrode.

The present invention is an electrical box cover system and method of installation that covers and protects existing electrical boxes and their electrical components. This invention prevents corrosion and the resulting damage to the mechanical and electrical components of the electrical box while ensuring the electrical box is safe to open and allowing access to the inside of the electrical box. The electrical box cover system includes a cover, fasteners, and a gasket. Generally, to install the cover, the fasteners are drilled through the cover and onto the sides of the damaged electrical box with the gasket, which is placed in the cover.

A pipe joint assembly including a first pipe element, a second pipe element, a pair of segments, each segment defining a first end and a second end, each first end comprising a tongue and each second end comprising a groove, each groove defining a groove shoulder surface, the tongue of the one segment defining a tongue outer surface, the tongue outer surface of the tongue of the one segment angled at a non-zero angle relative to the groove shoulder surface in an assembled and untightened position, the tongue outer surface of the tongue positioned parallel and flush to the groove shoulder surface of the groove of the second segment in an assembled and tightened condition; and a pair of fasteners configured to deflect each segment around the first pipe element and the second pipe element in the assembled and tightened condition.

An automated apparatus for use in selectively installing temporary fasteners in an assembly is provided. The apparatus includes an end effector, a cutting mechanism coupled to the end effector and that forms an opening in the assembly when a potential opening location is substantially aligned with a cutting mechanism center point. The apparatus also includes at least one of a first sub-assembly and a second sub-assembly coupled to the end effector. The first sub-assembly includes a temporary fastener insertion mechanism that inserts a temporary fastener through the opening in the assembly when the opening is substantially aligned with an insertion mechanism center point different from the cutting mechanism center point. The second sub-assembly includes a temporary fastener removal mechanism that removes installed temporary fasteners from the assembly when the installed temporary fastener is substantially aligned with a removal mechanism center point different from the cutting mechanism center point.

A fiber optic cassette includes a body defining a front and an opposite rear. A cable entry location is defined on the body for a cable to enter the cassette, wherein a plurality of optical fibers from the cable extend into the cassette and form terminations at non-conventional connectors adjacent the front of the body. A flexible substrate is positioned between the cable entry location and the non-conventional connectors adjacent the front of the body, the flexible substrate rigidly supporting the plurality of optical fibers. Each of the non-conventional connectors adjacent the front of the body includes a ferrule, a ferrule hub supporting the ferrule, and a split sleeve surrounding the ferrule.

A method of coupling first and second pipe elements in end-to-end facing relationship includes obtaining a coupling, the coupling including an annular gasket, at least one segment, and a fastener, each segment being approximately semi-circular and including at least two ends, each end including at least one of a tongue and a groove, each tongue protruding circumferentially from at least one end, each groove defined circumferentially in at least one end; slipping the coupling onto the first pipe element beyond any groove proximate the end of the first pipe element; aligning the second pipe element in end-to-end facing relationship with the first pipe element; slipping the coupling onto the second pipe element such that the segments of the coupling straddle the ends of the first and second pipe elements; and engaging each fastener to deform each segment into contact with the outer surfaces of the first and second pipe elements.

A hitch pin assembly for securing a shank member to a hitch receiver tube to minimize relative motion between the shank member and receiver tube, comprising an elongated pin having a threaded portion, a threaded nut, an elastomer piece, and a shank member which are mated for tightened engagement compressing the elastomer piece so as to firmly engage the receiver tube. The shank member may include a slot for a corresponding threaded nut and elastomer piece so when the pin is tightened, the nut compresses the elastomer against the interior wall of the shank surface and upwardly, thereby restraining movement of the threaded nut and dampening movement of the shank inside the hitch receiver tube.

Various connector housings for securing an optical cable, as well as methods of use and manufacture thereof are disclosed. A single-piece unitary connector housing body may include a first opening formed in a first end of the housing body, a second opening formed in a second end of the housing body, a bore through the housing body extending from the first opening to the second opening, and a back post surrounding the second opening. The first opening may be configured to receive a terminating optical cable and the second opening may be configured to receive a fiber optic cable. The back post may extend from the second opening in a longitudinal direction and may include a plurality of protrusions thereon. A length of the back post may have a concave shape.

A riveting tool configured to install a plurality of fasteners simultaneously is provided including a body having a generally central cavity. A strike surface is arranged at a first end of the body and a plurality of contactors extends generally outwards from a second, opposite end of the body. Each contactor includes an engagement surface configured to contact a surface of an adjacent fastener when a force is applied to the strike surface. A biasing mechanism is arranged within the cavity adjacent an upper cavity surface. A dowel is positioned within the cavity adjacent the biasing mechanism. The dowel is configured to engage a portion of an adjacent nut plate and translate within the cavity.

The present invention is an electrical box cover system and method of installation that covers and protects existing electrical boxes and their electrical components. This invention prevents corrosion and the resulting damage to the mechanical and electrical components of the electrical box while ensuring the electrical box is safe to open and allowing access to the inside of the electrical box. The electrical box cover system includes a cover, fasteners, and a gasket. Generally, to install the cover, the fasteners are drilled through the cover and onto the sides of the damaged electrical box with the gasket, which is placed in the cover.