Influence of Stator MMF Harmonics on the Utilization of Reluctance Torque in Six-Phase PMA-SynRM with FSCW

Cheng, Luming; Sui, Yi; Zheng, Ping; Yin, Zuosheng; Wang, Chuanze

doi:10.3390/en11010108

Cited by 10 publications

(5 citation statements)

References 29 publications

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“…This model was subsequently utilized to deduce the precise interrelationships among different unitized machine parameters, aiming to achieve optimal performance in both inverter control (IC) and traction scenarios. Cheng et al (9) analyzed a modeling of a sixphase surface mounted PMSM (SPMSM) based on the equivalent magnetic circuit with the magnetic behavior and electrical characteristics.…”

Section: Introductionmentioning

confidence: 99%

Analytical Modelling of a Six-Phase Surface Mounted Permanent Magnet Synchronous Motor

Truong Cong,

Nguyen Vu,

Bui Minh

et al. 2024

IJE

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A multi-phase permanent magnet synchronous motors (PMSM) has applied popularly in the field of industry (e.g. trucks, ship propulsion, mining, etc) due to its high torque, efficiency and reliable operation. So far, many researchers have studied the multi-phase PMSM (e.g, a three-phase PMSM, a six-phase PMSM) for electric vehicle applications. But, there are still significant limitations in the quantity of research on the six-phase PMSMs. Particularly, when researching this type of motor, authors mainly have provided specifications of the six-phase PMSMs and then conducted experiments on these machines without giving the detailed formulations to analytically compute and design dimensions and electromagnetic parameters. In this research, an analytic model is first developed to determine the main parameters of a six-phase surface-mounted PMSM (SPMSM). The finite element method (FEM) is then introduced to simulate and compute electromagnetic parameters, such as the current waveform, back electromotive force (EMF), flux density distribution, output torque, cogging torque, torque ripple and harmonic components. The development of proposed methods is applied on a practical problem of a sixphase SPMSM of 7.5kW.

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Section: Introductionmentioning

confidence: 99%

Analytical Modelling of a Six-Phase Surface Mounted Permanent Magnet Synchronous Motor

Truong Cong,

Nguyen Vu,

Bui Minh

et al. 2024

IJE

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“…Among the reported electric motors used for HDTs, multi-phase rare-earth permanent magnet (RE-PM)-based synchronous machines are widely utilized due to their high torque and power density, maximum speed, and efficiency [1]. For multi-phase machines, fractional-slot concentrated winding (FSCW) is generally utilized because the FSCW provides the inherent fault-tolerant capability, higher winding factor, and lower cogging torque than distributed winding [4][5][6]. However, the FSCW produces unwanted space harmonics in the stator magnetomotive force (MMF), resulting in high eddy current losses in permanent magnet (PM), localized core saturation, and difficulty to produce high reluctance torque from interior-mounted rotor topology [7,8].…”

Section: Introductionmentioning

confidence: 99%

“…To suppress the stator MMF harmonics, various methods, including PM segmentation [4,5], multilayer winding design [9], coils with a different number of turns per coil side [10], and stator-shifting [11], have been reported. Among these MMF harmonic suppression methods, the stator-shifting concept reduces both sub-and high-order stator MMF harmonics effectively without increasing manufacturing costs and material usage [4][5][6]11]. This concept has been validated with various rotor topologies, including surface-mounted and interior-mounted single-and multi-layer V-type rotor topologies [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

“…Among these MMF harmonic suppression methods, the stator-shifting concept reduces both sub-and high-order stator MMF harmonics effectively without increasing manufacturing costs and material usage [4][5][6]11]. This concept has been validated with various rotor topologies, including surface-mounted and interior-mounted single-and multi-layer V-type rotor topologies [4][5][6]. However, this concept has not been validated for interior-mounted spoke-type rotor topology yet.…”

Section: Introductionmentioning

confidence: 99%

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Novel Design of Six-Phase Spoke-Type Ferrite Permanent Magnet Motor for Electric Truck Application

et al. 2022

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This paper proposes a 300 kW 24-slot/10-pole 6-phase stator-shifted fractional-slot concentrated winding spoke-type ferrite permanent magnet machine for electric truck applications. The proposed motor consists of a stator with dual three-phase windings positioned 75 degrees apart to reduce higher-order MMF harmonic order, and a rotor with an inexpensive and high-resistance ferrite permanent magnet in the spoke configuration. The simulated result of the stator-shifted machine is compared with a fabricated stator-shifted machine, and the results show good agreement with each other. To further reduce the torque ripple from 2.5 to 0.9% while maintaining a high maximum torque of 2980 Nm, circular voids with a diameter of 11 mm are embedded in the rotor. The proposed motor is evaluated for irreversible demagnetization, mechanical and thermal stability, and fault tolerant ability. To assess the proposed motor performance, the electric truck simulation model is constructed using MATLAB/Simulink and used to compare with the reported 12-slot/10-pole rare-earth permanent magnet-based machine. Compared to a previously reported six-phase rare-earth permanent magnet based flat-type machine, the proposed motor can save 4.3 kWh of energy with a USD 2512 lower cost while retaining a similar motor performance.

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“…In particular, high efficiency, high power density and cost-effective manufacturing are required in the automotive industry [1][2][3]. One possible solution to meet these requirements is to optimize the copper filling factor of stator winding [4][5][6][7][8][9][10][11]. In particular, a high copper filling factor involves a more rational and efficient use of copper with economic benefits and improved energy savings.…”

Section: Introductionmentioning

confidence: 99%

Enhanced Flexible Algorithm for the Optimization of Slot Filling Factors in Electrical Machines

et al. 2020

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The continuous development in the field of industrial automation and electric mobility has led to the need for more efficient electrical machines with a high power density. The improvement of electrical machines’ slot filling factors is one of the measures to satisfy these requirements. In recent years, this topic has aroused greater interest in the industrial sector, since the evolution of the winding technological manufacturing processes allows an economically sustainable realization of ordered winding arrangements, rather than random ones. Moreover, the manufacture of electrical machines’ windings must be preceded by an accurate design phase in which it is possible to evaluate the maximum slot filling factor obtainable for a given wire shape and for its dimensions. For this purpose, this paper presents an algorithmic approach for the evaluation of maximum slot filling factors in electrical machines under an ideal geometric premise. In particular, this algorithm has a greater degree of flexibility with respect to the algorithm approaches found in the literature, since the study has been extended to round, rectangular and hexagonal wire sections. Furthermore, the slot filling factor calculation was carried out both for standard and non-standard slots. The algorithmic approach proposed can be considered as an additional useful tool for the fast design of electrical machine windings.

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Influence of Stator MMF Harmonics on the Utilization of Reluctance Torque in Six-Phase PMA-SynRM with FSCW

Cited by 10 publications

References 29 publications

Analytical Modelling of a Six-Phase Surface Mounted Permanent Magnet Synchronous Motor

Analytical Modelling of a Six-Phase Surface Mounted Permanent Magnet Synchronous Motor

Novel Design of Six-Phase Spoke-Type Ferrite Permanent Magnet Motor for Electric Truck Application

Enhanced Flexible Algorithm for the Optimization of Slot Filling Factors in Electrical Machines

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