You are using an outdated browser. Please upgrade your browser to improve your experience.
When diffusion bond treatment is still not sufficient to reach desired mechanical characteristics or correct behaviour to thermal treatments, then prealloy of Iron-Molibdenum grades are the best solution. Pre-alloyed only powders do not undergo ulterior diffusion bonding treatment.
Description of the material and main chemical components | Alloy of iron Cu atomised powder |
---|---|
Description of the manufacturing process | Water atomisation of molten alloy, annealing, mechanical treatment and final sieving |
Typical applications | Sintering of ferrous parts |
Particle shape | Irregular |
Main characteristic | Presence of Cu directly at alloy stage grants best homogenity of this element |
Particle upper cut size (full range) | 180 |
Particle upper cut size (typical) | 180 |
Apparent density (typical) | 3 |
Application notes | Normally used as additive |
Recommended packaging | BB 1000 |
Type | Upper cut size(µm) | Ot % | Apparent density(g/cm3) | Added elements |
---|---|---|---|---|
Cu8 | 180 | 0.2 | 2,90 to 3,10 | Cu at 8% |
Description of the material and main chemical components | Alloy of iron Cu atomised powder |
---|---|
Description of the manufacturing process | Water atomisation of molten alloy, annealing, mechanical treatment and final sieving |
Typical applications | Sintering of ferrous parts |
Particle shape | Irregular |
Main characteristic | Presence of Cu directly at alloy stage grants best homogenity of this element |
Particle upper cut size (full range) | 250 |
Particle upper cut size (typical) | 250 |
Apparent density (typical) | 3.05 |
Application notes | Normally used as additive for its copper content. Use of MCu20 have high advantage in DC control |
Recommended packaging | BB 1000 |
Type | Upper cut size(µm) | Ot % | Added elements |
---|---|---|---|
Cu20 | 250 | 0.25 | Cu at 20% |
Description of the material and main chemical components | Alloy of iron -Mo atomised powder |
---|---|
Description of the manufacturing process | Water atomisation of molten alloy, annealing, mechanical treatment and final sieving |
Typical applications | Sintering of Ferrous components with good mechanical performances |
Particle shape | Irregular |
Main characteristic | Presence of Mo directly from molten alloy permit a basic powder processing, still granting good performances. ST0 is rarely subject to thermal treatments |
Particle upper cut size (full range) | 180 |
Particle upper cut size (typical) | 180 |
Apparent density (typical) | 3.05 |
Application notes | ST0 is normally used with simple addition of Graphite and lubricants |
Recommended packaging | BB 1000 |
Type | Upper cut size(µm) | Ot % | Apparent density(g/cm3) | Added elements |
---|---|---|---|---|
ST0 | 180 | 0.15 | 3,0 to 3,15 | Mo at 1,5% |
Description of the material and main chemical components | Alloy of iron -Mo atomised powder |
---|---|
Description of the manufacturing process | Water atomisation of molten alloy, annealing, mechanical treatment and final sieving |
Typical applications | Sintering of Ferrous components with good mechanical performances |
Particle shape | Irregular |
Main characteristic | Presence of Mo directly from molten alloy permit a basic powder processing, still granting good performances |
Particle upper cut size (full range) | 212 |
Particle upper cut size (typical) | 212 |
Apparent density (typical) | 3 |
Application notes | ST0.85 is normally used with simple addition of Graphite and lubricants |
Recommended packaging | BB 1000 |
Type | Upper cut size(µm) | Ot % | Apparent density(g/cm3) | Added elements |
---|---|---|---|---|
ST0,85 | 212 | 0.15 | 2,95 to 3,05 | Mo at 0,85% |