Your search keyword '"*AIR gap flux"' showing total 150 results

1. Magnetic Analysis of Skew Effect in Surface-Mounted Permanent Magnet Machines With Skewed Slots.

Author

Zhuang, Haijun, Zuo, Shuguang, Ma, Zhixun, Yu, Qiang, Wu, Zhipeng, and Liu, Chang

Subjects

*PERMANENT magnets, *SLOT machines, *AIR gap flux, *FINITE element method, *ELECTROMOTIVE force, *ACTINIC flux

Abstract

Surface-mounted permanent magnet (SPM) machines with skewed slots as vehicle drives are widely used. Due to skewed slots, electromagnetic characteristics are modulated by the skew effect. To analyze the skew effect, Maxwell’s equations-based 3-D analytical model is proposed. Based on differences in 3-D air-gap flux density distribution, the mechanism by which the skew effect modulates cogging torque, flux linkage, and back electromotive force (EMF) is investigated. The effectiveness of the theory about the skew effect is verified by both the finite element method (FEM) and the experimental result. [ABSTRACT FROM AUTHOR]

Published

2022

2. Analysis of Analytical Magnetic Field and Flux Regulation Characteristics of Axial-Flux Permanent Magnet Memory Machine.

Author

Cao, Yongjuan, Feng, Liangliang, Mao, Rui, and Li, Kang

Subjects

*MAGNETIC fields, *MAGNETIC flux, *AIR gap flux, *PERMANENT magnets, *CARTESIAN coordinates, *FINITE element method

Abstract

Due to the high power density, short axial size, and wide permanent magnet (PM) flux linkage regulation range, an axial-flux PM memory machine (AFPMMM) with hybrid Halbach array is investigated in this article. To solve the problem of magnetic density variation of Halbach array composed of different types of PMs in asymmetric bilateral air-gap structure, the analytical method for calculating the air-gap flux density of AFPMMM is presented through mathematical analysis, which uses cylindrical coordinate system instead of Cartesian coordinate system and is solved by equivalent method, separated variable method, and boundary conditions. The magnetic field generated by the Halbach array is divided into three directions: radial, circumferential, and axial. The analytical model is compared with the finite element method (FEM) simulation results to verify its effectiveness. In addition, an approximate piecewise linear hysteresis model with parallelogram return line is established based on the analytical expression of magnetic field. By applying different pulse currents to change the residual flux density of PM, the flux regulation characteristics of the motor are studied, and it is found that the air-gap flux density of the motor can be smoothly adjusted by continuously changing the pulse current, which plays a positive role in solving the problem of online magnetic regulation of the motor. [ABSTRACT FROM AUTHOR]

Published

2022

3. Accurate Analytical Model for Synchronous Reluctance Machine With Multiple Flux Barriers Considering the Slotting Effect.

Author

Gallardo, Cesar, Tapia, Juan A., Degano, Michele, and Mahmoud, Hanafy

Subjects

*RELUCTANCE motors, *AIR gap flux, *ELECTRIC flux, *FINITE element method, *ACTINIC flux, *MAGNETIC circuits

Abstract

This article presents an accurate analytical model (AM) for synchronous reluctance machine (SynRM) that incorporates the effect of stator slots on the air gap flux density and torque waveforms. From the formulation of magnetic potential in the air gap for both the stator and rotor, the flux density is obtained, considering the first harmonic of the flux density and the electric loading, the average torque is calculated using the Lorentz’s force. The ripple torque is obtained from the energy stored in magnetic circuit. The method is developed for a rotor with one flux barrier per pole and then extended to a larger number of barriers. To validate the results obtained by the AM proposed finite element analysis have been carried out. Several comparisons have been derived considering different rotor positions as well as different harmonic orders, and the pros and cons of the method are highlighted. The model performs fast and can predict results with high accuracy, and can be adopted to speed up the preliminary design and optimizations of this type of motors, with respect to finite element. In addition, from the analytical expressions it is possible to obtain all the correlations between electrical, magnetic, and geometrical characteristics of the machine, with the advantage of enabling a faster machine design. [ABSTRACT FROM AUTHOR]

Published

2022

4. Research on Environmental Magnetic Field of Two-Pole Permanent Magnet Motor Considering Cogging.

Author

Rao, Fan, Gao, Wei, Wu, Xusheng, and Yue, Danyang

Subjects

*PERMANENT magnet motors, *MAGNETIC fields, *AIR gap flux, *AIR gap (Engineering), *PERMANENT magnets, *MAGNETIC flux density, *GEOMAGNETISM

Abstract

The peripheral magnetic field of the motor may cause magnetic field interference to the surrounding sensors, which would reduce the accuracy of sensors and affect the safety and concealment of vessel. This article explored the environmental magnetic field distribution law of a permanent magnet (PM) motor with two-pole parallel magnetization. A no-cogging magnetic field model was obtained by solving Maxwell equations, and the relationship between the air gap flux density and the environment flux density was built considering the motor cogging effect. In addition, a mathematical model of connections between the back electromotive force (EMF) and the environmental flux density was built, and the correctness of the model was verified by COMSOL. It is concluded that the circumferential and radial components of the environmental magnetic field are distributed sinusoidally, and the magnetic flux density modulus remains constant on the equidistant circumferential line, but attenuates squarely with the distance from the motor. It provides ideas for magnetic field analysis in the peripheral environment of other types of motors, sensors, and other anti-motor electromagnetic interference, magnetic field compensation for geomagnetic measurement, and motor fault diagnosis. [ABSTRACT FROM AUTHOR]

Published

2022

5. An Efficient Air-Gap Flux Density Analysis Method for the Design of Induction Machines.

Author

Liu, Jie, Di, Chong, and Bao, Xiaohua

Subjects

*AIR gap flux, *ACTINIC flux, *MACHINE design, *FINITE element method, *MAGNETIC fields, *RELUCTANCE motors

Abstract

The magnetic field distribution in the air gap is of great importance in the design of rotary machines. In this article, an efficient analytical method is presented, which is capable of plotting the air-gap flux density waveform of induction machines (IMs) less time-consuming than the finite element method (FEM) does. The proposed method, based on the product of the current linkage waveform and the permeance waveform, utilizes the calculations of the steady-state equivalent circuit to ensure the accuracy and an equivalent air-gap reluctance model to take into account both the slot opening effect and the rotor movement. The method is tested on a general IM with different load cases and different design parameters, and the results are compared to the FEM calculations. It can be concluded that the proposed analytical method is an efficient option in the motor design to investigate the influence of the parameters on the flux density distribution. [ABSTRACT FROM AUTHOR]

Published

2022

6. A New Hybrid-Excited Partitioned Stator Flux Modulated Machine With Dual-PM.

Author

Meng, Yao, Fang, Shuhua, Liu, Wei, Pan, Zhenbao, and Qin, Ling

Subjects

*STATORS, *AIR gap flux, *ACTINIC flux, *WINDING machines, *PERMANENT magnets, *MACHINERY, *MAGNETS, *TORQUE

Abstract

This article proposes a new hybrid-excited partitioned stator flux modulated machine with a dual-permanent magnet (HE-PSFMDPMM). The HE-PSFMDPMM employs consequent-pole (CP) permanent magnets (PMs) on the inner stator and Halbach array CP PMs on the rotor, which can yield abundant air-gap flux density working harmonics to increase the torque capability. Meanwhile, the field windings are housed in the inner stator to achieve flux weakening. The topology, working principle, and design optimization of HE-PSFMDPMM are investigated, respectively. The electromagnetic performances of HE-PSFMDPMM are analyzed and compared with that of a contrast model with conventional CP PMs on the rotor. The results indicate that by using dual-PM excitation, HE-PSFMDPMM can provide large flux linkage, high torque production with low torque ripple, and high efficiency. Meanwhile, a good flux weakening capability is obtained with the aid of direct current (dc) excitation. Moreover, compared with the contrast model, the proposed HE-PSFMDPMM with Halbach array CP PMs on the rotor can offer the merits of lower cogging torque and torque ripple, higher power factor, and better flux weakening capability. [ABSTRACT FROM AUTHOR]

Published

2022

7. Investigation of Axial Field Switched Flux Memory Machine by a Combined Analytical Method.

Author

Qin, Ling, Yang, Hui, Fang, Shuhua, Pan, Zhenbao, Meng, Yao, and Lin, Heyun

Subjects

*PERMANENT magnets, *AIR gap flux, *FINITE element method, *MACHINERY, *POWER density

Abstract

This article proposes a novel axial field switched flux memory machine (AF-SFMM) which is analyzed by a combined analytical method. Compared with conventional axial field (AF) permanent magnet (PM) machines having magnets in the rotor side, the AF-SFMM benefits from good heat dissipation, high rotor robustness, and improved power density. Meanwhile, because of the utilization of low coercive force PM materials, the proposed machine can flexibly regulate air-gap flux. This analytical method is characterized by the combination of a quasi-3-D (quasi-3D) finite element method, a magnetomotive force–permeance-based method, and a virtual linear hysteresis model of low coercive force PM. In addition, compared with conventional time-consuming 3-D finite element analysis (FEA), the proposed method can improve the computational efficiency significantly with satisfactory accuracy. This makes the proposed combined analytical method suitable for preliminary sizing determination of AF-SFMM. Meanwhile, the effectiveness of the proposed analytical method is validated by FEA results. [ABSTRACT FROM AUTHOR]

Published

2022

8. Reduced Order Modeling Based on Multiport Cauer Ladder Network for Space Harmonics of Air-Gap Flux Density in Cage Induction Motor.

Author

Takahashi, Yasuhito, Fujiwra, Koji, Sugahara, Kengo, and Matsuo, Tetsuji

Subjects

*AIR gap flux, *ACTINIC flux, *TRANSIENT analysis, *INDUCTION motors, *FINITE element method

Abstract

This study investigated an efficient procedure for developing an accurate behavioral model of a cage induction motor (IM) based on the multiport Cauer ladder network (CLN). The CLN method was applied to a cage IM with semi-closed rotor slots as a model order reduction (MOR) technique, and a method for selecting the appropriate space harmonics (SHs) included in the air-gap flux density, which is necessary for a multiport CLN method for induction machines, was discussed. Then, the developed approach was applied to the transient analysis of the cage IM coupled with a control system, and its effectiveness in terms of computational accuracy and cost was investigated. [ABSTRACT FROM AUTHOR]

Published

2022

9. A New Hybrid Magnet Dual Stator Field Modulation Machine With Different Split Ratios of Stators.

Author

Wang, Haitao, Zhu, Heng, Ding, Shuye, He, Chao, Jin, Zichen, and Wei, Ziqiang

Subjects

*PERMANENT magnets, *MAGNETS, *STATORS, *AIR gap flux, *GEARING machinery, *MAGNETIC flux density, *FINITE element method, *SPACE (Architecture)

Abstract

A new type of hybrid magnet dual stator field modulation machine with different split ratios of stators (DSR-HMDSFMM) is proposed in this article, which has the merit of high torque density. The split teeth of stator sever as modulators to modulate air gap flux density based on the magnetic gearing effect for high torque production. The total split tooth number of inner stator is equal to that of outer stator because the pole pair numbers of armature reaction and permanent magnet (PM) excitation on rotor are equal. Furtherly, the inner and outer stators with different split ratios and same split tooth number are employed to increase torque production because armature windings with high winding factor and high turn number can be used. In addition, the employment of hybrid magnet excitation can increase space utilization and enhance the air gap flux density with low harmonic distortion. Therefore, the proposed DSR-HMDSFMM can achieve high torque production with the same volume and PM usage. In order to find the optimal split ratio match of stators, several DSR-HMDSFMMs with different combinations of split ratios are proposed and calculated. The configuration and operating principle are illustrated, together with electromagnetic performances of the proposed machines analyzed using finite element analysis (FEA). The FEA-predicted results show that the proposed HMDSFMM exhibits high air-gap flux density with low harmonic distortion and high torque density, which is promising for the direct-drive applications. [ABSTRACT FROM AUTHOR]

Published

2022

10. Design of Hybrid Magnetic Stage for a Magnetic–Pneumatic Levitation System.

Author

Li, Bin, Liu, Zheng, Wang, Litong, and Li, Yuehua

Subjects

*PNEUMATICS, *AIR gap (Engineering), *AIR gap flux, *MAGNETISM, *MAGNETIC flux density, *MAGNETIC circuits, *LEVITATION

Abstract

This article presents a magnetic–pneumatic levitation system for gravity offload system of large deployable mechanisms, which combines the attractive force of magnetic stage and thrust force of air-bearing and is characterized by inner stability. The article focuses on the design of the hybrid magnetic stage. The equivalent magnetic circuit network method is used to analyze the electromagnetic (EM)-permanent hybrid magnetic field, the distribution of magnetic flux density of the air gap is solved, and then the magnetic force is obtained. To improve the design efficiency, the two-step design is adopted. First, the air gap is determined by sweeping the reluctance ratio to reduce the influence of parameter deviation of cast iron on the magnetic force. Then, the other parameters of the hybrid magnetic stage are optimized based on the multi-objective particle swarm optimization (MOPSO) algorithm. Through the comparison between the results of finite-element simulation and prototype experiments, the accuracy of the model is verified, and the expected design goal is achieved. [ABSTRACT FROM AUTHOR]

Published

2022

11. An Efficient Modeling of Air Gap and Nonlinear Analysis of Magnetic Equivalent Circuit for Large Turbogenerators Under No-Load Condition.

Subjects

*MAGNETIC circuits, *TURBOGENERATORS, *NONLINEAR analysis, *AIR gap flux, *COMMERCIAL art

Abstract

Fast and accurate modeling of large turbogenerators is of great importance for optimal design and commercial value. Therefore, a 2-D nonlinear magnetic equivalent circuit (MEC) model considering saturation and rotor motion is proposed in this article. When the node-based MEC adopts relaxation iteration for nonlinear calculation, it is not easy to converge by using traditional interpolation function and piecewise fitting of the core B–H or $u_{r} (B)$ curve. The main contribution of this article is to find that using continuous fitting function is of great significance for the convergence of nonlinear iteration. At the same time, a simple and effective MEC of air gap is also provided. The flux density of air gap and stator tooth obtained by the proposed method is in good agreement with results of the finite element. No-load characteristics were also verified by the finite element and experiment. The calculation time of a cycle takes about 700 s by the finite element, and however, MEC only takes about 2 s. [ABSTRACT FROM AUTHOR]

Published

2022

12. Design and Optimization of a Low-Cost Hybrid-Pole Rotor for Spoke-Type Permanent Magnet Machine.

Author

Han, Jianbin and Zhang, Zhuoran

Subjects

*PERMANENT magnets, *AIR gap (Engineering), *AIR gap flux, *FINITE element method, *ACTINIC flux, *MACHINERY, *GENETIC algorithms

Abstract

In this article, a novel spoke-type permanent magnet (PM) machine with two types of PM materials is proposed to reduce the cost. In order to improve torque density and reduce torque ripple, the multi-objective optimization combined finite element method (FEM) and genetic algorithm (GA) are used. In addition, the electromagnetic performances of the novel spoke-type PM machine, including no-load air-gap flux density, electromagnetic torque, torque ripple, efficiency, and cost are compared with the conventional spoke-type PM machine. It is demonstrated that the novel spoke-type PM machine obtains a 1.5% lower torque ripple and 36% lower cost, and the torque density is 4.3% lower than the conventional spoke-type PM machine. Meanwhile, the novel spoke-type PM machine has lower core loss and higher efficiency. Finally, a 40 kW spoke-type PM machine is manufactured to verify the analyzing method. Experimental results demonstrate that the proposed machine exhibits high torque density and low cost in the application of electric vehicles (EVs). [ABSTRACT FROM AUTHOR]

Published

2022

13. Optimized Rotor Shape for Reducing Torque Ripple and Electromagnetic Noise.

Author

Ge, Haorui, Qiu, Xin, Guo, Baocheng, Yang, Jianfei, Bai, Chenguang, and Jin, Zhen

Subjects

*ELECTROMAGNETIC noise, *PERMANENT magnet motors, *AIR gap flux, *COMPUTATIONAL electromagnetics, *COSINE function

Abstract

This article proposes a rotor design method suitable for double-layer interior permanent magnet synchronous motor (DIPMSM), which can reduce electromagnetic torque ripple and at the same time reduce the electromagnetic noise of the motor. In previous studies, the inverse cosine function (ICF) was used to modify the rotor shape for making the air-gap flux density distribution sinusoidal under no-load conditions, which can reduce the torque ripple. However, conventional ICF can only be used in a single-layer interior rotor structure. Consequently, this article proposes a piecewise inverse cosine function (PICF) based on ICF, which can be applied to DIPMSM. To verify the improvement of the proposed method in the electromagnetic and noise aspects of the motor, the electromagnetic model and a noise prediction model of the 36-slot/8-pole motor are established by the finite element method. The PICF model is compared with the prototype in the aspects of electromagnetic performance and noise. The torque ripple is reduced by 54.16%, from ±2.4 to ±1.1 N m, and the electromagnetic noise is reduced by about 4.9 dB. Finally, the accuracy of the noise prediction model is verified by the noise test of the prototype. [ABSTRACT FROM AUTHOR]

Published

2022

14. Reduction of Torque Ripple and Rotor Eddy Current Losses by Closed Slots Design in a High-Speed PMSM for EHA Applications.

Author

Hu, Yaohua, Zhu, Shushu, Xu, Lilin, and Jiang, Bin

Subjects

*EDDY current losses, *AIR gap (Engineering), *AIR gap flux, *TORQUE, *ELECTROMOTIVE force, *PERMANENT magnets

Abstract

Electromagnetic performance of high-speed permanent magnet synchronous machines (PMSMs) is studied for electro-hydrostatic actuator (EHA) applications in this article. The electromotive force (EMF) of different magnet pole-arc to pole-pitch ratios is studied. The no-load air-gap density, cogging torque, average torque, torque ripple, core loss, and rotor eddy current losses are investigated by closed slots design. The rotor eddy current losses of different magnetic retaining sleeve materials such as stainless steel, titanium alloy, and carbon fiber are calculated by finite-element analysis (FEA). The results show that, compared with the opening slot structure, the torque ripple and the rotor eddy current losses of closed slot structure are extremely reduced due to the fact that the 11th and 13th harmonics of air-gap flux density are significantly reduced and the slotting effect are effectively weakened. Increase the closed slot height not only reduce the average torque and increase the core loss but also the torque ripple and the rotor eddy current losses reduction effect is slight. A high-speed PMSM with closed slots design is prototyped to verify the analysis. [ABSTRACT FROM AUTHOR]

Published

2022

15. High-Frequency Loss Modeling of Amorphous and Nanocrystalline Cores With Different Air Gaps.

Author

Li, Yongjian, Liu, Huan, Sun, He, and Wan, Zhenyu

Subjects

*AIR gap (Engineering), *AIR gap flux, *MAGNETIC flux, *MAGNETIC properties, *MAGNETIC cores, *MAGNETIC circuits

Abstract

In general, an air gap plays an important function in the magnetic core. It will enhance the stability of the inductance value of a reactor, increase the power density of the inductor, and optimize the properties of a high-frequency transformer. Hence, it is of great significance to study the influence of the air gap on the properties of magnetic cores. Based on a novel designed tester, the dynamic magnetic properties of the C-type amorphous (AMCC025) core and nanocrystalline (F3CC0125) core with different lengths of the air gaps are measured and analyzed when the cores are excited at different frequencies. In addition, the modified Steinmetz empirical formula which takes the fringing magnetic flux near the air gap into account is proposed. The calculated magnetic properties obtained from the modified formula show great agreement with the measured results. The average prediction error of the modified model is confined in 10%. Both the calculated and experimental results indicate that the influence of the fringing magnetic flux could be ignored when the length of the air gap is less than 5% length of the equivalent magnetic circuit. In particular, the frequency-dependent losses decrease to a minimum value and then increase with the increase in flux density accordingly. The modified loss model and results would be beneficial to the design of high-frequency inductors and transformer cores. [ABSTRACT FROM AUTHOR]

Published

2022

16. 3-D Equivalent Magnetic Network Modeling and FEA Verification of a Novel Axial-Flux Hybrid-Excitation In-wheel Motor.

Author

Hou, Jining, Geng, Weiwei, Li, Qiang, and Zhang, Zhuoran

Subjects

*PERMANENT magnets, *AIR gap flux, *TORQUE control, *MAGNETIC circuits, *MAGNETIC structure, *MAGNETIC flux, *FINITE element method

Abstract

In order to solve the problems of poor capacity and unsatisfactory efficiency of flux-weakening control for the axial-flux permanent magnet (AFPM) machines with surface-mounted permanent magnet (PM) rotor structure, a new axial-flux hybrid-excitation machine (AFHEM) with double consequent-pole rotors is proposed, which combines the high torque density of the AFPM machine and the flexible flux regulation of the hybrid excitation machine. It meets the stringent requirements of the distributed in-wheel motor electric drive vehicle for high efficiency and high torque density. The topology, principle, and basic electromagnetic properties of the new axial-flux hybrid-excitation in-wheel motor are presented in this article. Based on the complex magnetic circuit of the AFHEM, a 3-D equivalent magnetic network (EMN) model is established. The air-gap flux density, flux linkage, back EMF, torque, and fault tolerance ability of the motor are solved through the EMN model and compared with the 3-D finite element analysis (FEA) to verify its validity and correctness. It is hoped to form a rapid design method for the new type of motor with the complex structure of 3-D magnetic flux path property. Finally, based on the EMN model, the influences of the magnetic saturation on the excitation regulation capability of the proposed AFHEM are analyzed, which provides a guideline for the optimization design of the new AFHE in-wheel motor. [ABSTRACT FROM AUTHOR]

Published

2021

17. Development of a Mixed Solution of Maxwell’s Equations and Magnetic Equivalent Circuit for Double-Sided Axial-Flux Permanent Magnet Machines.

Author

Taqavi, Omolbanin and Taghavi, Nasim

Subjects

*MAXWELL equations, *MAGNETIC circuits, *AIR gap flux, *ELECTROMOTIVE force, *MAGNETIC fields, *RELUCTANCE motors, *PERMANENT magnets, *MAGNETIC flux density

Abstract

This article presents a quasi-3-D analytical model for double-sided axial-flux permanent magnet machines (AFPMMs) with coreless structures. A simple, fast, and accurate technique is developed to calculate flux densities in different parts of the AFPMM combining the solution of Maxwell’s equations and the magnetic equivalent circuit (MEC). In this technique, Maxwell’s equations are used to generate flux sources that are used in the reluctance network of the MEC. After calculating all the reluctances and flux sources, the magnetic flux densities are obtained. This method takes into account the effects of permanent magnet (PM) reluctance, leakage flux between PM-to-PM, PM-to-rotor leakage flux at different PM edges, and the fringing flux effect. By considering these leakage fluxes as a factor called variation function in the design procedure of the machine, the analysis time is dramatically reduced compared to numerical methods while maintained high reliability. It should be noted that since considering saturation phenomenon effects in coreless AFPMM analysis does not give rise to significantly different performances, they are not included in the proposed model. Furthermore, the machine’s main features, such as the axial and tangential components of the no-load flux density in the air-gap and stator areas, as well as the back electromotive force (EMF), are derived by using magnetic field solutions and simple equivalent circuits. Finally, to validate the accuracy of the proposed method, the analytical results are compared to the case that no leakage fluxes are included in the analytical model and to the 3-D finite-element analysis (FEA) in terms of computation time and accuracy. [ABSTRACT FROM AUTHOR]

Published

2021

18. Shaping of the Air Gap in a V-Typed IPMSM for Compressed-Air System Applications.

Author

Zhu, Shushu, Hu, Yaohua, Liu, Chuang, and Jiang, Bin

Subjects

*AIR gap (Engineering), *AIR gap flux, *FINITE element method, *PERMANENT magnets, *ACTINIC flux

Abstract

The shaping of the air gap of a V-typed fractional slot concentrated windings interior permanent magnet synchronous machines (IPMSMs) is investigated for compressed-air system (CAS) applications in this article. The harmonics of no-load air gap density, average torque, torque ripple, and iron losses are studied by the finite element analysis (FEA). The results show that the air gap shaping of the V-typed IPMSM can be effectively used to reduce the torque ripple and stator core loss. It is because the low-order harmonics of the air gap flux density can be reduced with a little decrease in the average torque. The proposed air gap shaping methods have the advantages of simple design and simple manufacture. A V-typed IPMSM with air gap shaping is prototyped to verify the correctness of the analysis results. [ABSTRACT FROM AUTHOR]

Published

2021

19. Anti-Demagnetization Capability Research of a Less-Rare-Earth Permanent-Magnet Synchronous Motor Based on the Modulation Principle.

Author

Zhang, Yong, Xiang, Zixuan, Zhu, Xiaoyong, Quan, Li, and Jiang, Min

Subjects

*AIR gap flux, *MAGNETISM, *DEMAGNETIZATION, *PERMANENT magnet motors, *FINITE element method, *ACTINIC flux

Abstract

In this article, a new method of enhancing the anti-demagnetization capability based on the modulation principle is proposed for a less-rare-earth permanent-magnet synchronous motor (PMSM). By means of analytical method, the relationship between the demagnetization effect and the air gap flux density, calculated by magnetic motive force (MMF) and magnetic permeance, is established. By implementing the design of the fundamental harmonic modulation, the anti-demagnetization capability of the less-rare-earth PMSM can be improved. Using the finite-element method, the electromagnetic performances of the initial and optimal motor are analyzed and compared in detail, including the demagnetization characteristics and torque characteristics. Finally, theoretical analysis and simulation results verify the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2021

20. Design of a Novel IPMSM Bridge for Torque Ripple Reduction.

Author

Song, Cheon-Ho, Kim, Do-Hyun, and Kim, Ki-Chan

Subjects

*MAGNETIC flux density, *TORQUE, *PERMANENT magnet motors, *AIR gap flux, *PERMANENT magnets, *MAGNETIC flux, *MAGNETIC structure, *BRIDGES

Abstract

The interior permanent magnet synchronous motor uses a barrier structure to block the magnetic flux circulating inside the rotor and to send the magnetic flux into the air gap. Although the airgap magnetic flux density can be increased through the barrier, there is the disadvantage of increased torque ripple. Thus, this study is conducted to determine whether the torque ripple could be reduced by changing the barrier shape. The problem here is that the torque inevitably decreases when the torque ripple is decreased. Therefore, in this study, a novel shape of the bridge is proposed in a model in which the torque ripple is reduced but the torque is not. The notch structure is applied to the bridge and is analyzed through finite-element method analysis. To intuitively express the relationship between the torque and the torque ripple, a torque efficiency factor is devised, and as a result, the torque is maintained but the torque ripple is reduced. [ABSTRACT FROM AUTHOR]

Published

2021

21. Analysis of Double-Layer Permanent-Magnet Flux Reversal Machines With Different Permanent Magnet Arrangements in Stator.

Author

Yang, Kuang, Zhao, Fei, and Wang, Yi

Subjects

*PERMANENT magnets, *AIR gap flux, *STATORS, *ACTINIC flux, *FLUX (Energy), *AIRPORTS

Abstract

This article presents two novel double-layer permanent-magnet flux reversal (PMFR) machines to improve the torque capability, namely Machine A and Machine B. Both the Machine A and Machine B are designed as the consequent-pole PMFR machines. The rotors of two machines are identical, which adopt Halbach array permanent-magnet (PM) in the rotor slot to guide the flux into the rotor teeth to reduce the leakage flux. However, the PM relative positions of two PMFR machines on the adjacent stator teeth are different, which result in different pole numbers of air-gap flux density. The operation principles and performances of two machines are introduced and compared in this article. In addition, the air gap fields of two machines by PM magnetomotive force (MMF) are analyzed and the contribution of the dominant air-gap flux density harmonics to torque is revealed. [ABSTRACT FROM AUTHOR]

Published

2021

22. Hybrid Analysis Method Considering the Axial Flux Leakage in Spoke-Type Permanent Magnet Machines.

Author

Seo, Jung-Moo, Ro, Ah-Reum, Kim, Rae-Eun, and Seo, Jangho

Subjects

*PERMANENT magnets, *AIR gap flux, *FLUX (Energy), *ACTINIC flux, *LEAKAGE, *WOOD stoves

Abstract

In this article, a novel hybrid analysis method for spoke-type permanent magnet (PM) machines (STPMMs) is presented, which considers axial flux leakage using the machine’s lumped magnetic circuit. The STPMM can increase its air-gap flux density due to its effective flux concentration, but high flux leakage occurs in the axial end of its PMs. This results in a discrepancy between conventional 2-D finite-element analysis results and experimental data. To correct the discrepancy resulting from the unwanted axial flux leakage, a virtual residual flux density of the PM is proposed through equivalent circuits and a finite analysis model. The modified residual flux density is applied to 2-D numerical analyses, and the accuracy and usefulness of the proposed method are confirmed through 3-D numerical analyses. [ABSTRACT FROM AUTHOR]

Published

2020

23. Open-Circuit Air-Gap Field Calculation of a New PM Machine Having a Combined SPM and Spoke-Type Magnets.

Author

Dajaku, Gurakuq

Subjects

*MAGNETS, *AIR gap flux, *PERMANENT magnets, *ACTINIC flux, *RARE earth metals, *MAGNETIC fields

Abstract

This article presents the open-circuit analytical magnetic field distribution model for a new permanent magnets (PMs) rotor configuration designed to improve the utilization of rare earth magnets for flux density production. The air-gap flux density is determined with the superposition method according to the magnetomotive force (MMF) and the air-gap permeance model. Since the new rotor consists of two different rotor topologies, e.g., lateral and spoke magnets, their MMF functions are determined separately. The rotor flux barrier (FB) effect on the rotor MMF harmonics is included and studied closely. The investigations carried out on different rotor topologies show high positive impact of FBs on the third or the operating wave. Compared to the conventional rotor, the utilization of PMs for air-gap flux density production significantly is improved. To verify the analytic model, finite elements (FEs) are used and several simulation results are presented. [ABSTRACT FROM AUTHOR]

Published

2020

24. Analytical Modeling and Optimization of Dual-Layer Segmented Halbach Permanent-Magnet Machines.

Author

Ni, Youyuan, Jiang, Xin, Xiao, Benxian, and Wang, Qunjing

Subjects

*AIR gap flux, *PERMANENT magnets, *ELECTROMAGNETIC forces, *MAGNETIC fields, *ELECTRIC potential, *FINITE element method

Abstract

In this article, two kinds of dual-layer segmented Halbach arrays have been proposed for permanent-magnet (PM) brushless machines. The analytical expressions of magnetic fields due to the inner-/outer-layer Halbach magnets have been separately obtained. For the maximal flux density in the air gap, the optimal magnet segment radian ratios or magnetization angles for each dual-layer Halbach array have been analytically determined separately. The induced back electromotive force and electromagnetic torque have been analytically obtained. The prediction results show that the optimized electromagnetic performances for each double-layer segmented Halbach array with different slot and pole combinations are better than those for the corresponding single-layer one. The proposed analytical model can also be applied for optimizing the multi-layer segmented Halbach array. The analytical prediction results of a PM machine with the double-layer segmented Halbach array have been compared with those obtained by a finite-element method. [ABSTRACT FROM AUTHOR]

Published

2020

25. Modeling of a Halbach Array Voice Coil Actuator via Fourier Analysis Based on Equivalent Structure.

Author

Huang, Xiaolu, Zhang, Chi, Chen, Jinhua, and Yang, Guilin

Subjects

*FOURIER analysis, *AIR gap flux, *ACTUATORS, *PERMANENT magnets, *MAGNETIC fields, *ACTINIC flux

Abstract

This paper presents the magnetic field analysis for the double layer Halbach array voice coil actuator (VCA). This VCA is composed of a stator and a mover supported by the flexure-based bearings. The mover gets three coils winded on the skeleton. The stator comprises the closed yoke and the double layer Halbach array permanent magnets (PMs). The boundary condition of the quadrangularly surrounded yoke and the aperiodic distribution of the Halbach array PMs complicate the magnetic analysis process. An equivalent VCA structure that has almost identical air-gap flux distribution to the original one is, therefore, proposed. For the equivalent structure, the boundary condition is simple and the Halbach array PMs is periodically distributed, thus the analysis process of air-gap flux density distribution via Fourier analysis is simplified. The equivalence between these two structures is validated by finite-element analysis (FEA). The analytical model is built by adopting Fourier analysis. The results of the FEA and experiments confirm the correctness of the developed model and prove the feasibility of the analytic method with the equivalent structure. [ABSTRACT FROM AUTHOR]

Published

2019

26. Analysis of a Novel Hybrid-PM Variable-Flux Machine Using New Magnet Material CeFeB.

Author

Wang, Mingqiao, Tong, Chengde, Zheng, Ping, Cheng, Luming, Zhang, Shukuan, Qiao, Guangyuan, and Sui, Yi

Subjects

*PERMANENT magnets, *AIR gap (Engineering), *AIR gap flux, *MAGNETIC circuits, *MAGNETS, *ELECTRIC potential, *FOSSIL fuels

Abstract

Electric vehicle (EV) is a promising technology for saving fossil energy and reducing pollution. Hybrid-permanent-magnet (PM) variable-flux machine is a competitive candidate for EV propulsion since it has wide speed range and high efficiency at high-speed region. A novel hybrid-PM variable-flux machine with magnetic barriers is proposed in this paper, and a new magnet material CeFeB is used. The structure and operating principle are introduced, and different magnetization states of the machine are analyzed. The equivalent magnetic circuit model of the machine is established considering the influence of magnetic barriers, and the model is proven with good precision for the calculation of air gap flux density and PM operating point. The electromagnetic performances are analyzed, and compared with a traditional variable-flux machine. It is verified that the added magnetic barriers improve the distribution of air gap flux and load magnetization performance of the machine. The no-load back electromotive force, electromagnetic torque, speed range, and load magnetization ratio of the proposed scheme are all improved. [ABSTRACT FROM AUTHOR]

Published

2019

27. Influences of Stator Teeth Number on PM Coupling Levels of Co-Axial Dual-Mechanical-Port Flux-Switching PM Machines.

Author

Zhou, Lingkang and Hua, Wei

Subjects

*PERMANENT magnet generators, *STATORS, *AIR gap flux, *TEETH, *MACHINERY, *PERMANENT magnets

Abstract

In this paper, the influence of stator teeth number on permanent magnet (PM) field couplings of co-axial dual-mechanical-port flux-switching permanent magnet (CADMP-FSPM) machines for fuel-based extended-range electric vehicles is investigated. First, the relationships between the inner and outer stator teeth numbers are analytically evaluated. Second, four typical structures, including 5/6–12/22, 10/12–12/22, 5/6–18/42, and 10/12–18/42, of CADMP-FSPM machines are analyzed, and three key stator teeth types, namely, series, parallel, and independent teeth, are defined. Third, the PM field coupling levels of four structures, featured by PM field distributions and air-gap flux densities, are compared with stator teeth matchings. The results indicate that the 10/12–12/22 structure exhibits the lowest PM field coupling and the prior open-circuit performance. Furthermore, the PM field coupling effects on the inner and outer air-gap flux densities are analyzed. Finally, a prototyped 10/12–12/22 CADMP-FSPM machine is designed, optimized, and manufactured, and the experimental results verify that the PM field coupling level of the prototype is negligible, which agrees well with the finite-element predictions and the proposed matching criteria for the selection of the inner and outer stator teeth numbers of CADMP-FSPM machines. [ABSTRACT FROM AUTHOR]

Published

2019

28. Design and Analysis of Permanent Magnet Homopolar Machine for Flywheel Energy Storage System.

Author

Liu, Z. Q., Wang, K., and Li, F.

Subjects

*ENERGY storage, *PERMANENT magnets, *AIR gap flux, *MATHEMATICAL optimization, *FLYWHEELS, *ELECTRIC potential

Abstract

This paper presents the design and analysis of a 4-poles-24-slots permanent magnet (PM) homopolar machine for the flywheel energy storage system (FESS), and the operating principle is investigated. Due to the unconventional flux distribution in this machine and the goal of the design is to minimize the torque ripple while maximizing the torque density, the parameter of this machine was obtained by the 3-D finite element global optimization genetic algorithm method. In addition, the air-gap flux density of double stator, open-circuit magnetic field distribution, flux linkage, back electromotive force stator, core loss, external characteristic were analysis, and the operating principle is verified by open-circuit magnetic field distribution. It was found that core loss can be reduced almost 34% by comparing with a heteropolar PM machine, which demonstrated that the homopolar machine is a promising candidate for the FESS. A prototype has been manufactured and tested to validate the finite-element and theoretical analyses. [ABSTRACT FROM AUTHOR]

Published

2019

29. Analytical Model of Magnetic Field of a Permanent Magnet Synchronous Motor With a Trapezoidal Halbach Permanent Magnet Array.

Author

Zhang, Xintong, Zhang, Chengming, Yu, Jikun, Du, Pengcheng, and Li, Liyi

Subjects

*PERMANENT magnet motors, *PERMANENT magnets, *MAGNETIC fields, *AIR gap flux, *ELECTRIC potential, *ACTINIC flux

Abstract

This paper presents an analytical model of magnetic field of a permanent magnet synchronous motor (PMSM) with a trapezoidal Halbach permanent magnet array (THPMA). Compared with conventional Halbach array, the shape of each magnet in THPMA is transformed from rectangle to trapezium in polar coordinates. The THPMA is delaminated indefinitely radially and each layer is approximately considered to be a conventional Halbach array. The air-gap magnetic field of each layer is analyzed with the scalar magnetic potential. Then, the air-gap magnetic field of the THPMA is obtained by superposing magnetic fields of all layers. The validity of the analytical model is verified by a finite-element model (FEM). The air-gap flux density is optimized by adjusting the center angle coefficients of the THPMA, and a no-load phase back electromotive force (EMF) with the harmonic distortion rate (THD) of 0.75% is obtained by FEM. The back EMF is basically consistent with the measured result of a prototype motor. [ABSTRACT FROM AUTHOR]

Published

2019

30. High-Performance Ferrite Permanent Magnet Brushless Machines.

Author

Shanshal, Abdullah, Hoang, Khoa, and Atallah, Kais

Subjects

*PERMANENT magnets, *AIR gap flux, *SOFT magnetic materials, *FERRITES, *MACHINING, *ACTINIC flux

Abstract

The performance of a brushless permanent magnet machine topology equipped with axially and circumferentially magnetized ferrite permanent magnets is presented. Simulation studies show that for smaller ratios of axial length to active length, air-gap flux densities in excess of 1 T can be achieved, resulting in significant improvements in torque production and efficiency. A prototype machine is manufactured, and test results confirm the predictions of the EMF and the static torque. [ABSTRACT FROM AUTHOR]

Published

2019

31. Comparative Study of Partitioned Stator Memory Machines With Series and Parallel Hybrid PM Configurations.

Author

Yang, Hui, Zheng, Hao, Zhu, Z. Q., Lin, Heyun, Lyu, Shukang, and Pan, Zhenbao

Subjects

*MAGNETIC circuits, *AIR gap flux, *PERMANENT magnet generators, *PERMANENT magnets, *MACHINING, *STATORS, *COMPARATIVE studies

Abstract

In this paper, the partitioned stator (PS) structure is extended to variable-flux memory machines, forming two newly emerged PS switched-flux memory machines (PS-SFMMs) with series and parallel hybrid magnet configurations. From the perspective of geometry, both two PS-SFMMs share identical outer stator and rotor segments, while two different types of permanent magnet (PM) arrangements are employed in the inner stationary part. Thus, the developed machines can inherent the geometric separation of the armature winding and PM excitations from the PS design, thus achieving acceptable torque capability, and excellent air-gap flux control. A comparative study between PS-SFMMs with series and parallel structures is established. First, the topologies and operating principle are introduced, respectively. In addition, the design tradeoffs and PM sizing of the two PS machines are revealed and optimized with a simplified magnetic circuit model. Then, the electromagnetic characteristics of PS-SFMMs with different magnetic circuits are investigated and compared with the finite-element (FE) method. The FE results are validated by the experiments on a parallel prototype. [ABSTRACT FROM AUTHOR]

Published

2019

32. Flux-Density Harmonics Analysis of Switched-Flux Permanent Magnet Machines.

Author

Zeng, Zhiqiang, Shen, Yiming, Lu, Qinfen, Gerada, David, Wu, Bocheng, Huang, Xiaoyan, and Gerada, Chris

Subjects

*PERMANENT magnets, *AIR gap flux, *MACHINING, *ACTINIC flux, *PHASE space, *ANALYTICAL solutions, *HARMONIC analysis (Mathematics)

Abstract

By developing a simple permeance-magnetomotive force (MMF) model of switched-flux permanent magnet (SFPM) machines, the air-gap flux density produced by both PMs and armature current can be derived, in which harmonics with the same order and rotational speed are called an effective harmonic pair (EHP). By investigating the influences of armature current angle $\delta $ on both the phase and amplitude of each EHP, it is found that the amplitudes of both PM and armature reaction flux-density harmonics maintain fixed, whereas the space phase shift between them changes accordingly with armature current angle. Specifically, the PM and armature reaction flux-density harmonics are orthogonal in space if zero ${d}$ -axis current is fed. Therefore, the maximal torque is realized for each EHP. As the total torque of SFPM machines is the superposition of the contributions by each EHP, the zero ${d}$ -axis current control method turns out to be the optimum for maximal torque per ampere, thus verifying analytically that the ${d}$ - and ${q}$ -axes inductances are equal according to the general torque equation for the investigated machine topology. In addition, the torque adjustment mechanism of each EHP in SFPM machines has also been analytically demonstrated to be resemble that of the surface-mounted PM synchronous machine (PMSM). Finally, the finite-element analysis (FEA) has been performed to validate the previous analytical predictions. [ABSTRACT FROM AUTHOR]

Published

2019

33. Calculation of PM Vernier Motors Using an Improved Air-Gap Permeance Function.

Author

Choi, Myounghyun and Kim, Byungtaek

Subjects

*AIR gap flux, *ACTINIC flux, *VERNIERS, *PERMANENT magnets, *FOURIER series, *SUPERCONDUCTING magnets

Abstract

This paper proposes a more convenient and more accurate air-gap permeance function for the calculation of the air-gap flux density of flux modulation machines with permanent magnets (PMs). First, we review the previous air-gap permeance obtained from the approximated linear model and explain the problem that the accuracy of calculation becomes worse as the magnet thickness becomes larger. To solve this problem, we introduce an equivalent model that reflects the actual cylindrical structure of the machine with slots and, then, derives the air-gap function that is easy to be converted into the Fourier series, and finally propose the new air-gap permeance function. Using the proposed permeance function, the working harmonic components in the air-gap flux density of the surface magnet vernier motor are easily predicted, and then additional characteristics as well as flux density are compared with the finite-element simulation results to check the validity of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

34. An Innovative Dual-Rotor Axial-Gap Flux-Switching Permanent-Magnet Machine Topology With Hybrid Excitation.

Author

Yildiriz, E., Gulec, M., and Aydin, M.

Subjects

*AIR gap flux, *PERMANENT magnet motors, *ELECTROMAGNETISM, *NUCLEAR excitation, *MAGNETIC control, *MATHEMATICAL optimization

Abstract

In this paper, a novel dual-rotor axial-gap flux-switching permanent-magnet machine with dc excitation winding is proposed. First, the topology and operation principles of the proposed topology are clarified. Basic design equations and parameters are provided, and the electromagnetic analyses of the proposed flux-switching machine with 3-D FEA are performed. Parametric optimizations using 3-D FEA are completed for different dc excitations. A prototype machine is manufactured, tested, and validated. It is shown that the air-gap flux of the proposed axial-gap machine can be controlled in a wide range compared to conventional surface magnet machines. [ABSTRACT FROM AUTHOR]

Published

2018

35. Low-Cost High-Torque-Density Dual-Stator Consequent-Pole Permanent Magnet Vernier Machine.

Author

Baloch, Noman, Kwon, Byung-il, and Gao, Yuting

Subjects

*TORQUE, *PERMANENT magnet motors, *FINITE element method, *ELECTROMAGNETISM, *AIR gap flux

Abstract

This paper proposes a dual-stator consequent-pole permanent magnet vernier machine comprised of two stators and a sandwiched rotor. The proposed topology has high torque density owing to its special working principle and low cost due to the consequent-pole structure. To verify the superiority of the proposed machine, it is compared with an existing dual-stator vernier machine in terms of important electromagnetic characteristics. The finite-element analysis comparison of the two machines shows that the proposed machine achieves a higher average torque and a higher torque-per-magnet volume in comparison with the existing machine. Moreover, the proposed machine uses less magnet volume; therefore, the cost of the machine is significantly reduced. Furthermore, the proposed machine is more efficient compared with the existing machine. [ABSTRACT FROM AUTHOR]

Published

2018

36. Electromagnetic Performance Comparison of Multi-Layered Interior Permanent Magnet Machines for EV Traction Applications.

Author

Zhu, Shushu, Chen, Weifang, Xie, Mingqiu, Liu, Chuang, and Wang, Kai

Subjects

*PERMANENT magnet motors, *AIR gap flux, *ELECTROMAGNETIC fields, *ELECTRIC vehicles, *ROTORS

Abstract

Electromagnetic performance of three multi-layered interior permanent magnet (IPM) machines are investigated and compared for electric vehicle applications in this paper. The rotor structure, air-gap field distribution, torque density, torque ripple, core loss, magnet eddy-current loss, and output power are studied with finite-element analysis. It is demonstrated that the two-layered rotor structure with magnets buried deeply has the lower torque density and magnet eddy-current loss due to the utilization of magnets and the block effects of the armature-reaction flux is lower. The three-layered IPM machine has the lower torque ripple and core loss than two-layered IPM machines because the harmonics of air-gap density are reduce by the increase of magnet layers. Finally, an IPM machine with three-layered magnets rotor is prototyped to verify the analysis. [ABSTRACT FROM AUTHOR]

Published

2018

37. An Effective Method With Copper Ring for Vibration Reduction in Permanent Magnet Brush DC Motors.

Author

Hong, Jianfeng, Wang, Shanming, Sun, Yuguang, and Cao, Haixiang

Subjects

*COPPER alloys, *PERMANENT magnet motors, *AIR gap flux, *IMAGE stabilization, *ELECTROMAGNETIC fields

Abstract

This paper presents a new method by sticking a copper ring on the permanent magnet pole of the permanent magnet brush dc (PMBDC) motor to reduce the electromagnetic vibration. First, the air-gap flux density distribution and radial force density distribution are derived and the principle of the electromagnetic vibration reducing technique by the copper ring is analyzed in detail. Then, finite-element method is used to calculate the Maxwell force and the vibration spectrum of a 2-pole 24-slot PMBDC motor and a modified motor. Finally, experimental results are given to validate the proposed technique, by testing the vibration spectrum of the two prototype PMBDC motors. It is shown that the acceleration of the motor with copper ring can reduce the vibration effectively compared with the origin motor, and the reduced ratio can be up to 40%. [ABSTRACT FROM AUTHOR]

Published

2018

38. Analytical Method for Overhang Effect of Surface-Mounted Permanent-Magnet Motor Using Conformal Mapping.

Author

Ko, Young-Yoon, Song, Jun-Young, Seo, Myung-Ki, Han, Wonseok, Kim, Yong-Jae, and Jung, Sang-Yong

Subjects

*SURFACE mount technology, *PERMANENT magnet motors, *AIR gap flux, *CONFORMAL field theory, *FINITE element method

Abstract

In this paper, an analytical method for predicting the rotor overhang (OH) effect is presented using two types of conformal mappings (CMs), which are the ${r}$ – ${\theta }$ and zr plane CMs. First, the no-load air-gap flux density (AFD) of a slotted air gap without OH is determined using the ${r} {\theta }$ plane CM. Second, the complex relative air-gap permeance (CRAP) in the zr plane is obtained by the zr plane CM. This helps in taking the OH effect into account. Finally, the no-load AFD of the slotted and OH air gaps in cylindrical coordinates is derived from the no-load AFD in the ${r} {\theta }$ plane with CRAP along the ${z}$ -axis. The accuracy of the presented method is verified by comparing the results of no-load analysis with those of 3-D finite-element analysis. [ABSTRACT FROM AUTHOR]

Published

2018

39. Comparative Study of Air-Gap Field Modulation in Flux Reversal and Vernier Permanent Magnet Machines.

Author

Li, Hua-Yang, Liu, Y., and Zhu, Z. Q.

Subjects

*PERMANENT magnet motors, *AIR gap flux, *VERNIERS, *COMPARATIVE studies, *HARMONIC analysis (Mathematics)

Abstract

In this paper, the torque production mechanisms of flux-reversal permanent magnet (FRPM) machine and Vernier permanent magnet (PM) machine are analyzed and compared based on air-gap field modulation. Working harmonics of PM magnetomotive force (MMF) and air-gap permeance in two machines are analytically identified and compared, indicating that the fundamental PM MMF together with all permeance harmonics contribute to the torque production of Vernier machine whereas all PM MMF harmonics but only fundamental permeance in FRPM machine produces the torque. Thanks to the utilized large dc component of air-gap permeance, the torque density of Vernier machine is revealed to be better. Influence of critical parameters on machine performance, such as PM thickness and slot width ratio of the modulation pole, is also investigated. It shows that FRPM machine is more sensitive to the design parameters. Both finite-element analysis and experimental validation are conducted to verify the conclusion. [ABSTRACT FROM AUTHOR]

Published

2018

40. A Novel Multi-Unit Out-Rotor Homopolar Inductor Machine for Flywheel Energy Storage System.

Author

Ye, Caiyong, Yang, Jiangtao, Xu, Wei, Xiong, Fei, and Liang, Xin

Subjects

*FLYWHEELS, *HOMOPOLAR machines, *ENERGY storage, *MAGNETIC flux leakage, *AIR gap flux

Abstract

The homopolar inductor machine (HIM) is of particular interest in the field of flywheel energy storage system, where it has the potential to significantly reduce self-discharge associated with magnetic losses. However, the conventional HIM suffers from low power and torque density due to its unipolar air-gap flux density. Besides, the air-gap flux density of HIM is limited by the cross section of rotor, and the rotor diameter is limited by the maximum tip speed of the rotor. Thus, the maximum effective length and diameter of rotor should be within a certain range, which constrains the output power and stored energy of the HIM. To solve these problems, a novel multi-unit out-rotor HIM (MO-HIM) with bipolar air-gap flux density is proposed in this paper. First, the structure and operating principle of MO-HIM is illustrated. Then, the characteristics of the proposed machine are analyzed, indicating that MO-HIM can be regarded as a superposition of multiple unit machines. Finally, to verify the superior performances of the proposed MO-HIM, it is compared with a unipolar out-rotor HIM with multi-segment stator cores in terms of air-gap flux density, back electromotive force, and output torque. Results show that the proposed MO-HIM has larger fundamental air-gap flux density, higher power, and torque density. [ABSTRACT FROM AUTHOR]

Published

2018

41. Design and Analysis of Halbach Ironless Flywheel BLDC Motor/Generators.

Author

Liu, Kai, Yin, Ming, Hua, Wei, Ma, Ziqi, Lin, Mingyao, and Kong, Yong

Subjects

*FLYWHEELS, *ELECTRIC generators, *PERMANENT magnet motors, *BRUSHLESS electric motors, *ROTORS, *AIR gap flux

Abstract

Halbach array-based permanent magnet (PM) brushless machines exhibit attractive features when compared with conventional PM brushless machines with normal segmented magnets, including the flux-concentration effect, essentially sinusoidal air-gap flux density due to PMs, and negligible cogging torque. However, as for a motor/generator used in flywheel, an external rotor composed of Halbach array and rotor back-iron is necessary to increase the inertia of flywheel system, which is different from the conventional external-rotor machines. In this paper, a Halbach array PM motor is studied compared with the radial magnet array. The relationship between the air-gap field distribution and the magnet array is discussed. Finally, the eddy current loss in PMs of the external-rotor ironless brushless dc motor is analyzed between the Halbach PM motor and the conventional PM motor. [ABSTRACT FROM AUTHOR]

Published

2018

42. Quantitative Analysis of Contribution of Air-Gap Field Harmonics to Torque Production in Three-Phase 12-Slot/8-Pole Doubly Salient Synchronous Reluctance Machines.

Author

Ma, X. Y., Li, G. J., Jewell, G. W., and Zhu, Z. Q.

Subjects

*AIR gap flux, *ELECTRIC windings, *TORQUE, *ELECTRICAL harmonics, *FINITE element method

Abstract

This paper adopts simple analytical modeling to investigate the contribution of air-gap field harmonics to the torque production in some three-phase, 12-slot/8-pole doubly salient synchronous reluctance machines (DSRMs) with both conventional and mutually coupled winding configurations. The air-gap flux density has been calculated based on the analytically obtained magnetomotive force and doubly salient air-gap permeance for both the double-layer and single-layer DSRMs with different winding configurations. Then, the contribution of different air-gap field harmonics to average torque and torque ripple can be investigated and validated by direct finite-element analyses. It has been found that in the DSRMs, the 10th-order harmonic in the double-layer conventional winding (DLC), the 4th-order harmonic in the double-layer mutually coupled winding (DLMC), the 7th-order harmonic in the single-layer conventional winding (SLC), and the 10th-order harmonic in the single-layer mutually coupled winding (SLMC) have the highest contribution to positive average torque and with positive influence on torque ripple reduction. However, the 2nd-order harmonic in the DLC, the 8th-order harmonic in the DLMC, the 5th-order harmonic in the SLC, and the 2nd-order harmonic in the SLMC machines mainly reduce the average torque. [ABSTRACT FROM AUTHOR]

Published

2018

43. Analytical Modeling of Switched Flux Memory Machine.

Author

Yang, Hui, Lin, Heyun, Li, Yibo, Wang, Haitao, Fang, Shuhua, and Huang, Yunkai

Subjects

*OPEN-circuit voltage, *AIR gap flux, *MAGNETIC hysteresis, *ELECTRIC potential, *FINITE element method

Abstract

This paper presents the simple analytical modeling for switched flux memory machine to provide in-depth insight into its working mechanism. The analytical approach is based on the slotless open-circuit air-gap flux density and the slotted air-gap relative permeance calculations for a doubly salient structure. In addition, due to low coercivity and highly nonlinear hysteresis curve at the second quadrant, the piecewise and virtual-linear hysteresis models of AlNiCo permanent magnet (PM) are presented to determine the PM working point. This combined analytical solution allows rapid calculation of several electromagnetic characteristics, e.g., air-gap flux density and back electromotive force. The effectiveness of the analytical method is validated by both finite-element results and measurements. [ABSTRACT FROM AUTHOR]

Published

2018

44. The Relationship of Magnetomotive Force Under Different Excitation Modes of Dual-Excited Synchronous Generator.

Author

Xu, Guorui, Hu, Yiping, Hao, Xiajing, Zhan, Yang, Zhao, Haisen, Liu, Xiaofang, and Luo, Yingli

Subjects

*MAGNETOMETERS, *SYNCHRONOUS generators, *EXCITATION spectrum, *ROTORS, *AIR gap flux

Abstract

The high stability of the dual-excited synchronous generator (DESG) can enhance the reliability of power supply for critical users. Based on the traditional synchronous generator (TSG), a DESG with two sets of symmetrical field windings on the rotor is presented in this paper. The rotor slots are spaced equally over the whole rotor surface of DESG, which is different from the structure of TSG. Such structures of DESG are expected to enhance the reliability and give the electromagnetic performances, such as air-gap flux density and electromotive force (emf) that are close to those of TSG. For this purpose the relationship between the excitation magnetomotive forces (mmf) of the single- and dual-axis excited DESG is investigated. The mmf with a different rotor pitch is calculated by the finite-element simulation, and the simulation results agree with those by the theoretical derivation. The excitation air-gap flux density, emf, and the magnetic saturation in stator and rotor cores are calculated under different excitation modes, and the results are compared with those of TSG. In order to validate the simulation results, the emf of 10 kW DESG model machine is measured under different excitation modes. This paper provides the theoretical basis for the design and manufacture of large DESGs. [ABSTRACT FROM AUTHOR]

Published

2018

45. Nonlinear Equivalent Magnetic Network of a Linear Permanent Magnet Vernier Machine With End Effect Consideration.

Author

Liu, Guohai, Ding, Ling, Zhao, Wenxiang, Chen, Qian, and Jiang, Shan

Subjects

*VERNIERS, *PERMANENT magnet motors, *AIR gap flux, *ELECTRIC potential, *STRAY currents, *FINITE element method

Abstract

A nonlinear equivalent magnetic network (EMN) model is proposed for a linear permanent magnet vernier (LPMV) machine. The meshing method is employed to solve the problem of the modeling of complex flux paths in stator teeth tips. Especially, an end-region model based on the electromagnetic principle is developed to consider the longitudinal end effect of the LPMV machine. The key contribution of this paper is to present a faster and simpler approach to separate the detent force (end force component and cogging force component) than finite-element analysis (FEA). Besides, taking the iron saturation and air-gap flux leakage into account, the proposed model is used to predict the electromagnetic performances of the LPMV machine, such as air-gap flux density, back-electromotive force, cogging force, and thrust force. Finally, through comparisons among the FEA simulations, experimental measurements and EMN analyses, the accuracy and effectiveness of the proposed model are verified. [ABSTRACT FROM PUBLISHER]

Published

2018

46. Analytical Modeling of No-Load Eccentric Slotted Surface-Mounted PM Machines: Cogging Torque and Radial Force.

Author

Taghipour Boroujeni, Samad, Jalali, Pezhman, and Bianchi, Nicola

Subjects

*PERMANENT magnets, *AIR gap flux, *CURRENT sheets, *MAGNETISM, *FINITE element method, *PHASE modulation, *ELECTROMAGNETIC measurements

Abstract

In this paper, the air-gap flux density components in the eccentric surface-mounted phase modulation (SPM) machines are predicted analytically. In the provided model, the slotting effects of the armature are taken into account. In the modeling process, conformal transformations (CTs) are employed to obtain an equivalent concentric slotless machine for the eccentric slotted PM machine. To satisfy the condition of using CTs, i.e., having a Laplace equation, the PMs are replaced with an equivalent current sheet at the surface of the rotor. The approach of finding this current sheet is approved by the basis of the electromagnetic theory. One of the contributions of this paper is that the provided model is capable of modeling the eccentric SPM machines with any PM magnetization pattern by means of CTs. Substituting the predicted air-gap flux density components in the Maxwell stress tensor, the machine unbalanced magnetic force and its cogging torque are computed. Finally, the accuracy of the obtained results is evaluated by means of finite-element analysis. [ABSTRACT FROM PUBLISHER]

Published

2017

47. Influence of the Distributed Air Gap on the Parameters of an Industrial Inductor.

Author

Jez, Radoslaw

Subjects

*AIR gap flux, *MAGNETISM, *ELECTROMAGNETISM, *ELECTRIC inductors, *MAGNETIC flux leakage

Abstract

Air gaps are often used in a design of power inductors. Different arrangements of air gap in a magnetic circuit influence the parameters of an inductor. Understanding this dependence allows a design of more efficient inductors. In this paper, the influence of different air-gap arrangements on the distribution of the magnetic flux density, the value of saturation current, and the power losses is presented. The 3-D finite-element analyses and laboratory measurements were realized for the exemplary inductor made of grain-oriented steel and copper foil. Additionally, the main rules of the design of inductors with distributed air-gap arrangement are also given. [ABSTRACT FROM AUTHOR]

Published

2017

48. Modulating Ring Structural Configuration Influence on the Dual Air-Gap Magnetic Gear Electric Machine.

Author

Ubadigha, Chinweze U., Tsai, Mi-Ching, and Hsieh, Min-Fu

Subjects

*MAGNETICS, *AIR gap flux, *ELECTRIC machinery, *FINITE element method, *ELECTROMAGNETISM

Abstract

In this paper, a study was conducted using a unit equivalent magnetic circuit (EMC) in correlating the relationship between the magnet thickness, the modulating ring pole-piece thickness, and their circumferential pitch. A numerical optimization method is employed in selecting the optimum ratio of the magnet to pole-piece thickness. The study reveals the need to simultaneously consider these parameters during the design of a magnetic gear electric machine because of their strong mutual dependency. A finite element analysis (FEA) was conducted using the optimum ratios. The results correspond to those of the EMC. Also, the performance of the machine is analyzed and found to have a power factor of 0.78. To further verify the results of FEA, a prototype was built using the same configurations of the FEA model. Measurements taken from the prototype are on par with the simulated results. [ABSTRACT FROM AUTHOR]

Published

2017

49. Flux Weakening Performance of Permanent Magnet Synchronous Motor With a Conical Rotor.

Author

Chai, Feng, Zhao, Kui, Li, Zongyang, and Gan, Lei

Subjects

*PERMANENT magnets, *SYNCHRONOUS electric motors, *ELECTRIC potential, *AIR gap flux, *FINITE element method

Abstract

The general flux weakening control method for permanent magnet synchronous motor (PMSM) is changing the angle between the current and the no-load back-electromotive force (EMF). This paper presents a novel structure of PMSM with a conical rotor (CR-PMSM) and studies its flux weakening performance in detail. The CR can be moved outside in axial direction, which decreases the air-gap flux density as well as the effective space between the stator and the rotor. This method is effective in increasing the maximum speed and the output power of PMSM, including the surface-type and interior-type. 3-D finite-element model is used to simulate the magnetic-field distribution, flux weakening, and driving performance in CR-PMSM according to rotor axial displacement. The motoring performance of CR-PMSM is compared with that of the general method. A prototype machine with a cone angle of 5.7 and a rated power of 140 W at a rated speed of 300 rpm is designed and built to validate the theory. [ABSTRACT FROM AUTHOR]

Published

2017

50. Quantitative Design of a High Performance Permanent Magnet Vernier Generator.

Author

Zhang, Jian, Tounzi, Abdelmounaim, Delarue, Phillipe, Piriou, Francis, Leontidis, Vlasios, Dazin, Antoine, Caignaert, Guy, and Libaux, Antoine

Subjects

*PERMANENT magnets, *TORQUE, *FINITE element method, *MAGNETIZATION, *AIR gap flux

Abstract

Permanent-magnet vernier machines are becoming more and more attractive due to their high torque density and low-speed operating capabilities. This paper investigates the effects of the magnet thickness, magnet pole arc ratio, and slot open ratio on the torque capacity. An analytical model is first presented. It is validated by comparing the results with the finite-element analysis (FEA) under the same hypothesis. A mono-objective optimization is then conducted on the basis of the analytical model coupled to genetic algorithm to reach the optimal values yielding the highest value of the torque. Finally, the influence of nonlinear magnetic material behavior on the optimal design is investigated through nonlinear FEA. The results are presented and discussed. [ABSTRACT FROM AUTHOR]

Published

2017