Difference between revisions of "Manufacturing of Single Contact Parts"

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Revision as of 10:31, 12 May 2014

The group of single contacts includes contact rivets, contact tips, and formed parts such as weld buttons. Contact spheres (or balls) are today rarely used because of economical considerations.

Contact Rivets

Solid Contact Rivets

Solid contact rivets are the oldest utilized contact parts. Their manufacturing requires a ductile contact material and is done without scrap on fully automated special cold heading machines. A wire slug is cut off and the rivet head is formed by pressing and hammering. This way contact rivets with various head configurations such as flat, domed, spherical, or pointed can be manufactured depending on the final application and switch or relay design.

Typical Contact Shapes of Solid Contact Rivets
  • Typical Contact Shapes of Solid Contact Rivets (Figure 1)
  • Contact Materials
    Au-, AgPd-, PdCu-Alloys, Ag, AgNi 0,15 (ARGODUR-Spezial), AgCu, AgCuNi (ARGODUR 27), Ag/Ni (SINIDUR), Ag/CdO (DODURIT CdO), Ag/SnO2 SISTADOX), Ag/ZnO (DODURIT ZnO),Ag/C 97/3*, Cu
    * dimensionally very limited
  • Dimensional Ranges (Figure 2)
    The respective parameters cannot be chosen independently of each other. They mainly depend on the ductility of the required contact material. Before a final decision on the dimensions we recommend to consult with the contact manufacturer.
Dimensional Ranges
  • Qualitätsmerkmale und Toleranzen (Figure 3)
Qualitaetsmerkmale und Toleranzen

Characteristics

Form A Form B Form C

Rounded headf Trapeziodal Trapeziodal head, radiused head,flat

Suggested test equipment

a) Head diameter d1 [mm]

d1< 4 + 0,06 During optical measurement

d1> 4 - 0,06 disregard corner

radius R3

Comparator,

Measuring microscope

b) Head thickness

k [mm]

d1< 4 + 0,03

d1> 4 + 0,08

Micrometer, Dial indicator

c) Shank diameter d2 [mm]

d2< 2 - 0,06

d2> 2 - 0,08

Micrometer

d) Shank length [mm]

+ 0,15

Micrometer, Dial

indicator, Comparator

e) Radius at center

of contact surface

R1 [mm]

Form A und B: Within the head thickness

tolerance

Form C: Allowable deviation from flatness: convex: within head thickness tolerance

concave: 0.005 d1

Comparator,

Comparator template, Radius gage

f) Radius at edge of contact surface R2 [mm]

Form A: Smooth transition to R1

Form B: 1.5 R2 allowed

Form C: <0,1d1

Profile template,

Comparator, Radius gage

g) Radii

R3 and R5 [mm]

Sligth rounding allowed

Comparator

h) Transition radius head underside to shank R4 [mm]

d2 < 2 R4 < 0,08 if covered by DIN 46240 pg.1 d2 > 2 R4 < 0,1

d2 > 3 R4 < 0,2

Comparator if in doubt: microsection

i) Allowed deviation

from cylindrical shape

max. 7° 30’: or d2 < l, l > 0,7 mm and k < 0,6 d1.

max. 15°: for all other rivets

Comparator

k) Concentricity between head and shank center line [mm]

d1 < 4 0,15

d1 > 4 0,2

in general: approx. 70% of allowable deviation

per DIN 46240

Comparator, Special

turn fixture

Composite Contact Rivets

Clad rivets for which only a part of the head (composite or bimetal rivets) or also the shank end (tri-metal rivets) are composed of contact material – with the balance of the body mostly being copper – have replaced for many applications solid rivet versions because of economical considerations. The cost savings depend on the contact material and its required volume for a specific application. These composite rivets are also produced scrap-less from wire material on special machinery with two process variations utilized.

During cold bonding and heading the bond between the contact material and the copper is achieved without external heat energy by high plastic deformation at the face surfaces of the two wire segments Figure 4 (Fig. 3.1). The bonding pressure must be high enough to move the lattice components of the two metals within a few atom radii so that the adhesion forces between atoms become effective. Therefore the head to shank diameter ratio of 2:1 must be closely met for a strong bond between the two metals.

Cold bonding of bimetall rivets (schematic)

During hot bonding the required heat energy is applied by a short term electrical current pulse Figure 5 (Fig. 3.2). In the case of Ag and Cu a molten eutectic alloy of silver and copper is formed in the constriction area between the two wire ends. When using metal oxide containing contact materials the non-soluble oxide particles tend to coagulate and the bonding strength between the component materials is greatly reduced. Therefore the cold bonding technology is preferred for these contact materials. The during cold bonding required high surface deformation ratio can be reduced for the hot bonding process which allows the head to shank diameter ratio to be reduced below 2:1.

For composite rivets with AgPd alloys as well as alloys on the basis of Au, Pd, and Pt the above methods cannot be used because of the very different work hardening of these materials compared to the base material copper. The starting material for such composite rivets is clad strip material from which the contact rivets are formed in multiple steps of press-forming and stamping. Similar processes are used for larger contact rivets with head diameters > 8 mm and Ag-based contact materials.

Hot bonding of bimetall rivets (schematic)
  • Typical contact shapes for composite rivets (Figure 6)
Typical contact shapes for composite rivets
  • Contact materials
    Ag, AgNi 0,15 (ARGODUR), AgCu, AgCuNi (ARGODUR 27), Ag/Ni (SINIDUR), Ag/CdO (DODURIT CDO), Ag/SnO2 (SISTADOX), Ag/ZnO (DODURIT ZNO)
  • Base materials
    Cu
  • Dimensional ranges (Figure 7)
    These parameters cannot be chosen independently of each other. They depend mainly on the mechanical properties of the contact material. Before specifying the final dimensions we recommend to consult with the contact manufacturer.
Dimensional ranges
  • Quality criteria and tolerances (Figure 8)
Quality criteria and tolerances

Criteria

Form B Form C

Trapezoidal head, Trapezoidal head radiused flat

Suggested test

equipment

a) Head diameter

d1 [mm]

During optical measurement disregard corner radius R3 + 0.1

Comparator, measu-

ring microscpope

b) Head thickness

k [mm]

+ 0.1

Micrometer,

Dial indicator

c) Shank diameter

d2 [mm]

Deviation from roundness and conical shape of

shank only within allowed diameter tolerance d2 < 1.5 - 0.08

d2 > 1.5 - 0.1

Micrometer

d) Shank length l

[mm]

+ 0.15

Micrometer, Dial indicator, Comparator

e) Radius at center

of contact surface

R1 [mm]

Form B: + 10%, but not below

+ 0.5 mm

Form C: Allowable deviation from flatness: convex: within head thickness tolerance concave: 0.005 d1

Comparator, Comparator template, Radius gage, Profile template

f) Radius at edge

of contact surface

R2 [mm]

per DIN 46240: Form B and C max. 0.5 without DIN:max. 1

Profile template,

Comparator, Radius gage

g) Radii

R3 and R5 [mm]

Sligth rounding allowed

Comparator

h) Transition radius

head underside to shank R4 [mm]

d2 < 2 R4 < 0.08 d2 > 2 R4 < 0.1 d2 > 3 R4 < 0.2

Comparator, if in doubt: micro-section

i) Allowed deviation from cylindrical shape

d1 < 4 up to 7°30’ + 2°30’

d1 > 4 up to 10° + 5°

Comparator, Measu- ring microscope, if in doubt: microsection

k) Concentricity bet-

ween head and shank center line [mm]

5% of d1

Comparator,

Measuring microscope, Special turn fixture

l) Contact layer

thickness [mm]

In center area of 0.5 d1 s> nominal thickness

Remaining head area must be covered

Measuring micros- cope, Microsection

  • Typical contact shapes of tri-metal rivets (Figure 9)
Typical contact shapes of tri-metal rivets
  • Contact materials
    Ag, AgNi 0,15 (ARGODUR), AgCu, AgCuNi (ARGODUR 27), Ag/Ni (SINIDUR), Ag/CdO (DODURIT CDO), Ag/SnO (SISTADOX), Ag/ZnO (DODURIT ZNO)
  • Base materials
    Cu
  • Dimensional ranges (Figure 10)
Dimensional ranges
  • Standard values for rivet dimension
d1

k

1

d2

α

r1

s1

s2

3.0

0.8

2.0

1.5

7.5°

4.0

0.4

1.0

4.0

1.0

2.5

2.0

7.5°

8.0

0.5

1.2

5.0

1.2

3.0

2.5

10°

12.0

0.6

1.4

Braze Alloy Clad Contact Rivets

For special cases, especially high surrounding temperatures with high thermal and mechanical stresses during switching operations, a full metallurgical bond between the contact rivet and the contact carrier may be required to prevent a loosening of the connection and early failures of the device. To accomplish this superior bond a thin layer of brazing alloy is added to the underside of the head and the rivet shank. During assembly a thermal treatment is added after the mechanical staking.

Contact Rivets with Brazed Contact Material Layers

For certain applications contact rivets with non-ductile or brittle materials such as tungsten, silver–tungsten, or silver–graphite are required. Rivets with these contact materials can only be fabricated by brazing. Small round tips are brazed to pre-fabricated copper or steel bases using special brazing alloys in a reducing atmosphere.

Contact Tips

Flat or formed contact tips, welded or brazed to contact carriers, are frequently used in switching devices for higher power technology. Depending on the contact material and specified shapes these tips are produced by various manufacturing processes. The most frequently used ones are:

  • Stamping from strips and profiles
  • Cutting from extruded rods
  • Pressing, Sintering, and Infiltrating
  • Pressing, Sintering, and Re-Pressing
  • Pressing and Sintering

For stamping sufficiently ductile semi-finished materials are needed. These are mainly silver, silver–alloys, silver–nickel, silver–metal oxide, and silver–graphite (with graphite particle orientation parallel to the switching surface). Silver–metal oxides and silver–graphite need an additional well brazable or weldable silver layer on the underside which can be bonded to the bulk of the contact material by various processes. To further facilitate the final attachment process strips and profiles are often coated on the brazing underside with an additional thin layer of brazing alloy such as L-Ag 15P (CP 102 or BCuP-5). For Ag/C with the graphite orientation perpendicular to the switching surface the brazable underside is produced by cutting tips from extruded rods and burning out graphite in a defined thickness.

The press-sinter-infiltrate process (PSI) is used mainly for Ag/W and Cu/W material tips with tungsten contents of > 50 wt%. A silver or copper surplus on the underside of the tip later facilitates the brazing or welding during final assembly.

The press–sinter–re-press method (PSR) allows the economic manufacturing of shaped contact parts with silver or copper contents > 70 wt%. This process also alloys parts pressed in two layers, with the upper being the contact material and the bottom side consisting of pure Ag or Cu to support easy attachment.

Press–sinter processes are limited to smaller Ag/W contact tips with a Ag content of approximately 65 wt%.

  • Contact materials
    Ag, AgNi 0,15 (ARGODUR Spezial), AgCu, AgCuNi (ARGODUR 27), Ag/Ni (SINIDUR), Ag/CdO (DODURIT CdO), Ag/SnO2 (SISTADOX), Ag/ZnO (DODURIT ZnO), Ag/C (GRAPHOR), Ag/W (SIWODUR), Ag/WC (SIWODUR C), Ag/WC/C (SIWODUR C/C), Ag/Mo (SILMODUR), Cu/W (CUWODUR)
  • Typical contact shapes of tips and formed contact parts (Figure 11)
Typical contact shapes of tips and formed contact parts
  • Dimensional ranges
    Attachment Method: Welding
    Bonding Area: approx. 5 – 25 mm2
    Attachment Method: Brazing
    Bonding Area: > 25 mm2

Because of the wide variety of shapes of contact tips and formed contact parts the user and manufacturer usually develop special parts specific agreements on quality and tolerances.

Weld Buttons

For contacts used at higher temperatures, such as for example in controls for stove tops, the use of contact rivets or the direct welding of silver based contact materials on steel or thermo-bimetal carriers is usually not feasible. For such applications weld buttons are suitable contact components.

Weld buttons are round or rectangular tips manufactured from clad contact bimetal or in some cases tri-metal semi-finished materials. The surface layer is produced from the specified contact material, the bottom weldable layer from a material with higher electrical resistivity such as steel, nickel, or for example a copper-nickel alloy. For precious metal savings a third high conductive layer of copper may be inserted between the contact material and weld backing. To improve the welding process the underside often has an embossed pattern with one or more weld projections.

The manufacturing of weld buttons from bi– or tri–metal strip requires a ductile contact material. Weld buttons with tungsten contact layers are therefore produced by brazing of tungsten discs to a weldable pre-formed base.

  • Typical contact forms of weld buttons (Figure 12)
Typical contact forms of weld buttons
  • Contact materials
    Ag, AgNi 0,15 (ARGODUR-Spezial), AgCu, AgCuNi (ARGODUR 27), Ag/Ni (SINIDUR), Ag/CdO (DODURIT CdO), Ag/SnO2 (SISTADOX), Ag/ZnO (DODURIT ZnO)
  • Carrier materials
    Ni, Fe, CuNi, CuNiZn et.al.
  • Dimensional Ranges (Figure 13)
Dimensional Ranges
  • Quality criteria of standard weld buttons (Figure 14)
Quality criteria of standard weld buttons


References

Manufacturing Technologies for Contact Parts