Samarium Cobalt (SmCo) magnetsare optimal for high temperature motor applications due to their high magnetic strength, exceptional temperature resistance, and reliable performance without oxidation protection.
Samarium cobalt magnets tend to be an ideal first choice in mission critical applications involving elevated temperatures where magnetic strength and stability are critical. They are routinely used in high-performance motors, machinery, pumps, medical devices, magnetic couplings, sensors, generators, high temperature service applications, wide temperature range applications and for use in corrosive (e.g. water, oil) environments, instruments and meters, etc.
Corrosion Resistance
SmCo magnets can usually be used in humid applications without any need for a protective coating. In wet envrironments, coating of SmCo(2:17) in NiCuNi is recommended to avoid surface corrosion issue.
The corrosion resistant of SmCo magnets are considered good, surface coating is unnecessary, but the coatings like NiCuNi, Zn, Black epoxy can be plated if required. The oxidation resistance behavior of SmCo (2:17)-type high-temperature magnets modified with Ni–Cr two-layer coating is under studied.
Excellent Temperature Stability
Samarium cobalt magnets experience a minimal change in their magnetic performance as temperature increases from ambient, far less than neodymium and ferrite (ceramic) magnets. Being part of the rare-earth magnet family, Samarium cobalt magnets rank similarly in strength to neodymium magnets but have much higher temperature stability and higher coercivity.
| Physical properties of sintered Sm-Co magnets | |
| Property (unit) | Sm-Co |
| Remanence (T) | 0.8–1.16 |
| Coercivity (MA/m) | 0.493–2.79 |
| Relative permeability (–) | 1.05–1.1 |
| Temperature coefficient of remanence (%/K) | −0.03..–0.05 |
| Temperature coefficient of coercivity (%/K) | −0.15..–0.30 |
| Curie temperature (°C) | 700–850 |
| Density (g/cm3) | 8.2–8.5 |
| CTE, magnetizing direction (1/K) | (5–9)×10−6 |
| CTE, normal to magnetizing direction (1/K) | (10–13)×10−6 |
| Flexural strength (N/mm2) | 150–180 |
| Compressive strength (N/mm2) | 800–1000 |
| Tensile strength (N/mm2) | 35–40 |
| Vickers hardness (HV) | 400–650 |
| Electrical resistivity (Ω·cm) | (50–90)×10−6 |