Design and Experimental Evaluation of a 12 kW Large Synchronous Reluctance Motor and Control System for Elevator Traction

Li, Jing-Can; Mao, Xin; Fan, Zhaolin; Liu, Ren

doi:10.1109/access.2020.2974414

Cited by 22 publications

(17 citation statements)

References 22 publications

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“…Nowadays, the line-start synchronous reluctance motors (LS-SynRMs) are actively studied with the view to replace the three-phase SCIM, because they can meet the IE4 efficiency. The presence of air flux-barriers in the rotor multi-laminated structure scale downs the hysteresis and eddy current loss on the rotor of synchronous reluctance motors [4]. During steady state operation, the induced current in rotor cage bars is zero, and the rotor copper losses are inexistent.…”

Section: Introductionmentioning

confidence: 99%

“…During steady state operation, the induced current in rotor cage bars is zero, and the rotor copper losses are inexistent. The LS-SynRM has no rotor heating problem during synchronous operation, which improves the operating efficiency and safety of the motor [4]. Two major issues have been associated with LS-SynRMs, which include poor power factor and high torque pulsation.…”

Section: Introductionmentioning

confidence: 99%

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Line-Start Synchronous Reluctance Motor With V-Shaped Rotor Laminations

Muteba

2022

IEEE Access

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A line-start synchronous reluctance motor (LS-SynRM) that meets the IE4 efficiency and has satisfactory starting and synchronizing capabilities while operating with acceptable power factor will find application in constant speed drives. This paper introduces a line-start synchronous reluctance motor with Vshape rotor laminations (LS-SynRM-VSRL). The motor, which has been designed from an IE2-132S4 conventional foot mounted three-phase induction motor NEMA frame, was modeled using the threedimensional (3D) Finite Element Method (FEM), then prototyped and tested for transient, dynamic, and steady-state performance under different load conditions. The Finite Element Analysis (FEA) and measured results of the LS-SynRM-VSRL are compared with those of a conventional line-start synchronous reluctance motor (CLS-SynRM). The results evidenced that both LS-SynRMs achieved successful synchronization on no-load, with the proposed LS-SynRM-VSRL reaching the steady state condition much quicker than the CLS-SynRM. Under steady-state operations, both LS-SynRMs achieved IE4 efficiency, with the proposed LS-SynRM-VSRL reaching an efficiency of 93.6% on full-load, in contrast to the 84.9% that the IE2-132S4 induction motor has achieved under the same loading condition.INDEX TERMS Constant speed drives, dynamic response and transient analysis, experimental measurements, finite element analysis, IE4 efficiency, line-start motor, low torque ripple, steady-state analysis, synchronizing capability, synchronous reluctance motor.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Line-Start Synchronous Reluctance Motor With V-Shaped Rotor Laminations

Muteba

2022

IEEE Access

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“…In both cases, motor or generator, the gearbox is eliminated, resulting in a higher efficiency and reliability. Both features are shared with reluctance machines, so TFMs are strong candidates to inherit reluctance machinery applications such as elevators [23,24], industrial facilities [25], and home appliances [26].…”

Section: Introductionmentioning

confidence: 99%

Analytical Optimal Design of a Two-Phase Axial-Gap Transverse Flux Motor

2021

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Transverse flux motors (TFMs) are being investigated to be used in vehicle traction applications due to their high torque density. In this paper, a two-phase axial-gap transverse flux motor is designed for an electric scooter, proposing a novel analytical design method. First, the dimensioning equations of the motor are obtained based on the vehicle requirements, and the stationary dq model is calculated. Then, the motor is optimized using a multiobjective genetic algorithm, and finally a 3D-FEM verification is made. Both the motor structure and the design method aim to have a low complexity, in order to favor the sizing and manufacturing processes through a low computation time and simple core shapes. This approach has not yet been explored in axial-gap TFMs.

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“…High-efficiency synchronous reluctance motors (SynRM) can be a good option to replace with induction motors (IM) in fulfilling the customer's requirements. The efficiency of IM decreases sharply at low speeds in applications such as chillers and elevators (Oliveira and Ukil, 2018;Matsuo and Lipo, 1994;Li et al, 2020), which work partially in the full load mode and affect the efficiency of the machine. But SynRMs can work in high-efficiency points at different speeds.…”

Section: Introductionmentioning

confidence: 99%

Torque ripples reduction in a synchronous reluctance motor by rotor parameters optimization

Naeimi

Abbaszadeh

Nasiri‐Zarandi

2021

COMPEL

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Purpose High torque ripple is the significant challenge of the synchronous reluctance machine in household electric appliances, electric vehicles and so on. This paper aims to present an optimized design of a synchronous reluctance rotor structure to reduce the torque ripple with improving the average torque by the particle swarm optimization (PSO) algorithm. Design/methodology/approach The optimization of rotor geometries has been investigated. Most of the rotor parameters such as the width of iron parts, the width of barriers along d and q axes and the endpoint angle of barriers are optimized by a new method using the PSO algorithm. After optimization, the resulted optimum design along with the initial design is simulated by two-dimensional finite element method and results are compared. At the end, a prototype is constructed and tested. Results of the experiment are compared with the simulation results where acceptable adoption is yielded. Findings Minimizing the torque ripple without losing the average torque is an important achievement of the synchronous reluctance motor (SynRM) optimization; furthermore, the finite element analysis and experimental results indicate that the torque ripple of the SynRM with the optimized rotor is reduced significantly. Also, increasing the number of optimization parameters can effectively obtain an accurate shape of the SynRM barrier. Originality/value Because of the high number of parameters in synchronous reluctance rotors, the majority of proposed optimizations did not use all geometric parameters of the rotor and tried to simplify the optimization by ignoring several optimization parameters or reducing the number of flux barriers. In this optimization, most of the rotor parameters have been used to achieve the precise barrier shape with the aim of reducing the torque ripple in SynRM.

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Design and Experimental Evaluation of a 12 kW Large Synchronous Reluctance Motor and Control System for Elevator Traction

Cited by 22 publications

References 22 publications

Line-Start Synchronous Reluctance Motor With V-Shaped Rotor Laminations

Line-Start Synchronous Reluctance Motor With V-Shaped Rotor Laminations

Analytical Optimal Design of a Two-Phase Axial-Gap Transverse Flux Motor

Torque ripples reduction in a synchronous reluctance motor by rotor parameters optimization

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