1. Introduction
Permanent magnet synchronous motor (PMSM), due to its high torque density, high power factors, and small torque ripple [
1,
2,
3], has gradually replaced brushed DC motors and AC induction motors, widely used in military and industrial fields, especially in electric automobile and robots [
4,
5,
6]. The outer rotor structure is mostly used in low-speed and high-torque working environments because of its higher torque density, smaller torque ripple, and more stable structure [
7]. Outer rotor PMSM (OPMSM) mostly adopts fractional slot concentrated winding, compared with integral slot winding, the slot fill factor of fractional slot concentrated winding is greatly improved, the extension length of the winding end is greatly shortened, the amount of copper is reduced, and the cost is saved. It is conducive to miniaturization and lightweight of the motor, saving production hours, and realizing production automation [
8,
9,
10]. The rotor of OPMSM usually adopts the surface-mounted structure, which is the PM directly mounted on the surface of the rotor core. This structure leads to low installation accuracy and large installation errors of PM. The installation error of PM has an impact on some electromagnetic properties of the motor, such as torque, torque ripple, and cogging torque, limiting the performance of the OPMSM.
To reduce the influence of PM installation errors on motor performance, many methods are proposed. In [
11], an outer rotor interior PMSM (IPMSM) is proposed, which almost eliminates the PM installation error. This paper also slots on the rotor core to optimize the flux path reluctance, which plays a role in reducing the cogging torque. However, the PM embedding process of interior PM structure is complicated and the assembly cost is high. The authors in [
12,
13,
14] study the influence of manufacturing tolerances on motor performance during motor production. In [
12], the influence of manufacturing tolerance on the cogging torque of PMSM is analyzed by combining experiment and theory, it is concluded that the stator inner diameter tolerance has the greatest influence on the cogging torque, followed by the PM tolerance. It is proposed that special design and optimization of key tolerances must be carried out in large-scale production of motors, and a manufacturing method for producing stator and rotor stacks is proposed in this paper, which can reduce the cogging torque caused by error by about 50%. However, only the stator and rotor are analyzed and optimized, and the optimization method of PM is not mentioned. The influence of PM shape error on the electromagnetic characteristics of the motor is studied and the relationship between the width and thickness of the PM and the cogging torque characteristics of the motor is analyzed in [
15,
16], but the influence of the installation position error of the PM is not considered. The influence of PM installation position on cogging torque is studied in [
17,
18]. In [
17], the parameter expression of PM installation position and cogging torque is derived by energy method and flux path analysis. In [
18], the expected distribution of PM installation accuracy and cogging torque is calculated by statistical method, and a method of PM installation accuracy required to achieve the expected cogging torque is provided for reference, but the specific method of improving PM installation is not mentioned in [
18].
In summary, the installation error of PM has a great influence on the electromagnetic characteristics of the motor, but there is still a lack of research on the specific methods to improve the installation accuracy of PM. In this paper, the optimization method of adding auxiliary teeth to the rotor core is studied, which can facilitate the installation of PM and increase PM installation accuracy. The optimized motor is similar to the surface-mounted OPMSM in topology, but its electromagnetic characteristics are close to the surface-mounted OPMSM, it combines the advantages of the two structures. The optimized motor has mechanical stability, the characteristics of convenient PM installation of the surface-embedded structure, and the good electromagnetic characteristics of the surface-mounted structure. The influence of different auxiliary teeth heights on the electromagnetic performance of OPMSM is analyzed, the selection standard of the optimal auxiliary teeth height is determined, and the general applicability of the conclusion is verified. It can provide a design direction for such motor designers to improve the PM installation accuracy and take the electromagnetic performance into account.
In this paper, a 30-pole and 27-slot OPMSM is used as an example for modeling and analysis. The rest of this paper is organized as follows: the topological structure of the proposed motor is introduced in
Section 2. In
Section 3, the influence of PM installation error on the electromagnetic performance of OPMSM is analyzed, and the necessity of eliminating the PM installation error is demonstrated. In
Section 4, the parametric scanning method is used to analyze the optimization method of adding auxiliary teeth to the rotor core, and the selection standard of the best auxiliary teeth height is determined, the OPMSM with different sizes and pole–slot ratios is compared and analyzed to verify the universality of the conclusion. Finally,
Section 5 summarizes some conclusions.
2. Topology Structure and Parameters of the Proposed Motor
The OPMSM topology structure studied in this paper is shown in
Figure 1. The motor is mainly composed of rotor, stator, PMs, and winding.
When the inner rotor motor is running at a high speed, the PM is subjected to a huge centrifugal force. How to avoid the displacement and shedding of the PM during rotation is an important issue that must be paid attention to in the design of the inner rotor motor. The common method is to use a better binder or to add a non-magnetic sheath on the outside of the rotor to ensure the safety of the PM, which increases the production cost of the motor, but the outer rotor structure does not need to consider these problems, because the centrifugal force generated during the rotation of the motor rotor will make the PM more fit the rotor surface, and the outer rotor motor is generally not used for high-speed rotation environment. In addition, the motor with the outer rotor substructure has a larger air gap diameter, according to (1), the electromagnetic torque of the outer rotor motor is larger than that of the inner rotor motor of the same scale. The structural characteristics of OPMSM determine the large number of PM in the rotor part, which is one of the main reasons why the PM of OPMSM is difficult to install.
By adding auxiliary teeth on the surface of the rotor core, the installation accuracy of the PM can be greatly improved, and the adverse effects of the PM installation error on the motor can be reduced. The optimized structure is shown in
Figure 2.
Different from the general surface-embedded structure, the rotor teeth height of this motor is small, and its magnetic circuit characteristics are closer to the surface-mounted PMSM (SPMSM): the reluctance of the d-axis and q-axis is approximately the same, so the electromagnetic characteristics of the optimized motor are also closer to the SPMSM. Compared with the SPMSM, it has better mechanical stability, convenient installation of PMs, and high installation accuracy; compared with the surface-embedded PMSM (SEPMSM), it has lower cost, better magnetic circuit characteristics, lower requirements for rotor machining accuracy, and higher machining fault tolerance. The specific structural parameters of the OPMSM proposed in this paper are shown in
Table 1.
4. Analysis of Adding Auxiliary Teeth on the Surface of the Rotor Core
From the analysis results of the FEM in section III, it can be found that the PM offset has a negative impact on the electromagnetic characteristics of the OPMSM, especially the cogging torque, which changes greatly before and after the PM offset. Therefore, to ensure the high quality and performance unity of the motor production, it is necessary to eliminate the installation error of the PM in the large-scale production of the motor. By adding auxiliary teeth on the surface of the rotor core, the radial installation error of PM can be greatly reduced, as shown in
Figure 8.
In this section, the parametric scanning method is used to analyze the influence of rotor auxiliary teeth on the electromagnetic characteristics of OPMSM. The influence of different teeth heights on the electromagnetic performance of the motor is analyzed, and the selection standard of the best auxiliary teeth height is determined so that the electromagnetic performance of OPMSM is affected by the rotor auxiliary teeth as small as possible. Then the OPMSM with different sizes and pole–slot ratios are compared and analyzed to verify the universality of the conclusion.
4.1. Electromagnetic Characteristics
The air gap flux density is maintained at a constant value, and the auxiliary teeth height is linearly changed. The electromagnetic characteristics of OPMSM with different teeth heights are observed.
Figure 9 shows the electromagnetic torque characteristics of the OPMSM under different rotor teeth heights, including electromagnetic torque waveform, average torque curve, and torque ripple curve.
It can be seen from
Figure 9 that the average electromagnetic torque decreases with the increase in the rotor teeth height, and the torque ripple increases with the increase in the teeth height.
Figure 10 shows the air gap flux density waveform and its harmonic spectrum at different rotor teeth heights.
Figure 11 shows the back EMF amplitude and its waveform distortion rate at different rotor teeth heights. It can be seen from
Figure 10 that as the rotor teeth height increases, the sudden change trend of the air gap flux density waveform gradually increases near the q-axis (at 0°, 180°, and 360° electrical angles in
Figure 10). The Fourier expansion of the air gap flux density waveform is carried out to obtain the harmonic spectrum diagram of the air gap flux density in
Figure 10b, it can be obtained that the fundamental amplitude decreases with the increase in the rotor teeth height, and the 5th and 7th harmonic amplitude increases with the increase in the rotor teeth height.
Figure 11 shows that the back EMF amplitude increases with the increase in the rotor teeth height, but the harmonic distortion rate decreases with the increase in the rotor teeth height.
Summarizing the variation law of electromagnetic characteristics, it can be concluded that as the height of the rotor teeth changes linearly, the average torque, torque ripple, air gap flux density fundamental amplitude, back EMF amplitude, and back EMF harmonic distortion rate all change nonlinearly. The change trend is slow at the beginning, and the change speed increases significantly with the increase in rotor teeth height. In addition to the harmonic distortion rate, the electromagnetic characteristics are caused by the increase in the rotor teeth height, which leads to a decrease in the motor performance. However, when the rotor teeth height increases, the mechanical structure stability of OPMSM will be improved. Therefore, it is necessary to increase the height of the rotor teeth while ensuring that the electromagnetic performance does not change too much.
By analyzing
Figure 9b,c,
Figure 10b and
Figure 11, it can be found that when the rotor teeth height is less than 1 mm (half of the radial thickness of PM), the electromagnetic performance changes little. When the rotor teeth height continues to increase, the electromagnetic performance changes significantly. Comparing the electromagnetic performance changes when the auxiliary teeth height increases from 0 to 1 mm and from 1 mm to 2 mm, the average torque decreases by 0.66% and 3.78%, respectively. The torque ripple increases by 14.94% and 98.43%, respectively. The air gap flux density fundamental amplitude is reduced by 1.15% and 4.85%, respectively. The back EMF amplitude decreases by 0.17% and 0.90%, respectively. The back EMF waveform distortion rate is reduced by 5.50% and 19.06%, respectively. Therefore, it can be concluded that when the rotor teeth height is half of the radial thickness of the PM, the rotor teeth have little effect on the overall electromagnetic performance of OPMSM.
4.2. Loss and Efficiency
Figure 12 shows the eddy current loss of the magnetic steel under different rotor teeth heights during the steady-state operation of the motor.
Figure 13 shows the core loss of the stator core and rotor core of the motor.
Copper loss can be calculated by formula (7).
where
is the number of phases,
is the effective value of the phase current, and
is the copper wire resistance.
where
is the winding conductivity,
is the length of each phase winding wire, and
is the cross-sectional area of the wire.
Ignoring stray loss and mechanical loss, the efficiency of the motor is finally obtained.
Figure 14 shows the efficiency of the motor at different rotor teeth heights.
It can be seen from
Figure 14 that when the rotor teeth height increases from 0 to 1 mm, the efficiency is reduced by 0.14%. When the rotor teeth height increases from 1 mm to 2 mm, the efficiency is reduced by 0.68%. When the rotor teeth height increases from 1 mm to 2 mm, the efficiency of the motor decreases by nearly five times when the rotor teeth height increases from 0 to 1 mm. Therefore, it can be concluded that when the rotor teeth height is less than half of the radial thickness of the PM, the rotor teeth have little effect on the motor efficiency.
4.3. Universality Verification
To verify the universality of the above conclusions, the OPMSM with two different sizes and two different pole–slot ratios are compared and analyzed. The outer diameter of the original motor is 120 mm, the thickness of the PM is 2 mm, and the pole–slot ratio is 30p/27s.
Table 2 is the data of motors for comparison.
Figure 15 is the torque waveform of motors for comparison.
Figure 16 and
Figure 17 show the average torque and torque ripple curves, respectively.
Figure 18 shows the air gap flux density waveform.
Figure 19 shows the harmonic spectrum of the air gap flux density.
Figure 20 shows the amplitude of the back EMF and its harmonic distortion rate.
Figure 21 and
Figure 22 show the magnetic steel eddy current loss and the core loss, and
Figure 23 shows the efficiency change in the motor.
Table 3 summarizes the optimum auxiliary teeth height of four types of motors.
By analyzing the above figures, it can be concluded that when the size and pole–slot ratio of the OPMSM change, it does not affect the law that the electromagnetic characteristics change with the change in rotor teeth height. In addition to the change in the waveform distortion rate of the back EMF with the increase in the rotor teeth height, which will lead to the performance of the motor be better, the change in the average torque, torque ripple, air gap flux density, and the back EMF amplitude all lead to the decline of the motor performance, and the change speed of these electromagnetic characteristics is slow first and then fast. When the auxiliary teeth height is less than half of the radial thickness of the PM, adding auxiliary teeth has little effect on the overall performance of the motor.
It can be found that by adding rotor auxiliary teeth to the OPMSM and making its height about half of the radial thickness of the PM, the structural stability of the motor can be increased, the installation accuracy of PMs can be improved, and the influence of the installation error on the performance of OPMSM can be greatly reduced. At the same time, it has a small influence on the electromagnetic performance of the motor, making its electromagnetic performance close to the surface-mounted OPMSM and better than the surface-embedded OPMSM.
5. Conclusions
The structural characteristics of the surface-mounted OPMSM lead to some inevitable errors in the installation of the PM of the motor, and these errors will have an influence on the electromagnetic characteristics of the motor. The optimization method of adding auxiliary teeth on the surface of the rotor core is studied in this paper, and the selection criteria of the optimal auxiliary teeth height is finally determined. Some conclusions are summarized as follows:
(1) The PM installation error of OPMSM has little effect on the back EMF of the motor but has a great influence on the cogging torque and torque ripple: the 1-degree offset of S-poles will lead to an increase of 74.49% in the cogging torque amplitude and an increase of 35.98% in the torque ripple, which will lead to increases in the vibration and noise. Such errors can be almost eliminated completely by adding auxiliary teeth on the surface of the rotor core. For large-scale motor assembly production, these factors must be considered to improve the quality and life of the product.
(2) Through the parametric model simulation analysis, it can be found that the process of some electromagnetic parameters changing with the change in auxiliary teeth height is nonlinear, so the most suitable auxiliary teeth height can be found by parametric scanning method, which can reduce the PM installation error and enhance the structural stability of OPMSM while ensuring that the electromagnetic characteristics of the motor are not greatly affected. The analysis result shows that the optimal auxiliary teeth height of OPMSM is about half of the radial thickness of the PM, which can make the electromagnetic characteristics of OPMSM close to surface-mounted OPMSM and better than surface-embedded OPMSM. The wide applicability of this conclusion is verified by comparing and analyzing OPMSM with different sizes and different pole–slot ratios.