Many materials are used to transmit electrical energy, but those most frequently specified are copper, copper-covered steel, high strength copper alloys, and aluminium. For more unusual applications, conductors are fabricated from pure nickel, pure silver, copper-covered aluminium, and a host of metals, metal alloys, and metal combinations.
Copper - Copper is by far the most widely used conductor material. Among its physical properties are high electrical and thermal conductivity, ductility, malleability and solderability, high melting point, and high resistance to corrosion, wear and fatigue.
Copper-covered steel - Copper-covered steel combines the conductivity and corrosion resistance of copper with the strength of steel. Three types are presently available, differing primarily in method of producing the composite metal. In one type, molten welding permanently bonds the two components; in another, a copper layer is electroplated over a steel rod; and in the third, the copper and steel are metallurgically bonded.
High Strength Alloys - Though more expensive than copper-covered steel wires, copper alloy conductors are specified because they permit significant size and/or weight reductions especially important in computer and aerospace applications. They offer high breaking strength and greater flex life with only a small increase in DC resistance. Cadmium-chromium copper, cadmium copper, chromium copper, and zirconium copper are most frequently used.
Stainless Steel - Stainless steel is used for medical lead wires and cables. Stainless steel has poor conductivity compared to copper and may have to be gold plated to improve the conductivity.
Bare Copper - Bare copper slowly combines with oxygen at room temperatures to form copper oxide. Raising the temperature accelerates this reaction, and at about 180°C and higher bright copper wire turns black in just a few minutes. Oxide film is a poor conductor of electricity and must be either removed or prevented from forming in order to assure reliability of connections. This is usually accomplished coating the copper wire with another metal which oxidizes more slowly at operating and processing temperatures. Thus, a coating is sometimes used to facilitate termination (soldering); sometimes as a processing aid (preventing oxidation of the copper at Teflon® TFE extrusion temperatures); and sometimes to offer a lower-resistance connection ("Wire-Wrap" termination). Bare copper is satisfactory at temperatures up to about 100°C.
Tinned Copper - Tinned copper conductors are a soldering aid and are usually specified where this terminating method is to be used. Suitable for conductors continually exposed to temperatures not exceeding 150°C, tinned copper conductors are slightly more expensive than bare copper wires. However, the labor savings gained by using tinned copper more than offset the additional expense, especially when manual twisting and solder dipping of the stripped lead is required.
Silver Coated Copper - Silver plated copper is made by electro-plating pure silver on 18 AWG wire which then is cold drawn to size and finally annealed. Minimum silver thickness is 40 micro-inches. Though higher in cost than tinned copper, silver-coated conductors are recommended for wires operating from above 150°C to about 200°C and in high frequency applications where, because of skin effect, higher conductivity of silver is desirable. They are readily wet by solder, permitting rapid soldering with hand irons. Care must be taken, however, to prevent solder wicking under the insulation, which may reduce conductor flex life. Silver coated copper will oxidize after a few hundred hours at 250°C.
Nickel Coated Copper - Nickel plated conductor (50 micro-inches minimum nickel thickness) is recommended for Teflon® TFE hook-up wire operating for prolonged periods at temperatures of from 200° to 260°C, and where silver coating is objectionable because of possible solder wicking. Ordinary soft solder does not wet nickel as readily as it does tin or silver. It adheres well enough to make a good termination, but will not wick into the stranded conductor beyond the joint, thereby leaving flexibility unimpaired. Connections exposed to temperatures above the melting point of soft solder require special soldering techniques. The term" nickel clad" refers to a much thicker coating - 10% to 30% of the radius of the strand.
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