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The contact parts are important components in switching devices. They have to maintain their function from the new state until the end of the functional life of the devices.
+
===2.1 Introduction===
 +
The contact parts are important components in switching devices. They have to
 +
maintain their function from the new state until the end of the functional life of the
 +
devices.
  
The requirements on contacts are rather broad. Besides typical contact properties such as
+
The requirements on contacts are rather broad. Besides typical contact properties
 +
such as
  
 
*High arc erosion resistance
 
*High arc erosion resistance
Line 9: Line 13:
 
*Good arc extinguishing capability
 
*Good arc extinguishing capability
  
They have to exhibit physical, mechanical and chemical properties like high electrical and thermal conductivity, high hardness, high corrosion resistance etc. and besides this, should have good mechanical workability and also be suitable for good weld and brazing attachment to contact carriers. In addition they must be made from environmentally friendly materials.
+
they have to exhibit physical, mechanical, and chemical properties like high electrical
 +
and thermal conductivity, high hardness, high corrosion resistance, etc and besides
 +
this should have good mechanical workability, and also be suitable for good weld and
 +
brazing attachment to contact carriers. In addition they must be made from
 +
environmentally friendly materials.
  
Materials suited for use as electrical contacts can be divided into the following groups based on their composition and metallurgical structure:
+
Materials suited for use as electrical contacts can be divided into the following groups
 +
based on their composition and metallurgical structure:
  
 
*Pure metals
 
*Pure metals
 
*Alloys
 
*Alloys
 
*Composite materials
 
*Composite materials
 +
*Pure metals
  
 +
From this group silver has the greatest importance for switching devices in the higher
 +
energy technology. Other precious metals such as gold and platinum are only used in
 +
applications for the information technology in the form of thin surface layers. As a nonprecious
 +
metal tungsten is used for some special applications such as for example as
 +
automotive horn contacts. In some rarer cases pure copper is used but mainly paired
 +
to a silver-based contact material.
  
'''Pure metals'''
+
*Alloys
 
 
Within this group, silver has the greatest importance for switching devices in the higher energy technology. Other precious metals such as gold and platinum are only used in applications for the information technology in the form of thin surface layers. As a nonprecious metal, tungsten is used for some special applications such as, for example, automotive horn contacts. In some rarer cases, pure copper is used, but mainly paired to a silver-based contact material.
 
 
 
'''Alloys'''
 
 
 
Besides these few pure metals, a larger number of alloy materials made by melt technology are available for the use as contacts. An alloy is characterized by the fact, that its components are completely or partially soluble in each other in the solid state. Phase diagrams for multiple metal compositions show the number and type of the crystal structure as a function of the temperature and composition of the alloying components.
 
  
They indicate the boundaries of liquid and solid phases and define the parameters of solidification.
+
Besides these few pure metals a larger number of alloy materials made by melt
Alloying allows to improve the properties of one material at the cost of changing them for the second material. As an example, the hardness of a base metal may be increased while at the same time the electrical conductivity decreases with even small additions of the second alloying component.
+
technology are available for the use as contacts. An alloy is characterized by the fact
 +
that its components are completely or partially soluble in each other in the solid state.
 +
Phase diagrams for multiple metal compositions show the number and type of the
 +
crystal structure as a function of the temperature and composition of the alloying components.
  
'''Composite Materials'''
+
They indicate the boundaries of liquid and solid phases and define the
 +
parameters of solidification.
 +
Alloying allows to improve the properties of one material at the cost of changing
 +
them for the second material. As an example, the hardness of a base metal may
 +
be increased while at the same time the electrical conductivity decreases with
 +
even small additions of the second alloying component.
  
Composite materials are a material group whose properties are of great importance for electrical contacts that are used in switching devices for higher
+
*Composite Materials
electrical currents.
 
  
Those used in electrical contacts are heterogeneous materials, composed of two or more uniformly dispersed components, in which the largest volume portion consists of a metal.
+
Composite materials are a material group whose properties are of great
 +
importance for electrical contacts that are used in switching devices for higher
 +
electrical currents.
 +
Those used in electrical contacts are heterogeneous materials composed of two
 +
or more uniformly dispersed components in which the largest volume portion
 +
consists of a metal.
 +
The properties of composite materials are determined mainly independent from
 +
each other by the properties of their individual components. Therefore it is for
 +
example possible to combine the high melting point and arc erosion resistance
 +
of tungsten with the low melting and good electrical conductivity of copper, or
 +
the high conductivity of silver with the weld resistant metalloid graphite.
  
The properties of composite materials are determined mainly independent from each other by the properties of their individual components. Therefore it is, for example, possible to combine the high melting point and arc erosion resistance of tungsten with the low melting and good electrical conductivity of copper or the high conductivity of silver with the weld resistant metalloid graphite. <xr id="fig:Powder metallurgical manufacturing of composite materials (schematic)"/> shows the schematic manufacturing processes from powder blending to contact material. Three basic process variations are typically applied:
+
Figure 2.1 shows the schematic manufacturing processes from powder
 +
blending to contact material. Three basic process variations are typically
 +
applied:
  
 
*Sintering without liquid phase (Press-Sinter-Repress, PSR)
 
*Sintering without liquid phase (Press-Sinter-Repress, PSR)
Line 42: Line 71:
 
*Infiltration (Press-Sinter-Infiltrate, PSI)
 
*Infiltration (Press-Sinter-Infiltrate, PSI)
  
<figure id="fig:Powder metallurgical manufacturing of composite materials (schematic)">
+
During sintering without a liquid phase (left side of schematic) the powder mix is
[[File:Powder metallurgical manufacturing of composite materials (schematic).jpg|thumb|<caption>Powder-metallurgical manufacturing of composite materials (schematic) T<sub>s</sub> = Melting point of the lower melting component)</caption>]]
+
first densified by pressing, then undergoes a heat treatment (sintering), and
</figure>
+
eventually is re-pressed again to further increase the density. The sintering
 +
atmosphere depends on the material components and later application; a
 +
vacuum is used for example for the low gas content material Cu/Cr. This
 +
process is used for individual contact parts and also termed press-sinterrepress
 +
(PSR). For materials with high silver content the starting point at
 +
pressing is most a larger block (or billet) which is then after sintering hot
 +
extruded into wire, rod, or strip form. The extrusion further increases the density
 +
of these composite materials and contributes to higher arc erosion resistance.
 +
Materials such as Ag/Ni, Ag/MeO, and Ag/C are typically produced by this
 +
process.
 +
 
 +
Sintering with liquid phase has the advantage of shorter process times due to
 +
the accelerated diffusion and also results in near-theoretical densities of the
  
During ''sintering without a liquid phase'' (left side of schematic), the powder mix is first densified by pressing, then undergoes a heat treatment (sintering) and eventually is re-pressed again to further increase the density. The sintering atmosphere depends on the material components and later application; a vacuum is used for example for the low gas content material Cu/Cr. This process is used for individual contact parts and also termed press-sinter-repress (PSR). For materials with high silver content, the starting point before pressing is mostly a large block (or billet) which is then, after sintering, hot extruded into wire, rod or strip form. The extrusion further increases the density of these composite materials and contributes to higher arc erosion resistance. Materials such as Ag/Ni, Ag/MeO and Ag/C are typically produced by this process.
+
Fig. 2.1: Powder-metallurgical manufacturing of composite materials (schematic)
 +
T = Melting point of the lower melting component
  
''Sintering with liquid phase'' has the advantage of shorter process times due to the accelerated diffusion and also results in near-theoretical densities of the composite material. To ensure the shape stability during the sintering process, it
+
composite material. To ensure the shape stability during the sintering process it
 
is however necessary to limit the volume content of the liquid phase material.
 
is however necessary to limit the volume content of the liquid phase material.
  
As opposed to the liquid phase sintering, which has limited use for electrical contact manufacturing, the ''Infiltration process'' as shown on the right side of the schematic, has a broad practical range of applications. In this process the powder of the higher melting component, sometimes also as a powder mix with a small amount of the second material, is pressed into parts. Then, right after sintering, the porous skeleton is infiltrated with liquid metal of the second material. The fill-up process of the pores happens through capillary forces. This process reaches, after the infiltration, near-theoretical density without subsequent pressing and is widely used for Ag- and Cu-refractory contacts. For Ag/W or Ag/WC contacts, controlling the amount or excess on the bottom side of the contact of the infiltration metal Ag, results in contact tips that can be easily attached to their carriers by resistance welding. For larger Cu/W contacts, additional machining is often used to obtain the final shape of the contact component.
+
As opposed to the liquid phase sintering which has limited use for electrical
 
+
contact manufacturing, the Infiltration process as shown on the right side of the
==Gold Based Materials==
+
schematic has a broad practical range of applications. In this process the
 
+
powder of the higher melting component sometimes also as a powder mix with
Pure Gold is besides Platinum the chemically most stable of all precious metals. In its pure form, it is not very suitable for use as a contact material in electromechanical devices because of its tendency to stick and cold-weld at even  low contact forces. In addition, it is not hard or strong enough to resist mechanical wear and exhibits high material losses under electrical arcing loads. This limits its use in form of thin electroplated or vacuum deposited layers.
+
a small amount of the second material is pressed into parts and after sintering
 
+
the porous skeleton is infiltrated with liquid metal of the second material. The
Main Article: [[Gold Based Materials| Gold Based Materials]]
+
filling up of the pores happens through capillary forces. This process reaches
 
+
after the infiltration near-theoretical density without subsequent pressing and is
==Platinum Metal Based Materials==
+
widely used for Ag- and Cu-refractory contacts. For Ag/W or Ag/WC contacts,
 
+
controlling the amount or excess on the bottom side of the contact of the
The platinum group metals include the elements Pt, Pd, Rh, Ru, Ir and Os ([[Platinum_Metal_Based_Materials|Table 1]]<!--(Table 2.6)-->). For electrical contacts, platinum and palladium have practical significance as base alloy materials and ruthenium and iridium are used as alloying components. Pt and Pd have similar corrosion resistance as gold but due to their catalytical properties, they tend to polymerize adsorbed organic vapors on contact surfaces. During frictional movement between contact surfaces, the polymerized compounds known as “brown powder” are formed, which can lead to a significant increase in contact resistance. Therefore Pt and Pd are typically used as alloys and are rather not used in their pure form for electrical contact applications.
+
infiltration metal Ag results in contact tips that can be easily attached to their
 
+
carriers by resistance welding. For larger Cu/W contacts additional machining is
Main Article: [[Platinum Metal Based Materials| Platinum Metal Based Materials]]
+
often used to obtain the final shape of the contact component.
 
 
==Silver Based Materials==
 
 
 
Main Article: [[Silver Based Materials| Silver Based Materials]]
 
 
 
==Tungsten and Molybdenum Based Materials==
 
 
 
Main Article: [[Tungsten and Molybdenum Based Materials| Tungsten and Molybdenum Based Materials]]
 
 
 
==Contact Materials for Vacuum Switches==
 
 
 
The low gas content contact materials are developed for the use in vacuum switching devices. 
 
 
 
Main Article: [[Contact Materials for Vacuum Switches| Contact Materials for Vacuum Switches]]
 
 
 
==References==
 
 
 
Vinaricky, E.(Hrsg.): Elektrische Kontakte, Werkstoffe und Anwendungen.
 
Springer-Verlag, Berlin, Heidelberg etc. 2002
 
 
 
Lindmayer, M.: Schaltgeräte-Grundlagen, Aufbau, Wirkungsweise.
 
Springer-Verlag, Berlin, Heidelberg, New York, Tokio, 1987
 
 
 
Rau, G.: Metallische Verbundwerkstoffe. Werkstofftechnische
 
Verlagsgesellschaft, Karlsruhe 1977
 
 
 
Schreiner, H.: Pulvermetallurgie elektrischer Kontakte. Springer-Verlag
 
Berlin, Göttingen, Heidelberg, 1964
 
 
 
Hansen. M.; Anderko, K.: Constitution of Binary Alloys. New York:
 
Mc Graw-Hill, 1958
 
 
 
Shunk, F.A.: Constitution of Binary Alloy. 2 Suppl. New York; Mc Graw-Hill, 1969
 
 
 
Edelmetall-Taschenbuch. ( Herausgeber Degussa AG, Frankfurt a. M.),
 
Heidelberg, Hüthig-Verlag, 1995
 
 
 
Rau, G.: Elektrische Kontakte-Werkstoffe und Technologie. Eigenverlag G. Rau
 
GmbH & Co., Pforzheim, 1984
 
 
 
Heraeus, W. C.: Werkstoffdaten. Eigenverlag W.C. Heraeus, Hanau, 1978
 
 
 
Linde, J.O.: Elektrische Widerstandseigenschaften der verdünnten Legierungen
 
des Kupfers, Silbers und Goldes. Lund: Hakan Ohlsson, 1938
 
 
 
Engineers Relay Handbook, RSIA, 2006
 
 
 
Großmann, H. Saeger, K. E.; Vinaricky, E.: Gold and Gold Alloys in Electrical
 
Engineering. in: Gold, Progress in Chemistry, Biochemistry and Technology. John
 
Wiley & Sons, Chichester etc, (1999) 199-236
 
 
 
Gehlert, B.: Edelmetall-Legierungen für elektrische Kontakte.
 
Metall 61 (2007) H. 6, 374-379
 
 
 
Aldinger, F.; Schnabl, R.: Edelmetallarme Kontakte für kleine Ströme.
 
Metall 37 (1983) 23-29
 
 
 
Bischoff, A.; Aldinger, F.: Einfluss geringer Zusätze auf die mechanischen
 
Eigenschaften von Au-Ag-Pd-Legierungen. Metall 36 (1982) 752-765
 
 
 
Wise, E.M.: Palladium, Recovery, Properties and Uses. New York, London:
 
Academic Press 1968
 
 
 
Savitskii, E.M.; Polyakova, V.P.; Tylina, M.A.: Palladium Alloys, Primary Sources.
 
New York: Publishers 1969
 
 
 
Gehlert, B.: Lebensdaueruntersuchungen von Edelmetall Kontaktwerkstoff-
 
Kombinationen für Schleifringübertrager. VDE-Fachbericht 61, (2005) 95-100
 
 
 
Holzapfel,C.: Verschweiß und elektrische Eigenschaften von
 
Schleifringübertragern. VDE-Fachbericht 67 (2011) 111-120
 
 
 
Schnabl, R.; Gehlert, B.: Lebensdauerprüfungen von Edelmetall-
 
Schleifkontaktwerkstoffen für Gleichstrom Kleinmotoren.
 
Feinwerktechnik & Messtechnik (1984) 8, 389-393
 
 
 
Kobayashi, T.; Koibuchi, K.; Sawa, K.; Endo, K.; Hagino, H.: A Study of Lifetime
 
of Au-plated Slip-Ring and AgPd Brush System for Power Supply.
 
th Proc. 24 Int. Conf. on Electr. Contacts, Saint Malo, France 2008, 537-542
 
 
 
Harmsen, U.; Saeger K.E.: Über das Entfestigungsverhalten von Silber
 
verschiedener Reinheiten. Metall 28 (1974) 683-686
 
 
 
Behrens, V.; Michal, R.; Minkenberg, J.N.; Saeger, K.E.: Abbrand und
 
Kontaktwiderstandsverhalten von Kontaktwerkstoffen auf Basis von Silber-
 
Nickel. e.& i. 107. Jg. (1990), 2, 72-77
 
 
 
Behrens, V.: Silber/Nickel und Silber/Grafit- zwei Spezialisten auf dem Gebiet
 
der Kontaktwerkstoffe. Metall 61 (2007) H.6, 380-384
 
 
 
Rieder, W.: Silber / Metalloxyd-Werkstoffe für elektrische Kontakte,
 
VDE - Fachbericht 42 (1991) 65-81
 
 
 
Harmsen,U.: Die innere Oxidation von AgCd-Legierungen unter
 
Sauerstoffdruck.
 
Metall 25 (1991), H.2, 133-137
 
 
 
Muravjeva, E.M.; Povoloskaja, M.D.: Verbundwerkstoffe Silber-Zinkoxid und
 
Silber-Zinnoxid, hergestellt durch Oxidationsglühen.
 
Elektrotechnika 3 (1965) 37-39
 
 
 
Behrens, V.; Honig Th.; Kraus, A.; Michal, R.; Saeger, K.-E.; Schmidberger, R.;
 
Staneff, Th.: Eine neue Generation von AgSnO<sub>2</sub> -Kontaktwerkstoffen.
 
VDE-Fachbericht 44, (1993) 99-114
 
 
 
Braumann, P.; Lang, J.: Kontaktverhalten von Ag-Metalloxiden für den Bereich
 
hoher Ströme. VDE-Fachbericht 42, (1991) 89-94
 
 
 
Hauner, F.; Jeannot, D.; Mc Neilly, U.; Pinard, J.: Advanced AgSnO Contact 2
 
th Materials for High Current Contactors. Proc. 20 Int. Conf. on Electr. Contact
 
Phenom., Stockholm 2000, 193-198
 
 
 
Wintz, J.-L.; Hardy, S.; Bourda, C.: Influence on the Electrical Performances of
 
Assembly Process, Supports Materials and Production Means for AgSnO<sub>2</sub> .
 
Proc.24<sub>th</sub> Int. Conf. on Electr. Contacts, Saint Malo, France 2008, 75-81
 
 
 
Behrens, V.; Honig, Th.; Kraus, A.; Michal, R.: Schalteigenschaften von
 
verschiedenen Silber-Zinnoxidwerkstoffen in Kfz-Relais. VDE-Fachbericht 51
 
(1997) 51-57
 
 
 
Schöpf, Th.: Silber/Zinnoxid und andere Silber-Metalloxidwerkstoffe in
 
Netzrelais. VDE-Fachbericht 51 (1997) 41-50
 
 
 
Schöpf, Th.; Behrens, V.; Honig, Th.; Kraus, A.: Development of Silver Zinc
 
th Oxide for General-Purpose Relays. Proc. 20 Int. Conf. on Electr. Contacts,
 
Stockholm 2000, 187-192
 
 
 
Braumann, P.; Koffler, A.: Einfluss von Herstellverfahren, Metalloxidgehalt und
 
Wirkzusätzen auf das Schaltverhalten von Ag/SnO in Relais. 2
 
VDE-Fachbericht 59, (2003) 133-142
 
 
 
Kempf, B.; Braumann, P.; Böhm, C.; Fischer-Bühner, J.: Silber-Zinnoxid-
 
Werkstoffe: Herstellverfahren und Eigenschaften. Metall 61(2007) H. 6, 404-408
 
 
 
Lutz, O.; Behrens, V.; Finkbeiner, M.; Honig, T.; Späth, D.: Ag/CdO-Ersatz in
 
Lichtschaltern. VDE-Fachbericht 61, (2005) 165-173
 
 
 
Lutz, O.; Behrens, V.; Wasserbäch, W.; Franz, S.; Honig, Th.; Späth,
 
D.; Heinrich, J.: Improved Silver/Tin Oxide Contact Materials for Automotive
 
th Applications. Proc.24 Int. Conf. on Electr. Contacts, Saint Malo, France 2008,
 
88-93
 
 
 
Leung, C.; Behrens, V.: A Review of Ag/SnO Contact Materials and Arc Erosion. 2
 
th Proc.24 Int. Conf. on Electr. Contacts, Saint Malo, France 2008, 82-87
 
 
 
Chen, Z.K.; Witter, G.J.: Comparison in Performance for Silver–Tin–Indium
 
Oxide Materials Made by Internal Oxidation and Powder Metallurgy.
 
th Proc. 55 IEEE Holm Conf. on Electrical Contacts, Vancouver, BC, Canada,
 
(2009) 167 – 176
 
 
 
Roehberg, J.; Honig, Th.; Witulski, N.; Finkbeiner, M.; Behrens, V.: Performance
 
of Different Silver/Tin Oxide Contact Materials for Applications in Low Voltage
 
th Circuit Breakers. Proc. 55 IEEE Holm Conf. on Electrical Contacts, Vancouver,
 
BC, Canada, (2009) 187 – 194
 
 
 
Muetzel, T.; Braumann, P.; Niederreuther, R.: Temperature Rise Behavior of
 
th Ag/SnO Contact Materials for Contactor Applications. Proc. 55 IEEE Holm 2
 
Conf. on Electrical Contacts, Vancouver, BC, Canada, (2009) 200 – 205
 
 
 
Lutz, O. et al.: Silber/Zinnoxid – Kontaktwerkstoffe auf Basis der Inneren
 
Oxidation fuer AC – und DC – Anwendungen.
 
VDE Fachbericht 65 (2009) 167 – 176
 
 
 
Harmsen, U.; Meyer, C.L.: Mechanische Eigenschaften stranggepresster Silber-
 
Graphit-Verbundwerkstoffe. Metall 21 (1967), 731-733
 
 
 
Behrens, V.: Mahle, E.; Michal, R.; Saeger, K.E.: An Advanced Silver/Graphite
 
th Contact Material Based on Graphite Fibre. Proc. 16 Int. Conf. on Electr.
 
Contacts, Loghborough 1992, 185-189
 
 
 
Schröder, K.-H.; Schulz, E.-D.: Über den Einfluss des Herstellungsverfahrens
 
th auf das Schaltverhalten von Kontaktwerkstoffen der Energietechnik. Proc. 7 Int.
 
Conf. on Electr. Contacts, Paris 1974, 38-45
 
 
 
Mützel, T.: Niederreuther, R.: Kontaktwerkstoffe für Hochleistungsanwendungen.
 
VDE-Bericht 67 (2011) 103-110
 
 
 
Lambert, C.; Cambon, G.: The Influence of Manufacturing Conditions and
 
Metalurgical Characteristics on the Electrical Behaviour of Silver-Graphite
 
th Contact Materials. Proc. 9 Int. Conf.on Electr. Contacts,
 
Chicago 1978, 401-406
 
 
 
Vinaricky, E.: Grundsätzliche Untersuchungen zum Abbrand- und
 
Schweißverhalten von Ag/C-Kontaktwerkstoffen. VDE-Fachbericht 47 (1995)
 
159-169
 
 
 
Agte, C.; Vacek, J.: Wolfram und Molybdän. Berlin: Akademie-Verlag 1959
 
 
 
Keil, A.; Meyer, C.-L.: Der Einfluß des Faserverlaufes auf die elektrische
 
Verschleißfestigkeit von Wolfram-Kontakten. ETZ 72, (1951) 343-346
 
 
 
Slade, P. G.: Electric Contacts for Power Interruption. A Review. Proc. 19 Int.
 
Conf. on Electric Contact Phenom. Nuremberg (Germany) 1998, 239-245
 
 
 
Slade, P. G.: Variations in Contact Resistance Resulting from Oxide Formation
 
and Decomposition in AgW and Ag-WC-C Contacts Passing Steady Currents
 
for Long Time Periods. IEEE Trans. Components, Hybrids and Manuf. Technol.
 
CHMT-9,1 (1986) 3-16
 
 
 
Slade, P. G.: Effect of the Electric Arc and the Ambient Air on the Contact
 
Resistance of Silver, Tungsten and Silver-Tungsten Contacts.
 
J.Appl.Phys. 47, 8 (1976) 3438-3443
 
  
Lindmayer, M.; Roth, M.: Contact Resistance and Arc-Erosion of W-Ag and
+
===2.2 Gold Based Materials===
WC-Ag. IEEE Trans components, Hybrids and Manuf. Technol.
 
CHMT-2, 1 (1979) 70-75
 
  
Leung, C.-H.; Kim, H.J.: A Comparison of Ag/W, Ag/WC and Ag/Mo Electrical
+
Pure Gold is besides Platinum the chemically most stable of all precious metals.
Contacts. IEEE Trans. Components, Hybrids, Manuf. Technol.,
+
In its pure form it is not very suitable for use as a contact material in
Vol. CHMT-7, 1 (1984) 69-75
+
electromechanical devices because of its tendency to stick and cold-weld at even
 +
low contact forces. In addition it is not hard or strong enough to resist
 +
mechanical wear and exhibits high materials losses under electrical arcing
 +
loads. This limits its use in form of thin electroplated or vacuum deposited layers.
  
Allen, S.E.; Streicher, E.: The Effect of Microstructure on the Electrical
+
For most electrical contact applications gold alloys are used. Depending on the
th Performance of Ag-WC-C Contact Materials. Proc. 44 IEEE Holm Conf. on Electr.
+
alloying metal the melting is performed either under in a reducing atmosphere or
Contacts, Arlington, VA, USA (1998), 276-285
+
in a vacuum. The choice of alloying metals depends on the intended use of the
 +
resulting contact material. The binary Au alloys with typically <10 wt% of other
 +
precious metals such as Pt, Pd, or Ag or non-precious metals like Ni, Co, and
 +
Cu are the more commonly used ones (Table 2.2). On one hand these alloy
 +
additions improve the mechanical strength and electrical switching properties
 +
but on the other hand reduce the electrical conductivity and chemical corrosion
 +
resistance (Fig. 2.2) to varying degrees.
 +
Under the aspect of reducing the gold content ternary alloys with a gold content
 +
of approximately 70 wt% and additions of Ag and Cu or Ag and Ni resp., for
 +
example AuAg25Cu5 or AuAg20Cu10 are used which exhibit for many
 +
applications good mechanical stability while at the same time have sufficient
 +
resistance against the formation of corrosion layers (Table 2.3). Other ternary
 +
alloys based on the AuAg system are AuAg26Ni3 and AuAg25Pt6. These alloys
 +
are mechanically similar to the AuAgCu alloys but have significantly higher
 +
oxidation resistance at elevated temperatures (Table 2.4).
 +
Caused by higher gold prices over the past years the development of alloys with
 +
further reduced gold content had a high priority. The starting point has been the
 +
AuPd system which has continuous solubility of the two components. Besides
 +
the binary alloy of AuPd40 and the ternary one AuPd35Ag9 other multiple
 +
component alloys were developed. These alloys typically have < 50 wt% Au and
 +
often can be solution hardened in order to obtain even higher hardness and
 +
tensile strength. They are mostly used in sliding contact applications.
 +
Gold alloys are used in the form of welded wire or profile (also called weldtapes),
 +
segments, contact rivets, and stampings produced from clad strip
 +
materials. The selection of the bonding process is based on the cost for the
 +
joining process, and most importantly on the economical aspect of using the
 +
least possible amount of the expensive precious metal component.
 +
Besides being used as switching contacts in relays and pushbuttons, gold
 +
alloys are also applied in the design of connectors as well as sliding contacts for
 +
potentiometers, sensors, slip rings, and brushes in miniature DC motors
 +
(Table 2.5).
  
Haufe, W.; Reichel, W.; Schreiner H.: Abbrand verschiedener W/Cu-Sinter-
+
Table 2.3: Mechanical Properties of Gold and Gold-Alloys
Tränkwerkstoffe an Luft bei hohen Strömen. Z. Metallkd. 63 (1972) 651-654
 
  
Althaus, B.; Vinaricky, E.: Das Abbrandverhalten verschieden hergestellter
+
Table 2.1: Commonly Used Grades of Gold
Wolfram-Kupfer-Verbundwerkstoffe im Hochstromlichtbogen.
 
Metall 22 (1968) 697-701
 
  
Gessinger, G.H.; Melton, K.N.: Burn-off Behaviour of WCu Contact Materials in an
+
Table 2.2: Physical Properties of Gold and Gold-Alloys
Electric Arc. Powder Metall. Int. 9 (1977) 67-72
 
  
Magnusson, M.: Abbrandverhalten und Rißbildung bei WCu-Tränkwerkstoffen
+
Fig. 2.2:
unterschiedlicher Wolframteilchengröße. ETZ-A 98 (1977) 681-683
+
Influence of 1-10 atomic% of different
 +
alloying metals on the electrical resistivity of gold
 +
(according to J. O. Linde)
  
Heitzinger, F.; Kippenberg, H.; Saeger, K.E.; Schröder, K.H.: Contact Materials for
+
Fig. 2.3:
Vacuum Switching Devices. Proc. XVth ISDEIV, Darmstadt 1992, 273-278
+
Phase diagram
 +
of goldplatinum
  
Grill, R.; Müller, F.: Verbundwerkstoffe auf Wolframbasis für
+
Fig. 2.4:
Hochspannungsschaltgeräte. Metall 61 (2007) H. 6, 390-393
+
Phase diagram
 +
of gold-silver
  
Slade, P.: G.: The Vacuum Interrupter- Theory; Design; and Application. CRC
+
Fig. 2.5:
Press, Boca Raton, FL (USA), 2008
+
Phase diagram
 +
of gold-copper
  
Frey, P.; Klink, N.; Saeger, K.E.: Untersuchungen zum Abreißstromverhalten von
+
Fig. 2.6: Phase diagram of gold-nickel
Kontaktwerkstoffen für Vakuumschütze. Metall 38 (1984) 647-651
 
  
Frey, P.; Klink, N.; Michal, R.; Saeger, K.E.: Metallurgical Aspects of Contact
+
Fig. 2.7: Phase diagram of gold-cobalt
Materials for Vacuum Switching Devices. IEEE Trans. Plasma Sc. 17, (1989) 743-
 
740
 
  
Slade, P.: Advances in Material Development for High Power Vacuum Interrupter
+
Fig. 2.8:
th Contacts. Proc.16 Int. Conf. on Electr. Contact Phenom.,
+
Strain hardening
Loughborough 1992,1-10
+
of Au by cold working
  
Behrens, V.; Honig, Th.; Kraus, A.; Allen, S.: Comparison of Different Contact
+
Fig. 2.9:
th Materials for Low Voltage Vacuum Applications. Proc.19 Int. Conf. on Electr.
+
Softening of Au after annealing
Contact Phenom., Nuremberg 1998, 247-251
+
for 0.5 hrs after 80%
 +
cold working
  
Rolle, S.; Lietz, A.; Amft, D.; Hauner, F.: CuCr Contact Material for Low Voltage
+
Fig. 2.10:
th Vacuum Contactors. Proc. 20 int. Conf. on Electr. Contact. Phenom. Stockholm
+
Strain hardening of
2000, 179-186
+
AuPt10 by cold working
  
Kippenberg, H.: CrCu as a Contact Material for Vacuum Interrupters.
+
Fig. 2.11:
th Proc.13 Int. Conf. on Electr. Contact Phenom. Lausanne 1986, 140-144
+
Strain hardening
 +
of AuAg20 by cold working
  
Hauner, F.; Müller, R.; Tiefel, R.: CuCr für Vakuumschaltgeräte-
+
Fig. 2.12:
Herstellungsverfahren, Eigenschaften und Anwendung.
+
Strain hardening of
Metall 61 (2007) H. 6, 385-389
+
AuAg30 by cold working
  
Manufacturing Equipment for Semi-Finished Materials
+
Fig. 2.13:
(Bild)
+
Strain hardening of AuNi5
 +
by cold working
  
[[de:Kontaktwerkstoffe_für_die_Elektrotechnik]]
+
Fig. 2.14:
 +
Softening
 +
of AuNi5 after annealing
 +
for 0.5 hrs after 80%
 +
cold working

Revision as of 12:00, 3 December 2013

2.1 Introduction

The contact parts are important components in switching devices. They have to maintain their function from the new state until the end of the functional life of the devices.

The requirements on contacts are rather broad. Besides typical contact properties such as

  • High arc erosion resistance
  • High resistance against welding
  • Low contact resistance
  • Good arc moving properties
  • Good arc extinguishing capability

they have to exhibit physical, mechanical, and chemical properties like high electrical and thermal conductivity, high hardness, high corrosion resistance, etc and besides this should have good mechanical workability, and also be suitable for good weld and brazing attachment to contact carriers. In addition they must be made from environmentally friendly materials.

Materials suited for use as electrical contacts can be divided into the following groups based on their composition and metallurgical structure:

  • Pure metals
  • Alloys
  • Composite materials
  • Pure metals

From this group silver has the greatest importance for switching devices in the higher energy technology. Other precious metals such as gold and platinum are only used in applications for the information technology in the form of thin surface layers. As a nonprecious metal tungsten is used for some special applications such as for example as automotive horn contacts. In some rarer cases pure copper is used but mainly paired to a silver-based contact material.

  • Alloys

Besides these few pure metals a larger number of alloy materials made by melt technology are available for the use as contacts. An alloy is characterized by the fact that its components are completely or partially soluble in each other in the solid state. Phase diagrams for multiple metal compositions show the number and type of the crystal structure as a function of the temperature and composition of the alloying components.

They indicate the boundaries of liquid and solid phases and define the parameters of solidification. Alloying allows to improve the properties of one material at the cost of changing them for the second material. As an example, the hardness of a base metal may be increased while at the same time the electrical conductivity decreases with even small additions of the second alloying component.

  • Composite Materials

Composite materials are a material group whose properties are of great importance for electrical contacts that are used in switching devices for higher electrical currents. Those used in electrical contacts are heterogeneous materials composed of two or more uniformly dispersed components in which the largest volume portion consists of a metal. The properties of composite materials are determined mainly independent from each other by the properties of their individual components. Therefore it is for example possible to combine the high melting point and arc erosion resistance of tungsten with the low melting and good electrical conductivity of copper, or the high conductivity of silver with the weld resistant metalloid graphite.

Figure 2.1 shows the schematic manufacturing processes from powder blending to contact material. Three basic process variations are typically applied:

  • Sintering without liquid phase (Press-Sinter-Repress, PSR)
  • Sintering with liquid phase
  • Infiltration (Press-Sinter-Infiltrate, PSI)

During sintering without a liquid phase (left side of schematic) the powder mix is first densified by pressing, then undergoes a heat treatment (sintering), and eventually is re-pressed again to further increase the density. The sintering atmosphere depends on the material components and later application; a vacuum is used for example for the low gas content material Cu/Cr. This process is used for individual contact parts and also termed press-sinterrepress (PSR). For materials with high silver content the starting point at pressing is most a larger block (or billet) which is then after sintering hot extruded into wire, rod, or strip form. The extrusion further increases the density of these composite materials and contributes to higher arc erosion resistance. Materials such as Ag/Ni, Ag/MeO, and Ag/C are typically produced by this process.

Sintering with liquid phase has the advantage of shorter process times due to the accelerated diffusion and also results in near-theoretical densities of the

Fig. 2.1: Powder-metallurgical manufacturing of composite materials (schematic) T = Melting point of the lower melting component

composite material. To ensure the shape stability during the sintering process it is however necessary to limit the volume content of the liquid phase material.

As opposed to the liquid phase sintering which has limited use for electrical contact manufacturing, the Infiltration process as shown on the right side of the schematic has a broad practical range of applications. In this process the powder of the higher melting component sometimes also as a powder mix with a small amount of the second material is pressed into parts and after sintering the porous skeleton is infiltrated with liquid metal of the second material. The filling up of the pores happens through capillary forces. This process reaches after the infiltration near-theoretical density without subsequent pressing and is widely used for Ag- and Cu-refractory contacts. For Ag/W or Ag/WC contacts, controlling the amount or excess on the bottom side of the contact of the infiltration metal Ag results in contact tips that can be easily attached to their carriers by resistance welding. For larger Cu/W contacts additional machining is often used to obtain the final shape of the contact component.

2.2 Gold Based Materials

Pure Gold is besides Platinum the chemically most stable of all precious metals. In its pure form it is not very suitable for use as a contact material in electromechanical devices because of its tendency to stick and cold-weld at even low contact forces. In addition it is not hard or strong enough to resist mechanical wear and exhibits high materials losses under electrical arcing loads. This limits its use in form of thin electroplated or vacuum deposited layers.

For most electrical contact applications gold alloys are used. Depending on the alloying metal the melting is performed either under in a reducing atmosphere or in a vacuum. The choice of alloying metals depends on the intended use of the resulting contact material. The binary Au alloys with typically <10 wt% of other precious metals such as Pt, Pd, or Ag or non-precious metals like Ni, Co, and Cu are the more commonly used ones (Table 2.2). On one hand these alloy additions improve the mechanical strength and electrical switching properties but on the other hand reduce the electrical conductivity and chemical corrosion resistance (Fig. 2.2) to varying degrees. Under the aspect of reducing the gold content ternary alloys with a gold content of approximately 70 wt% and additions of Ag and Cu or Ag and Ni resp., for example AuAg25Cu5 or AuAg20Cu10 are used which exhibit for many applications good mechanical stability while at the same time have sufficient resistance against the formation of corrosion layers (Table 2.3). Other ternary alloys based on the AuAg system are AuAg26Ni3 and AuAg25Pt6. These alloys are mechanically similar to the AuAgCu alloys but have significantly higher oxidation resistance at elevated temperatures (Table 2.4). Caused by higher gold prices over the past years the development of alloys with further reduced gold content had a high priority. The starting point has been the AuPd system which has continuous solubility of the two components. Besides the binary alloy of AuPd40 and the ternary one AuPd35Ag9 other multiple component alloys were developed. These alloys typically have < 50 wt% Au and often can be solution hardened in order to obtain even higher hardness and tensile strength. They are mostly used in sliding contact applications. Gold alloys are used in the form of welded wire or profile (also called weldtapes), segments, contact rivets, and stampings produced from clad strip materials. The selection of the bonding process is based on the cost for the joining process, and most importantly on the economical aspect of using the least possible amount of the expensive precious metal component. Besides being used as switching contacts in relays and pushbuttons, gold alloys are also applied in the design of connectors as well as sliding contacts for potentiometers, sensors, slip rings, and brushes in miniature DC motors (Table 2.5).

Table 2.3: Mechanical Properties of Gold and Gold-Alloys

Table 2.1: Commonly Used Grades of Gold

Table 2.2: Physical Properties of Gold and Gold-Alloys

Fig. 2.2: Influence of 1-10 atomic% of different alloying metals on the electrical resistivity of gold (according to J. O. Linde)

Fig. 2.3: Phase diagram of goldplatinum

Fig. 2.4: Phase diagram of gold-silver

Fig. 2.5: Phase diagram of gold-copper

Fig. 2.6: Phase diagram of gold-nickel

Fig. 2.7: Phase diagram of gold-cobalt

Fig. 2.8: Strain hardening of Au by cold working

Fig. 2.9: Softening of Au after annealing for 0.5 hrs after 80% cold working

Fig. 2.10: Strain hardening of AuPt10 by cold working

Fig. 2.11: Strain hardening of AuAg20 by cold working

Fig. 2.12: Strain hardening of AuAg30 by cold working

Fig. 2.13: Strain hardening of AuNi5 by cold working

Fig. 2.14: Softening of AuNi5 after annealing for 0.5 hrs after 80% cold working

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