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Application of Polar Anisotropic
NdFeB Ring-Type Permanent
Magnet to Brushless DC Motor
2
3
Hyo Jun Kim 1, Dong Hwan Kim1, Chang Seop Koh , and Pan Seok Shin
IEEE TRANSACTIONS ON MAGNETICS, VOL. 43, NO. 6, JUNE 2007
授課老師:王明賢 教授
學
生:簡敏洲
學
號:M9929101
Outline
Abstract
 I. INTRODUCTION
 II. EXPERIMENTS

A. Alignment of the NdFeB Powder
B. Evaluation of the Four-Pole Polar Magnet and Motor

III. RESULTS
A. Magnetic Field Analysis and Powder Alignment Behavior
B. Effects of Premagnetization
IV. CONCLUSION
 REFERENCES

Abstract

A four-pole polar anisotropic sintered NdFeB permanent magnet (PM)
with high surface magnetic flux density is developed using a dry pressing
process with pulse magnetizing fields.

The effects of powder-filling density, magnetic field intensity, distribution
in the cavity, and premagnetization of the powder on the magnet
performance are investigated.

Through an application of the developed PM to a brushless DC motor, it
is shown that the premagnetization of the powder is very effective for
increasing the surface magnetic flux density.

Experimental results with a brushless DC motor adopting the developed
PM shows that the surface magnetic flux density is increased up to 0.63 T,
and the back emf at 1000 rpm measured 2.7 V, which is 41% higher than
the conventional segment type PM.
I. INTRODUCTION

In the design of brushless DC motors, permanent magnets
(PMs) with high-energy density, such as NdFeB, are essential to
have high power-to-volume ratio. Among the NdFeBPMs, plastic
PMs, made by injection molding process of the mixture of NdFeB
powder and binders, are widely being used mainly for low power
applications. However, for higher power applications, sintered
NdFeB PMs having higher energy density than the plastic one, are
more attractive [1].

Until now, among the sintered NdFeB PMs, the segment-type
anisotropic PMs and ring-type radial anisotropic PMs have been
developed and applied to the design of motors. In general, the ringtype radial anisotropic PMs have slightly lower energy density than
the segment-type anisotropic PMs because it is difficult to apply
strong magnetic fields enough to align the NdFeB powder during the
dry pressing process.

In the viewpoint of the motor design, the polar anisotropic
sintered NdFeB PM is expected to give stronger magnetic fields, and
therefore a PMmotor with higher power density is expected to be
designed. However, the polar anisotropic sintered R-Fe-B PM,
where R represents rare-earth metals, as well as NdFeB sintered PM,
is often noted but rarely studied because of their strong and complex
dependence on flux distribution and orientation ratio, etc. [2].

In this paper, the effects of powder filling density, magnetic
field intensity and distribution in the cavity, and the
premagnetization of powder are investigated for the development of
high-performance polar anisotropic sintered NdFeB PM. This paper
also compares the performances of three brushless DC motors which
employ a radial anisotropic ring type sintered NdFeB PM (35SH),
segment anisotropic sintered NdFeB PMs (39SH), and a polar
anisotropic sintered NdFeB PM (39SH), respectively.
II. EXPERIMENTS
A. Alignment of the NdFeB Powder

The magnetic properties of a sintered NdFeB PM, such as
residual magnetic flux density and intrinsic coercive force, are
generally affected a lot by the filling density and alignment of the
anisotropic NdFeB powder.

In this paper, the alloy of Nd14Dy1B6Co1Al0.5Nb0.5Febal in
atom percentage composition was prepared through the strip casting
process under an Ar atmosphere. After hydrogenation and
dehydrogenation treatments, the alloy was crushed and milled in a
jet mill to NdFeB powder; hereinafter, this powder will be referred
to NP, with an average particle size of 3.5 m.

In order to improve the powder alignment, the NP was premagnetized
with a pulse field of 1600 kA/m; hereinafter, this premagnetized powder
will be referred to PNP, and mixed in the blender.

The NP and PNP are filled with a filling density in the range of 2000–
3000 kg/m in a nonmagnetic mold. In the pressing process, to align the
powder in polar anisotropic direction, a capacitor-discharge pulse
magnetizer with four poles, of which the capacitor bank, capacitance, and
initial charging voltage are 6.25 kJ, 2000 F, and 2500 V, respectively.
B. Evaluation of the Four-Pole Polar Magnet and Motor

The magnetic properties of the sintered magnets were measured by using a
flux meter after magnetization. The commercial PM motors employing
radial and segment PMs were selected as benchmarks against a new motor
employing the developed polar anisotropic sintered PM. Comparisons are
made under the condition of the same outer dimensions of all motors.
Fig. 1. Pulse magnetizer: (a) cross section of mold; (b) four-pole polar
aligned NdFeB powder in cavity.
III. RESULTS



A. Magnetic Field Analysis and Powder Alignment Behavior
In order to apply strong magnetic field to align the powder, a pulse
current is applied instead of DC current. According to Rodewald, it has
been reported that using a pulse magnetic field of 6400 kA/m, sintered
Nd-Fe-B magnet with a maximum energy density of 451 kJ/m can be
obtained [3]. A pulse current is an effective choice for a magnetic field
source.
In order to find a proper magnetic field strength in the cavity for
making a high-performance polar anisotropic magnet, the alignment
behavior of the powder with varying magnetic field strength has been
investigated.

Fig. 2 shows the relationship between powder alignment degree and the applied
magnetic field intensity.
Fig. 2. Powder alignment ratios of NP on various filling densities.
Powder alignment ratios were normalized by alignment degree of
NP at = 2000 kg/m3, Ha = 1200 kA/m.

The virgin curves of NP were measured by putting the
magnetic powder that is NP into a capsule and changing the filling
density to 2000–3000 kg/m .

It means it is needed to reduce the filling density for the
reduction of friction between powders in order to improve the
alignment of powders.


B. Effects of Premagnetization
The PNP is obtained by mixing in the blender after magnetization with
NP. Fig. 4 shows the virgin curves of PNP.
Fig. 4. Comparisons of powder alignment ratios between NP and PNP on various filling densities. Powder
alignment ratios were normalized by alignment degree of NP at = 2000 kg/m ; Ha= 1200 kA/m.

Depending on the filling density, the alignment behavior of PNP
according to the applied magnetic field intensity shows distinctive
difference from that of NP.

It is shown that the alignment degree of PNP is higher than that of NP
as filling density increases.

since premagnetized powder has a bigger alignment torque than NP at
the high filling density, PNP tends to get affected by external magnetic
fields than NP.

On the other hand, when the magnetic field intensity is less than 240
kA/m, the alignment ratio of PNP is lower than that of NP due to the
attraction among the magnetized powder.

It seems that there exists critical value of the magnetic field intensity
that has to be overcome towards the magnetic field direction according to
the filling density.

C. Magnetic Performance of Four-Pole Polar Magnet and Its Application
Fig. 5. Comparison of surface flux density distribution between NP magnet and PNP magnet after magnetization.

It can be seen that the surface magnetic flux density from the PNP sintered
magnet is 10% higher than that of NP magnet thanks to premagnetized effect.

Fig. 8 compares the measured back emf waveforms of the motors under 1000
rpm. Comparing the back emf constants, Ke = 0.0027 V /rpm is measured with
the developed PNP magnet, which is around 41% higher than K e = 0.00192
V /rpm of the segment NP magnet.
Fig. 8. Comparison of 1-phase back emf. between by using polar anisotropic magnet
and using current commercial magnets.

Similarly, we experimented an increase of torque constant from K t = 0.0225
Nm/A to 0.0316 Nm/A (load condition 0.0294 Nm), that is again an increase of
40%.
IV. CONCLUSION

In the fabrication of a polar anisotropic sintered NdFeB ringtype
PM using pulse magnetizing fields, the required field intensity,
filling density, and premagnetization method have been investigated.
Low-level filling density of magnetic powder in the mold is very
favorable for the improvement of alignment.

In high-level filling density, the premagnetization is proven very
effective to improve the powder alignment.

The performances of the PM motor employing the fabricated
polar anisotropic sintered NdFeB magnet are also improved
compared with a motor employing conventional segment type
NdFeB magnets.
REFERENCES









[1] V. S. Ramsden, “Application of rare-earth magnets in high
performance
electric machines,” in Proc. 15th Int. Workshop REM and
Their Applications,
1998, p. 623.
[2] Y. Sun, R. W. Gao, G. B. Han, G. Bai, T. Liu, and B.Wang,
“Effects of
powder flowability on the alignment degree and magnetic
properties for
NdFeB sintermagnets,” J. Magn. Magn. Mater., vol. 299, p. 82,
2006.
[3] W. Rodewald, B. Wall, M. Katter, K. Ustuner, and S.
Steinmetz, “Extraordinary
strong Nd-Fe-B magnets by a controlled microstructure,”
in Proc. 17th Int. Workshop REM and Their Applications, 2002,
p. 25.