Abstract: Disclosed is a billfold (10) or the like having at least one outer surface area with a woven nylon (or similar) engagement member (11, 12) and either a pocket (20) lining (14) having a complementary woven nylon engagement member (13) or a planar pocket insert (22) which is not readily removable and which includes a complementary woven nylon engagement member (23) attached co-planar to the pocket insert (22).

Abstract: Disclosed is an apparatus and method for continuously detecting skips, protrusions, protuberances and other defects in cable conductor shield, comprising a high voltage electrode, a capacitance bridge filter circuit and a corona discharge detector. A noncontacting coaxial electrode is employed to create an electric field between the cable conductor and the electrode. In the presence of this field, defects in the shield produce corona discharges. A detection circuit employing a capacitance bridge is employed to continuously detect corona discharges and produce signals used for subsequently locating the positions of the defects on the finished cable.

Abstract: A method and burner apparatus for heating and continuously melting a non-ferrous material charge, such as copper pieces in a furnace without contaminating the material charge in the furnace with non-vaporized liquid fuel thereby maintaining the metallurgical quality of the non-ferrous material charge.

Abstract: A pit cover for retaining heat in an open top, ring-shaped, carbon anode baking furnace comprises an insulating cement cast into the form of the cover, at least one metal beam embedded in the insulating cement, and a plurality of stainless steel needles interspersed substantially throughout the insulating cement for reinforcement purposes. The insulating cement has a K factor of approximately 2 to 4, a density of approximately 80 to 100 lb./ft..sup.3, a cold crushing strength in the range of 1,000 to 5,000 psi, and a low iron content, preferably, less than 2%.

Abstract: This disclosure relates to a high tensile strength aluminum alloy electrical conductor that is manufactured by alloying at least one alloying element with molten aluminum in sufficient proportion to yield intermetallic precipitates during subsequent solidification and thermomechanical processing. The conductor is in the form of a hard-drawn wire which is annealed at a temperature within the range corresponding to the onset of recovery such that there will be produced secondary intermetallic precipitates corresponding to the primary precipitates which come out of solution during casting, whereby both the primary and secondary precipitates act to pin dislocation sites between adjacent subgrain boundaries in the aluminum matrix thereby increasing the ultimate tensile strength and yield strength of the conductor.

Abstract: This disclosure relates to an aluminum alloy electrical conductor which contains from about 0.20% to about 1.60% by weight nickel, from about 0.30% to about 1.30% iron, optionally up to 2.00% of additional specified alloying elements, and the remainder aluminum with associated trace elements. The conductors are processed in a continuous operation which includes continuous casting, hot-rolling in the as-cast condition to form continuous rod, cold-working of the rod by drawing it through a series of wire-drawing dies, without preliminary or intermediate anneals, and thereafter annealing the wire to achieve a minimum electrical conductivity of 58% IACS, an ultimate tensile strength of at least 12,000 psi, a yield strength of at least 8,000 psi and an elongation of at least 12% when measured as a No. 10 AWG wire. The additional alloying elements are precisely controlled in order to facilitate the continuous processing of the cast bar without splitting and cracking of the subsequently rolled and cold-drawn rod.

Abstract: Aluminum alloy electrical conductors are produced from aluminum base alloys containing from about 0.20 percent to about 1.60 percent by weight nickel, from about 0.30 percent to 1.30 percent iron, optionally up to about 1.00 percent of additional alloying elements, the remainder being aluminum with associated trace elements. The alloy conductors have an electrical conductivity of at least fifty-seven percent (57%), based on the International Annealed Copper Standard (IACS), and improved properties of increased thermal stability, tensile strength, percent ultimate elongation, ductility, fatigue resistance and yield strength as compared to conventional aluminum alloys of similar electrical properties.