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Silver Based Materials

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|80

|-

|~~AgNi 0,~~AgNi0.15~~ ARGODUR-Spezial~~

|99.85

|10.5

|85

|-

|AgCu24,.5Ni0,.5

|75

|10.0

|92

|-

|Ag99,.5NiMg ARGODUR 32 Not heat treated

|99.5

|10.5

<caption>'''Mechanical Properties of Silver and Silver Alloys'''</caption>

<tr><th>Material</th><th>HardnessCondition</th><th>Tensile StrengthRm [MPa]</th><th>Elongation A [%] min.</th><th>Vickers HardnessHV 10</th></tr><tr><td>Ag</td><td>R 200R 250R 300R 360</td><td>200 - 250250 - 300300 - 360> 360</td><td>30832</td><td>30608090</td></tr><tr><td>~~AgNi 0,~~AgNi0.15~~ARGODUR Special~~</td><td>R 220R 270R 320R 360</td><td>220 - 270270 - 320320 - 360> 360</td><td>25621</td><td>407085100</td></tr><tr><td>AgCu3</td><td>R 250R 330R 400R 470</td><td>250 - 330330 - 400400 - 470> 470</td><td>25421</td><td>4590115120</td></tr><tr><td>AgCu5</td><td>R 270R 350R 460R 550</td><td>270 - 350350 - 460460 - 550> 550</td><td>20421</td><td>5590115135</td></tr><tr><td>AgCu10</td><td>R 280R 370R 470R 570</td><td>280 - 370370 - 470470 - 570> 570</td><td>15321</td><td>6095130150</td></tr><tr><td>AgCu28</td><td>R 300R 380R 500R 650</td><td>300 - 380380 - 500500 - 650> 650</td><td>10321</td><td>90120140160</td></tr><tr><td>Ag98CuNiARGODUR 27</td><td>R 250R 310R 400R 450</td><td>250 - 310310 - 400400 - 450> 450</td><td>20521</td><td>5085110120</td></tr><tr><td>AgCu24,5Ni0,5</td><td>R 300R 600</td><td>300 - 380> 600</td><td>101</td><td>105180</td></tr><tr><td>Ag99,5NiMgARGODUR 32Not heat treated</td><td>R 220R 260R 310R 360</td><td>220260310360</td><td>25521</td><td>407085100</td></tr><tr><td>ARGODUR 32 Heat treated</td><td>R 400</td><td>400</td><td>2</td><td>130-170</td></tr></table>

</figtable>

====Fine-Grain Silver====

Fine-Grain silver ~~(ARGODUR-Spezial)~~ is defined as a silver alloy with an addition of 0.15 wt% of nickel. Silver and nickel are not soluble in each other in solid form. In liquid silver, only a small amount of nickel is soluble as the phase diagram illustrates (<xr id="fig:Phase diagram of silver nickel"/>) ~~illustrates~~. During solidification of the melt, this nickel addition gets finely dispersed in the silver matrix and eliminates the pronounce coarse grain growth after prolonged influence of elevated temperatures (<xr id="fig:Coarse grain micro structure of Ag"/> and <xr id="fig:Fine grain microstructure of AgNiO"/>).

</figure>

[[File:Strain hardening of AgNiO15 by cold working.jpg|left|thumb|<caption>Strain hardening of AgNiO15 by cold working</caption>]]

</figure>

[[File:Softening of AgNiO15 after annealing.jpg|left|thumb|<caption>Softening of AgNiO15 after annealing</caption>]]

</figure>

!colspan="2" | Properties

|-

|Ag AgNi0,.15~~ ARGODUR-Special~~

|Highest electrical and thermal conductivity, high affinity to sulfur (sulfide formation), low welding resistance, low contact resistance, very good formability

|Oxidation resistant at higher make currents, limited arc erosion resistance, tendency to material transfer in DC circuits, easy to braze and weld to carrier materials

!Form of Supply

|-

|Ag AgNi0,.15~~ ARGODUR-Spezial~~ AgCu3 AgNi98NiCu2 ARGODUR 27 AgCu24,5Ni0,5

|Relays, Micro switches, Auxiliary current switches, Control circuit devices, Appliance switches, Wiring devices (≤ 20A), Main switches

|'''Semi-finished Materials:''' Strips, wires, contact profiles, clad contact strips, toplay profiles, seam- welded strips '''Contact Parts:''' Contact tips, solid and composite rivets, weld buttons; clad, welded and riveted contact parts

|'''Semi-finished Materials:''' Strips, wires, contact profiles, clad contact strips, seam-welded strips '''Contact parts:''' Contact tips, solid contact rivets, weld buttons; clad, welded and riveted contact parts

|-

|Ag99, .5NiOMgO ARGODUR 32

|Miniature relays, aerospace relays and contactors, erosion wire for injection nozzles

|Contact springs, contact carrier parts

AgPd alloys are hard, arc erosion resistant, and have a lower tendency towards material transfer under DC loads (<xr id="tab:Contact and Switching Properties of Silver-Palladium Alloys"/>). On the other hand, the electrical conductivity is decreased at higher Pd contents. The ternary alloy AgPd30Cu5 has an even higher hardness, which makes it suitable for use in sliding contact systems.

AgPd alloys are mostly used in relays for the switching of medium to higher loads (> 60V, > 2A) as shown in (<xr id="tab:Application Examples and Forms of Suppl for Silver-Palladium Alloys"/>). Because of the high palladium price, these formerly solid contacts have been widely replaced by multi-layer designs such as AgNi0.15 or AgNi10 with a thin Au surface layer. A broader field of application for AgPd alloys remains in the wear resistant sliding contact systems.

!Silver Content [wt%]

!Additives

!Theoretical Density [g/cm3]!~~Electrical Resistivity [μΩ·cm]!colspan="2" style="text-align:center"|~~Electrical Conductivity ~~[% IACS]~~ [MS/m]!Vickers Hardness ~~Hv1~~[HV0,1]

!Tensile Strength [MPa]

!Elongation~~ ~~(soft annealed) A[%]min.

!Manufacturing Process

!Form ofSupply|-|Ag/SnO2 ~~Supply~~98/2 SPW|97 - 99|WO3|10,4|59 ± 2|57 ± 15|215|35|Powder Metallurgy|1

|-

|Ag/SnO2 92/~~8PW10 ~~8 SPW

|91 - 93

|WO3

|10,1

|51 ± 2

|62 ± 15

|255

|25

|Powder Metallurgy

|1

|-

|Ag/SnO2 90/10 SPW

|89 - 91

|WO3

|10

|47 ± 5

|

|250

|25

|Powder Metallurgy

|1

|-

|Ag/SnO2 88/12 SPW

|87 - 89

|WO3

|9.9

|246 ± 5|8667 ± 15|50270|~~50 - 95|200 - 320|30~~20|Powder Metallurgy~~ ~~

|1

|-

|Ag/SnO2 9092/8 SPW4|91 - 93|WO3|10,1|51 ± 2|62 ± 15|255|25|Powder Metallurgy|1,2|-|Ag/~~10PW10~~SnO2 90/10 SPW4

|89 - 91

|WO3

|10

|

|Powder Metallurgy

|1,2

|-

|Ag/SnO2 88/12 SPW4

|87 - 89

|WO3

|9,8

|46 ± 5

|80 ± 10

|

|Powder Metallurgy

|1,2

|-

|Ag/SnO2 88/12 SPW6

|87 - 89

|MoO3

|9.8

|42 ± 5|70 ± 10|||Powder Metallurgy|2~~.08~~|83-|48Ag/SnO2 97/3 SPW7|55 96 - ~~100~~98|Bi2O3 and WO3|||||~~220~~ |Powder Metallurgy|2|-|Ag/SnO2 90/10 SPW7|89 - ~~330~~91|Bi2O3 and WO3|9,9||||28

|Powder Metallurgy

|12

|-

|Ag/SnO2 88/~~12PW10 ~~12 SPW7

|87 - 89

|Bi2O3 and WO3|9.78|42 ± 5|70 ± 10|||Powder Metallurgy|2|-|Ag/SnO2 98/2 PMT1|97 - 99|Bi2O3 and CuO|10,4|57 ± 2~~.17~~|79|46215|35|Powder Metallurgy|1,2|-|Ag/SnO2 96/4 PMT1|95 - 97|Bi2O3 and CuO||||||Powder Metallurgy|1,2|-|Ag/SnO2 94/6 PMT1|93 - 95|Bi2O3 and CuO||||||Powder Metallurgy|1,2|-|Ag/SnO2 92/8 PMT1|91 - 93|Bi2O3 and CuO|10|50 ± 2|62 ± 15|240|25|Powder Metallurgy|1,2|60 - ~~106~~|~~230~~ Ag/SnO2 90/10 PMT1|89 - ~~330~~91|Bi2O3 and CuO|10|48 ± 2|65 ± 15|240

|25

|Powder Metallurgy

|1,2|-|Ag/SnO2 88/12 PMT1|87 - 89|Bi2O3 and CuO|9,9|46 ± 5||260|20|Powder Metallurgy|1,2

|-

|Ag/SnO2 90/~~10PE ~~10 PE

|89 - 91

|Bi2O3 and CuO

|9.,8|48 ± 2~~.04|84|49~~

|55 - 100

|230 - 330

|1

|-

|Ag/SnO2 88/~~12PE ~~12 PE

|87 - 89

|Bi2O3 and CuO

|9.,7~~|2.17|79~~|46± 5

|60 - 106

|235 - 330

|1

|-

|Ag/SnO2 88/12 ~~TOS F ~~PMT2

|87 - 89

|~~In2O3~~CuO|9.8~~|2.22|78~~,9|45|~~100 - 120~~90 ± 10|~~330 -430~~|25|~~Inernal Oxidation~~Powder Metallurgy

|1,2

|-

|Ag/SnO2 9086/~~10WPD ~~14 PMT3|89 85 - 9187|AgBi2~~MoO~~O43and CuO|9.9~~|2.13~~,8|81|47~~|70 - 120~~95 ± 10

|

|2

|-

|Ag/SnO2 8894/~~12WPD ~~6 LC1|87 93 - 8995|AgBi2O3 and In2~~MoO~~O43|9.,8|~~2.27|76|44~~45 ± 5|~~75 - 120~~55 ± 10

|

|Powder Metallurgy

|2

|-

|Ag/SnO2 90/10 POX1

|89 - 91

|In2O3

|9,9

|50 ± 5

|85 ± 15

|310

|25

|Internal Oxidation

|1,2

|-

|Ag/SnO2 90/10 POX1

|87 - 89

|In2O3

|9,8

|48 ± 5

|90 ± 15

|325

|25

|Internal Oxidation

|1,2

|-

|Ag/SnO2 90/10 POX1

|85 - 87

|In2O3

|9,6

|45 ± 5

|95 ± 15

|330

|20

|Internal Oxidation

|1,2

|-

|}

</figtable>

</figure>

<figure id="fig:Micro structure of Ag ZnO 92 8 ~~Pw25~~PW25"> [[File:Micro structure of Ag ZnO 92 8 Pw25.jpg|left|thumb|<caption>Micro structure of Ag/ZnO 92/8 ~~Pw25~~PW25: a) perpendicular to extrusion direction b) parallel to extrusion direction</caption>]]

</figure>

<caption>'''Application Examples of Silver–Metal Oxide Materials'''</caption>

<tr><th>Material</th><th>Application Examples</th></tr><tr><td>Ag/SnO22</td><td>Micro switches, Network relays, Automotive relays, Appliance switches,Main switches, contactors, Fault current protection relays (paired againstAg/C), (Main) Power switches</td></tr><tr><td>Ag/ZnO</td><td>Wiring devices, AC relays, Appliance switches, Motor-protective circuitbreakers (paired with Ag/Ni or Ag/C), Fault current circuit breakers paired againct Ag/C, (Main) Power switches</td></tr></table>

</figtable>

|40 - 60

|-

|AgC DF GRAPHOR DF*)[[#text-reference1|1]]

|95.7 - 96.7

|8.7 - 8.9

|69 - 76

|40 - 44

|-

|}

<div id="text-reference1">1 Graphite content 3.8 wt%, Graphite particles and fibers parallel to switching surface</div>

</figtable>

~~<nowiki>*)</nowiki> Graphite content 3.8 wt%, Graphite particles and fibers parallel to switching surface~~

<caption>'''Application Examples and Forms of Supply of Silver– Graphite Contact Materials'''</caption>

<tr><th>Material</th><th>Application Examples</th><th>Form of Supply</th></tr><td>Ag/C 98/2</td><td>Motor circuit breakers, paired with Ag/Ni</td><td>Contact tips, brazed and welded contact parts, some contact rivets Contact profiles (weld tapes), Contact tips, brazed and welded contact parts</td></tr><tr><td>Ag/C 97/3Ag/C 96/4Ag/C 95/5Ag/C DF</td><td>Circuit breakers, paired with Cu, Motor-protective circuit breakers, paired with Ag/Ni,Fault current circuit breakers, paired with Ag/Ni, Ag/W, Ag/WC, Ag/SnO22, Ag/ZnO,(Main) Power switches, paired with Ag/Ni, Ag/W</td><td>Contact tips, brazed and welded contactparts, some contact rivets withAg/C97/3</td/></tr></table>

</figtable>

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