Ceramics
Engineering ceramics are inherently difficult to wet with conventional brazing filler metals. Another problem is the difference in coefficient of thermal expansion (CTE) between the ceramic and the brazing filler metal. Due to the poor thermal conductivity and tensile strength of ceramics, care has to be taken to prevent cracking in the joint ( Joint design for ceramics).
There are a number of established processes that promote wetting of the ceramic by the braze alloy, these are:
- molybdenum-manganese process
- active filler metal brazes
- vapour sputter coating
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Comparison of active metal brazing with Mo-Mn process |
Molybdenum-manganese process
The most widely used approach in industry for brazing alumina involves the molybdenum-manganese (Mo-Mn) process. This process metallises the alumina surfaces by coating it with a mixture of metal and oxide powders, followed by a sintering treatment at high temperature, and then a plating operation. The alumina surfaces can then be brazed with a number of standard braze filler metals.
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ASTM leak test samples |
Active metal braze
Engineering ceramics can be directly brazed to other ceramics and to metals without prior surface coating, using active filler metals. To promote wetting on the ceramic, elements such as titanium, hafnium and zirconium are added to standard braze alloys. The most well established active metal braze is based on the Ag-28%Cu eutectic, with titanium as the active element, such as Ag-27.5%Cu-2%Ti and Ag-35%Cu-2%Ti. Other active metal braze alloys include elements such as Au, Ni, V and In. These braze alloys have different properties, such as brazing temperature, flow characteristics, CTE and corrosion resistance.
Active filler metals can be used to braze all of the engineering ceramics, including: alumina, silicon carbide, silicon nitride, boron nitride, aluminium nitride, zirconia, diamond, tungsten carbide, and sialons.
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Silicon Nitride turbocharger rotors
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Vapour sputter coating
Another approach to metallising the ceramic surface is the use of a vapour deposited metal coating. The process involves depositing a thin (several microns) coating of a reactive metal, such as titanium, onto the ceramic prior to brazing. This promotes the wetting of non-active braze alloys onto the ceramic.
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