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Contact Carrier Materials

19 bytes removed, 11:36, 8 January 2014
5.1 Copper and Copper Alloys
welded, brazed or coated by electroplating
===5.1 Copper and Copper Alloys===
====5.1.1 Standards Overview====
Copper and copper alloys to be used in electrical and electronic components
DIN 17670, DIN 1751, DIN 1791.
====5.1.2 Pure Copper====
Copper is used in electrical engineering mostly because of its high electrical
after 50% cold working
====5.1.3 High Cu Content Copper Alloys====
The high Cu content alloy materials are closest in their properties to pure copper materials. By defined addition of small amounts of alloying elements it is possible to increase the mechanical strength and especially the softening temperature of copper and at the same time decrease the electrical conductivity only insignificantly ''(Fig. 5.4)''. Silver, iron, tin, zinc, nickel, chromium, zirconium, silicon, and titanium are used. Usually the additive amounts are significantly below 3 wt%. This group of materials consists of mixed crystal as well as precipitation hardening alloys. The precipiytion hardening copper-beryllium and copper-chromium-zirconium materials are decribed later in a separate section.
Influence of small additions on the electrical conductivity of copper
====5.1.4 Naturally Hard Copper Alloys====
Alloys like brasses (CuZn), tin bronzes (CuSN), and German silver (CuNiZn), for which the required hardness is achieved by cold working are defined as naturally hard alloys. Included in this group are also the silver bronzes (CuAg) with 2 – 6 wt% of Ag.
====5.1.5 Other Naturally Hard Copper Alloys====
Main Articel: [[Other Naturally Hard Copper Alloys| Other Naturally Hard Copper Alloys]]
====5.1.6 Precipitation Hardening Copper Alloys====
Besides the naturally hard copper materials precipitation hardening copper alloys play also an important role as carrier materials for electrical contacts. By means of a suitable heat treatment finely dispersed precipitations of a second phase can be achieved which increase the mechanical strength of these copper alloys significantly.
====5.1.7 Application Properties for the Selection of Copper Alloys====
Important for the usage as spring contact components are besides mechanical strength and electrical conductivity mainly the typical spring properties such as the maximum spring bending limit and the fatigue strength as well as the bendability. During severe thermal stressing the behavior of spring materials is determined by their softening and relaxation. The following briefly describes these material properties.
====5.1.8 Selection Criteria for Copper-Based Materials====
The selection of copper-based materials from the broad spectrum of available materials must be based on the requirements of the application. First an
The increasing requirements on spring components in connectors, especially for use in automotive applications, such as higher surrounding temperatures, increased reliability, and the trend towards miniaturization led to a change of materials from traditionally CuZn30 and CuSn4 to CuNiSi alloys, for example. These CuNiSi alloys and the newer heavy duty copper alloys like CuNi1Co1 are significantly improved with regards to mechanical strength, relaxation behavior, and electrical conductivity.
 
===5.2 Nickel and Nickel Alloys===

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