Abstract
Currently, permanent-magnet-type traction motors drive most electric vehicles. However, the potential demagnetization of magnets in these motors limits the performance of an electric vehicle. It is well known that during severe duty, the magnets are demagnetized if they operate beyond a ‘knee point’ in the B(H) curve. We show herein that the classic knee point definition can degrade a magnet by up to 4 grades. To prevent consequent excessive loss in performance, this paper defines the knee point k as the point of intersection of the B(H) curve and a parallel line that limits the reduction in its residual flux density to 1%. We show that operating above such a knee point will not be demagnetizing the magnets. It will also prevent a magnet from degenerating to a lower grade. The flux density at such a knee point, termed demag flux density, characterizes the onset of demagnetization. It rightly reflects the value of a magnet, so can be used as a basis to price the magnets. Including such knee points in the purchase specifications also helps avoid the penalty of getting the performance of a low-grade magnet out of a high-grade magnet. It also facilitates an accurate demagnetization analysis of traction motors in the worst-case conditions.
Highlights
At present, 80 to 90% of electric vehicles sold globally use permanent magnet (PM) type traction motors [1]
We define the knee point k as one where the B(H) curve intersects with a parallel line that is offset by 1% Br
We showed that operating above such knee point k protects it from degenerating to a lower grade forever
Summary
80 to 90% of electric vehicles sold globally use permanent magnet (PM) type traction motors [1]. Since the flux density falls sharply as a waterfall beyond the knee, a minute increase in the demagnetizing field can drastically reduce the performance of a traction motor [9,10] This can reduce the service life of the electric vehicle. It shows that the classic knee point K lies close to the irreversible segment, while the knee endpoint k lies close to its reversible segment. Its knee endpoint field Hk of −495.5 kA/m is 5.4% lower This again demonstrates that using the classic Machines 2021, 9, x FOR PEER REVIEkWnee point K to price magnets, a buyer is paying a significant, but spurious 5.4% hi5gohfe1r5 cost for the magnet.
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