Abstract
When modelling permanent magnet motors, it is important to understand the resistivity of the magnetic material, and its eddy current flow. These motors often operate over a wide range of temperatures and thus an understanding of the dependency of resistivity with temperature is necessary for accurate modelling.
Previous works have shown that for SmCo type magnets the resistivity can be anisotropic for 1:5 and 2:17-type magnets, and that operating temperature can significantly change resistivity.
The authors investigated the temperature dependence of different commercial grade SmCo 2:17-type and -1:5 type magnets, up to 200 °C, in both a magnetised and non-magnetised condition. Anisotropic resistivity was observed in both types, with the 2:17-types having lower resistivity in the plane perpendicular to the c-axis, and the 1:5-type having lower resistivity in the parallel plane. At room temperature, resistivity was found to be similar in both the magnetised and non-magnetised states and a linear increase in resistivity was observed with increasing temperature for both. However, the temperature coefficient was found to be lower in the magnetised state, leading to a lower resistivity at higher temperatures than for the non-magnetised state.
For 2:17-type magnets of similar composition, differences in the Zr content and the Zr-rich lamellae within the cellular structures were found to produce variations in the resistivity, only in the axis perpendicular to the c-axis. An additional 0.31 wt% of Zr is shown to lower resistivity by 0.7%.
Previous works have shown that for SmCo type magnets the resistivity can be anisotropic for 1:5 and 2:17-type magnets, and that operating temperature can significantly change resistivity.
The authors investigated the temperature dependence of different commercial grade SmCo 2:17-type and -1:5 type magnets, up to 200 °C, in both a magnetised and non-magnetised condition. Anisotropic resistivity was observed in both types, with the 2:17-types having lower resistivity in the plane perpendicular to the c-axis, and the 1:5-type having lower resistivity in the parallel plane. At room temperature, resistivity was found to be similar in both the magnetised and non-magnetised states and a linear increase in resistivity was observed with increasing temperature for both. However, the temperature coefficient was found to be lower in the magnetised state, leading to a lower resistivity at higher temperatures than for the non-magnetised state.
For 2:17-type magnets of similar composition, differences in the Zr content and the Zr-rich lamellae within the cellular structures were found to produce variations in the resistivity, only in the axis perpendicular to the c-axis. An additional 0.31 wt% of Zr is shown to lower resistivity by 0.7%.
| Original language | English |
|---|---|
| Publication status | Unpublished - 2023 |
| Event | 27th International Workshop on Rare Earth and Future Permanent Magnets and their Applications - University of Birmingham, Birmingham, United Kingdom Duration: 3 Sept 2023 → 7 Sept 2023 https://uobevents.eventsair.com/repm2023/ |
Conference
| Conference | 27th International Workshop on Rare Earth and Future Permanent Magnets and their Applications |
|---|---|
| Abbreviated title | REPM 2023 |
| Country/Territory | United Kingdom |
| City | Birmingham |
| Period | 3/09/23 → 7/09/23 |
| Internet address |
Keywords
- rare earth alloys
- Magnets
- resistivity
- Samarium cobalt
- temperature effects