1. Introduction
Brushless motors such as brushless DC motors (BLDCMs) and switched reluctance motors (SRMs) have been gaining significant attention in many applications [1-2], and a BLDCM is more effective in high power density and high efficiency. However, placing permanent magnets in the rotor of the BLDCM makes this motor suffer from the possibility of irreversible demagnetization by high temperature or armature reaction flux. Also, the mechanical integrity of permanent magnets inside the rotor gives this motor a limit in high-speed applications. On the other hand, the absence of permanent magnets in SRMs leads to cost effectiveness as a merit but offers lower efficiency and lower power density as a demerit at the same time compared to BLDCMs [3]. Recent cost rise in rare earth permanent magnet materials intensifies a need for the combination of an SRM with a BLDCM by slightly adding permanent magnets into the stator of the SRM such as doubly-salient permanent magnet machine [4], flux-reversal permanent magnet machine [5] and flux-switching permanent magnet machine [6].
In this paper, a permanent-magnet-assisted switched reluctance motor having small excitation poles, where phase coils are concentrically wound on the poles and thin permanent magnets are inserted inside the poles, is proposed. A step-by-step design procedure has been analytically conducted and also the benefit of the proposed permanent-magnet-assisted structure has been verified by a comparison with no-permanent-magnet SRM in terms of static torque comparison along with dynamic performance. Additionally, the first prototype of the proposed permanent-magnet-assisted SRM has been built up, and its stator and rotor laminations including its physical assembly are given in this paper.
2. Concept of Permanent-Magnet-Assisted SRM
Table 1 gives physical information and key specification for the proposed permanent-magnet-assisted SRM in the paper, and the outer diameter and stack length of the machine are 121.52mm and 70.0mm, respectively, along with 1.5kilowatt at 3,000 revolutions per minute (rpm) as its rated condition.
Table 1.Information of permanent-magnet-assisted SRM
Fig. 1 illustrates the effect of insertion of permanent magnets into the stator excitation poles of the proposed SRM in terms of positive flux combination with existing flux generated by the excitation poles compared to a conventional two-phase four-stator-pole two-rotor-pole (4/2) SRM.
Fig. 1.. Comparison of two SRMs in terms of placing permanent magnets during phase-A excitation: (a) conventional two-phase 4/2 SRM; (b) proposed two-phase 8/10 SRM
As shown in Fig. 1(a), two thin permanent magnets have been inserted into every stator pole in such a way that the permanent magnets are magnetized according to the polarity of windings in each stator pole. During phase-A excitation in windings, the four corresponding permanent magnets are sure to match their coils regarding the direction of flux. In this case, however, flux cancellation happens partly in the other phase as shaded in the figure (position “A”) between the energized windings and permanent magnets of phase-B due to the share of stator back iron as a flux path in the two-phase 4/2 SRM. Like the 4/2 SRM, the conflict of coils’ flux with permanent magnets’ flux gives a conventional SRM a big bottleneck in increasing its power density by employing permanent magnets into the magnetic structure.
As shown in Fig. 1(b), the two-phase 8/10 SRM has two thin permanent magnets in each stator excitation pole in the same manner as the 4/2 SRM, and four dashed loops in Fig. 1(b) are denoted as a flux path when the two phases are excited independently. It is obvious that four permanent magnets buried in the stator poles of phase-A have to generate magnetic fields in the identical direction of coils of the same phase, but the flux paths are separated from those of the other phase unlike the 4/2 SRM. The independent production of flux between phases are allowed this proposed magnetic structure to boost power density by means of the addition of permanent magnets inside its stator excitation poles since there is no cancellation in flux at all. It is noted that permanent magnets in the 8/10 magnetic configuration should assist windings’ flux.
3. Design and Analysis of Permanent-Magnet- Assisted SRM
3.1 Placement of permanent magnets in terms of torque performance
In order to investigate the effect of permanent magnets’ placement on static torque in the permanent-magnet- assisted SRM, two key design factors are chosen as space between two adjacent permanent magnets (wa) and the thickness of each permanent magnet (wb), respectively. Table 2 gives the variation of the design parameters, and the space (wa) is ranged from 2.0mm to 4.0mm in 0.4mm increments without the change of the thickness (wb) as fixed in 1.0mm.
Table 2.Change of two design parameters regarding permanent magnets
Fig. 2.Two design parameters as space between permanent magnets (wa) and thickness (wb)
The average static torque of the 8/10 permanent-magnet- assisted SRM is examined by varying space between two adjacent permanent magnets (wa) ranging from 2.0mm up to 4.0mm when torque in the case of no permanent magnets is considered as a base, and the result of average static torque at 2A is given in Fig. 3. It is shown that average static torque goes up gradually compared to the no-permanent-magnet case since the reluctance of excitation poles becomes lower as the space increases, and the average torque of the permanent-magnet-assisted SRM is 432.9% and 941.6% in the space of 2.0mm and 4.0mm, respectively, compared to the magnetic structure of no permanent magnets as shown in Fig. 3.
Fig. 3.Average static torque at 2A in the permanent-magnet-assisted SRM compared to the case of no permanent magnets by varying space between permanent magnets (wa)
3.2 Torque performance with saturation
As noticed just before, the average torque of the 8/10 permanent-magnet-assisted SRM is higher than that of no-permanent-magnet design regardless of space between two adjacent permanent magnets (wa). However, this study has been done at 2A which is recognized as low saturation based on the rated condition of 1.5 kilowatt at 3,000 rpm, and hence, the examination of torque of the proposed 8/10 SRM is stretched to magnetically saturated position ranging from 2A up to 20A. Fig. 4 shows the change of torque in the permanent-magnet-assisted SRM having 4.0mm in wa compared to the case of no permanent magnets, and the reason why the design of 4.0mm in wa has been chosen is that its torque is highest in the previous investigation given in Fig. 3. After current goes up more than 8A, the average torque of the permanent-magnet-assisted SRM becomes lower than no-permanent-magnet design since there is more saturation in the stator pole of the permanent-magnet-assisted SRM due to the removal of steel by making two pockets in each stator pole.
Fig. 4.Average static torque in the permanent-magnet-assisted SRM compared to the case of no permanent magnets by varying phase current
In an SRM, electromagnetic torque is proportional to the rate of change of inductance as expressed below.
where τ, i, L, and θ are the electromagnetic torque, phase current, inductance, and rotor position, respectively.
Considering that average torque in Fig. 4 is estimated under the condition of constant current, torque difference between the permanent-magnet-assisted and no-permanent-magnet SRMs is dependent only on inductance. The inductance of the no-permanent-magnet SRM is determined by following.
Inductance in case of the proposed SRM is expressed as
where N, , , and are the number of turns per pole, the flux of windings in the no-permanent-magnet SRM, that of windings in the permanent-magnet-assisted SRM, and that of permanent magnets in the permanent-magnet-assisted SRM, respectively.
In Fig. 5, there is the comparison of inductance profiles at 8A during one period in the permanent-magnet-assisted SRM versus the no-permanent-magnet SRM. Since the slope of inductance in the permanent-magnet-assisted SRM is less steep, the corresponding torque has to be reduced by 10.6% compared to the no-permanent-magnet case as given in Fig. 4. Even though the flux of permanent magnets is added to that of windings in the proposed SRM, the total amount of flux deteriorates gradually as phase current increases. This behavior in the permanent-magnet-assisted SRM comes from the magnetic saturation of silicon steel due to the inevitable addition of pockets for permanent magnets in each stator pole. As a result, due to smaller reluctance in he stator pole of the permanent-magnet-assisted SRM, the flux of windings becomes less than that of windings in case of no permanent magnets and such a deviation in flux from the no-permanent-magnet SRM gets worse as phase current goes up.
Fig. 5.Inductance of the permanent-magnet-assisted and no-permanent-magnet SRMs at 8A
3.3 Design modification for better reluctance
In order to improve the reluctance of stator excitation poles in the previous permanent-magnet-assisted SRM, another design parameter, the width of a stator excitation pole (wc), is applied as illustrated in Fig. 6, and its value is modified in two steps (9.26mm and 11.26mm in wc) as given in Table 3. In case of 9.26mm in wc, the average torque of the permanent-magnet-assisted SRM is improved until 12A as shown in Fig. 7(a), and it is noted that thicker width leads to more improvement in average torque compared to no-permanent-magnet case as shown in Fig. 7(b).
Fig. 6.Another design parameter for improving reluctance: the width of a stator excitation pole (wc)
Table 3.Change of width of a stator excitation pole
Fig. 7.Average static torque in the permanent-magnet-assisted SRM compared to the case of no permanent magnets by varying the width of a stator excitation pole (wc), (a) wc = 9.26mm, (b) wc = 11.26mm
3.4 Increase of copper area
Although the increase of width of a stator excitation pole (wc) enables its corresponding reluctance to go down for better performance, the width enlargement causes the reduction of copper area at the same time. Consequently, the width of a common pole (wd) in Fig. 8 needs to be modified in order to obtain enough space for excitation coils without deteriorating machine performance, and the range of its modification is given in Table 4.
Fig. 8.Last design parameter for enlarging copper area: the width of a common pole (wd)
Table 4.Change of width of a common pole
In this case, other design factors such as space between two adjacent permanent magnets (wa), the thickness of each permanent magnet (wb), and the width of a stator excitation pole (wc) are fixed in a constant value as given in Table V since the influence of wd on torque is a focus in this investigation. Compared to the copper area of the reference design, the copper area of width of 5.2mm, 6.2mm, and 7.2mm are 104.3%, 103.2%, and 102.3%, respectively
Table 5.Change of width of a permanent magnet
Fig. 9 shows the comparison of average static torque in the permanent-magnet-assisted SRM in changing the width of common poles from 7.2mm down to 5.2mm. Both 7.2 mm and 6.2mm cases have a very similar torque characteristic with approximately 0.1% maximum deviation each other, but there is approximately 0.6% drop in average torque at 20A in case of 5.2mm compared to 7.2mm design because of longer flux paths in the width of 5.2mm leading to higher reluctance.
Fig. 9.Average static torque in the permanent-magnet-assisted SRM by varying the width of a common pole (wd)
3.5 Thickness of a permanent magnet
Fig. 10 shows the average static torque of sole winding excitation versus permanent magnets in terms of percentage with respect to phase current under the condition of 7.2mm in wd and 1.0mm in wb . It is assumed that permanent magnets’ excitation is constant all the time during normal operation, but the strength of coil excitation is significantly dependent on the level of phase current. The portion of torque generated only by coils gets higher as phase current rises, but the situation of permanent magnets is the opposite as illustrated in Fig. 10. At low currents up to 6A, the ratio of torque of permanent magnets is greater than coil excitation, but torque produced by coils starts being dominated at more than 8A due to gradual boost in the magneto-motive force of coils.
Fig. 10.Average static torque of sole winding excitation versus permanent magnets’ fixed excitation with respect to phase current
Fig. 11 shows the comparison of average torque in five design modifications regarding permanent magnets’ thickness (wb) ranging from 0.6mm to 1.4mm in 0.2mm increments under the condition that the thickness of 1.0mm is considered as a base in 100% at all the levels of phase current. In this case, space between two adjacent permanent magnets (wa) has to be revised according to the variation of permanent magnets’ thickness (wb) since the width of a stator excitation pole (wc) is fixed in 11.26mm, and the dimension of four design parameters are detailed in Table 5.
Fig. 11.Average static torque in the permanent-magnet-assisted SRM by varying the width of a permanent magnet (wb)
As the thickness of permanent magnets is increased in Fig. 11, the corresponding average torque becomes higher until the phase current of 8A compared to the reference design having 1.0mm in thickness, but just after this moment, torque generated in the design of interest deteriorates due to more saturation in steel compared to the reference design. Two other modifications in thickness such as 0.6mm and 0.8mm are the opposite to the previous case, these two designs have more torque than the thickness of 1.0mm after 10A because there is more space between two adjacent permanent magnets (wa) in the designs leading to lower reluctance in their excitation poles.
Dynamic performance in the design of 0.6mm permanent magnets in thickness has been carried out, and the result of simulation is summarized and compared to 1.0mm and 1.4mm permanent magnets as given in Table 6. Also, current and torque waveforms in the three designs are compared in Fig. 12. As mentioned before, the thickness of 0.6mm in permanent magnets has better characteristics in the initial build-up of current and positive torque production in minimum and maximum inductances, respectively. In Fig. 12(b), the design of 0.6mm thickness has the lowest negative torque even though its current is almost similar to the other two designs in the region of startup, and there is the smallest copper loss of 92.8W in the design of 0.6mm because of its better positive torque generation compared to the designs of 1.0mm and 1.6mm. Also, realizing that the 0.6mm lamination has lower saturation around stator excitation poles, its core loss becomes lowest in 48.8W among the three machines. As a result, in the thickness of 0.6mm in permanent magnets, there is 0.6% and 2.6% deviation in efficiency from 1.0mm and 1.6mm designs, respectively.
Table 6.Summary of the predicted performance at 3,000 RPM
Fig. 12.Dynamic performance Estimation with single-pulse operation at 3,000rpm: (a) phase current; (b) torque
4. Comparison between No-Permanent-Magnet and Permanent-Magnet-Assisted SRMs
In this section, a comparison between no-permanent-magnet 8/10 SRM and the proposed permanent-magnet assisted SRM is conducted. Several key criteria are given to design the two machines, and they are detailed as following
The same silicon steel is used for stator and rotor laminations The external stator and shaft are the same Stack length are the same in both SRMs The back iron thickness is equal Asymmetric rotor pole faces are utilized in the design of the two SRMs to help with self-starting and continuous torque production Maximum radial air gap length between stator and rotor poles is set to 0.5mm Operating speed and rated torque is 3,000rpm and 4.6Nm, respectively
Critical dimensions and weights in both SRMs for comparison are summarized in Table 7.
Table 7.Dimensions and weights in no-permanent-magnet and permanent-magnet-assisted SRMs
4.1 Static performance comparison
From Eq. (1), torque is proportional to the square of phase current and the rate of change of inductance with respect to rotor position. Figs. 13(a) and 13(b) give inductance profiles of two 8/10 SRMs without permanent magnets and with permanent magnets, respectively. The inductances are plotted at various constant phase currents, and in this case, torque is solely dependent on the slope of inductance.
Fig. 13.Inductance profiles of two 8/10 SRMs at various currents: (a) no-permanent-magnet SRM; (b) permanent-magnet-assisted SRM
It is clear that the insertion of two thin permanent magnets into each stator excitation pole improves the addition of flux leading to the increase of inductance slope in the permanent-magnet-assisted SRM. As a result, this machine is able to end up with more torque generation compared to the 8/10 SRM with no permanent magnets.
Fig. 14(a) and 14(b) present static torque profiles in the two 8/10 SRMs for both phases at five different levels of phase current. It is noted that the permanent-magnet-assisted SRM has higher average torque than no-permanent-magnet design due to the insertion of permanent magnets. The average torque of the permanent-magnet-assisted SRM is higher by 147% and 17% at 4A and 20A, respectively, and as a result, the effect of permanent magnets becomes less as phase current goes up because of magnetic saturation in steel. The improvement of static torque in the permanent-magnet-assisted SRM needs to be quantitatively evaluated in efficiency during dynamic operation.
Fig. 14.Torque profiles of two 8/10 SRMs at various currents: (a) no-permanent-magnet SRM; (b) permanent-magnet-assisted SRM
4.2 Dynamic performance comparison
The dynamic simulation of both SRMs is conducted under single pulse operation at 3000 rpm using the same switching angles of 6.2 and 17.2 degrees in advance and dwell angles, respectively, and the result of simulation is summarized in Table 8. In the permanent-magnet-assisted SRM, there is a drop of 70.6W and 4.1W in copper and core losses, respectively. Therefore, the permanent-magnet-assisted SRM has an increase of 4.0% in the predicted efficiency over no-permanent-magnet SRM.
Table 8.Summary of dynamic performance
In Fig. 15, phase current waveforms are compared at 4.6 Nm of rated torque. Since no-permanent-magnet SRM has to create the same rated torque without permanent magnets, its phase current shows a sharp increase up to a peak of approximately 22A as shown in Fig. 15(a). On the other hand, as shown in Fig. 15(b), there is a significant drop of phase current by approximately 3 Arms in the permanent-magnet-assisted SRM due to the aid of permanent magnets. This is because the addition of permanent magnets gives rise to an increase in inductance slop leading to torque enhancement as shown in Figs. 13 and 14. The first prototype of a permanent-magnet-assisted SRM having the thickness of 0.6mm in permanent magnets is given in Fig. 16 and its stator and rotor laminations, rotor assembly, stator with windings, and stator-rotor assembly are shown in Fig. 16(a), (b), (c), and (d), respectively.
Fig. 15.Phase current in dynamic performance simulation with single pulse operation: (a) no-permanent-magnet SRM; (b) permanent-magnet-assisted SRM (solid line: 310Vdc, dotted line: 300Vdc)
Fig. 16.Photographs of the first prototype of permanent-magnet-assisted SRM: (a) stator and rotor laminations; (b) rotor assembly; (c) stator with windings; (d) stator-rotor assembly
4.3 Experimental verification
The experimental set up and driving converter of a prototype permanent-magnet-assisted SRM are shown in Fig. 17. Using an asymmetric topology, the motor test has been conducted with a single-pulse operation at 3,000 rpm, but due to the limit of the testing system in power, the efficiency of the SRM has been measured at approximately 1kW. Phase currents from dynamic simulation and laboratory testing are compared in Fig. 18 under the same condition of operation. It is seen that the two waveforms matches well, and the measured efficiency is 87.1% and there is 1.8% deviation compared to the estimated efficiency of 88.9%
Fig. 17.Experimental set up with the first prototype of permanent-magnet-assisted SRM: (a) testing installation; (b) converter drive
Fig. 18.Phase current of the first prototype of permanent-magnet-assisted SRM at 3,000rpm with a single-pulse operation: (a) dynamic simulation; (b) laboratory testing (scale: 10 A/div)
5. Conclusion
A permanent-magnet-assisted SRM is proposed for efficiency improvement, and its concept, design, and analysis has been presented. Two thin permanent magnets are inserted into every stator excitation pole in such a way that the permanent magnets are magnetized according to the polarity of windings in each stator pole. Three key design parameters such as the thickness of permanent magnets, space between two adjacent permanent magnets, and the width of stator excitation poles are determined during a design procedure. The insertion of permanent magnets into excitation poles enables the machine to be significantly improved in the initial build-up of current and positive torque production as well. It can be concluded that the thickness of permanent magnets is considered as the most critical factor in efficiency during step-by-step design processes. The thickness of 0.6mm in permanent magnets has 0.6% and 2.6% boost in efficiency over 1.0mm and 1.6mm thickness, respectively. The benefit of the proposed permanent-magnet-assisted structure has been verified analytically by a comparison with no-permanent- magnet SRM in terms of static torque comparison along with dynamic performance estimation. The proposed permanent-magnet-assisted SRM is higher than no-permanent-magnet-assisted SRM by 4.0% in efficiency under the condition of the same output power. The first prototype has been built up, and its stator and rotor laminations including its physical assembly are given in this paper. Finally, the proposed motor has been experimentally verified by giving the result of laboratory testing compared to that of estimation.
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