Your search keyword '"Motor design"' showing total 14 results

1. Sizing of a Traction Switched Reluctance Motor for an Electric Refuse-Collecting Vehicle Application

Author

Alexander Forsyth, Francisco Juarez-Leon, and Berker Bilgin

Subjects

electric vehicles, finite element analysis (FEA), heavy duty vehicles, motor design, refuse-collecting vehicle, switched reluctance motor (SRM), Mechanical engineering and machinery, TJ1-1570

Abstract

Refuse-collecting vehicles are significant polluters due to their expected drive cycles involving frequent stops and long idle periods. Electric refuse-collecting vehicles, still in their infancy, promise to address this through the replacement of internal combustion engines with batteries and electric traction motors. Today, typical motors for these vehicles involve heavy use of rare earth permanent magnets, which are subject to high price volatility, environmentally damaging mining practices, and occupational health hazards associated with refinement. The switched reluctance motor, which makes use of no permanent magnets, is a suitable substitute. This type of motor technology offers several advantages such as simple and robust construction, the ability to operate at high speeds and high temperature conditions, fault tolerance capability, and lower production costs in comparison with other technologies. This paper focuses on the design process of a switched reluctance motor for a battery electric refuse-collecting vehicle. The designed motor has a 36/24 outer rotor configuration, and its electrical and mechanical characteristics are based on the commercial traction motor TM4 SUMO HD HV3500-9P. The performance of the motor is evaluated using simulation tools such as JMAG and MATLAB/Simulink.

Published

2023

2. E-Bike Motor Drive: A Review of Configurations and Capabilities

Author

Chiara Contò and Nicola Bianchi

Subjects

Permanent Magnet Synchronous Motor (PMSM), synchronous machine, light electric vehicles, electric bicycle, motor design, Technology

Abstract

In recent years, the mobility sector is undergoing a revolution, which is resulting also into a worldwide spread of light electric vehicles, such as electric scooters and bicycles. The increasing public concern about environmental problems further feeds this revolution. Electric-bicycles (or e-bikes) are a new trend which fits different riders’ needs. In fact, they offer extended range and ease of use, allowing riders to travel in urban centres, but also to take longer trips. E–bikes are reliable, easy to ride, affordable, and they help people live and travel a little greener, with a great benefit for their health. Many Companies (such as Brose, Bafang, Bosch and Shimano) developed performing e-bike motor drives. However, there is not a detailed general procedure to help the choice and design of electric bikes, in particular concerning the electric machine. This review focuses on the analysis of different motors for e-bike application. First, the e-bike system state of art is presented. The pedal-assist and power-on-demand e-bike system typologies are presented, together with the most popular parallel configuration and the less common series configuration. Further on, the environmental resistances are analysed for a traditional bicycle system and then the force balance is extended to the electric vehicle example. The most common Lithium-ion battery and the battery management system state of art is discussed, presenting design schemes and typical performances. Concerning the electrical machine, some electromagnetic design approaches are described, together with some data on commercial motors. Finite element analysis of a common motor model is carried out and some experimental tests are presented to highlight their capabilities. Different control strategies are compared, including innovative solutions and new trends.

Published

2022

3. A Hybrid-Excitation Synchronous Motor with a Change in Polarity

Author

Chiara Contò and Nicola Bianchi

Subjects

permanent magnet synchronous motor (PMSM), synchronous machine, change in polarity, motor design, Mechanical engineering and machinery, TJ1-1570

Abstract

The hybrid-excitation permanent magnet (HEPM) motor is a synchronous motor characterized by a rotor that includes both permanent magnets and excitation windings. Thus, an active change in the magnetic flux by means of the excitation current is possible. In particular, the hybrid-excited rotor studied in this paper can be used to change the number of poles of the rotor itself. At the same time, the stator winding is also designed to perform a polarity change. The change in polarity allows users to obtain different torque versus speed characteristics with the same motor. In particular, a configuration with a lower pole number exhibits low torque at high speeds, while a configuration with a higher pole number produces high torque at low speeds. In this way, a single HEPM motor behaves like two different machines, extending the usual operating speed range of synchronous motors. In this paper, an HEPM rotor configuration is designed, and its performance is analyzed through finite element electromagnetic and thermal simulations.

Published

2022

4. Analysis and Mitigation of AC Losses in High Performance Propulsion Motors

Author

Ahmed Hebala, Stefano Nuzzo, Peter H. Connor, Giuseppe Volpe, Chris Gerada, and Michael Galea

Subjects

AC losses, finite element analysis, motor design, PMSM, propulsion motor, winding configuration, Mechanical engineering and machinery, TJ1-1570

Abstract

In this paper, the AC copper losses in classical random windings are investigated and mitigated using several techniques across a range of permanent magnet synchronous motor designs. At high operating frequencies, AC copper losses can represent a substantial share of the total loss in electrical machines, thus, reducing the machine’s overall performance, and increasing the thermal loading. Recently, different approaches for modelling AC copper losses have been proposed. This paper utilises simulation software to quantify the expected AC losses in six different propulsion motor designs. The motor designs are then modified to reduce the AC winding losses through the implementation of five different methods. Using two-dimensional finite element analysis, the magnetisation direction, magnet to airgap ratio, copper stranding, magnetic wedges and the motor slot openings are modified to reduce AC losses. The paper considers distributed, fractional, slot and concentrated windings, and the results show promising reductions across these different winding configurations.

Published

2022

5. A Permanent Magnet Assembling Approach to Mitigate the Cogging Torque for Permanent Magnet Machines Considering Manufacturing Uncertainties

Author

Haipeng Liu, Xin Jin, Nicola Bianchi, Gerd Bramerdorfer, Pengzhong Hu, Chengning Zhang, and Yongxi Yang

Subjects

motor design, robust assembling approach, combination sequence of uncertainties, cogging torque reduction, PM uncertainties, Technology

Abstract

Conventionally, the small mean and variance of peak-to-peak cogging torque of permanent magnet (PM) machines considering manufacturing uncertainties can be achieved by a robust design or by reducing the uncertainties range. However, the consequent compromise of other design objectives or the increase in the manufacturing costs are frequently inevitable. In this paper, the combination sequence of the uncertainties is highlighted and implemented to achieve a stable performance even for a non-robust design without increasing the cost too much. A PM assembling approach is proposed to mitigate the influences of PM uncertainties on cogging torque by means of combining the uncertainties in a particular sequence, where the effects of uncertainties would counteract each other. Both the singular type of PM uncertainties and the combined ones are considered in the assembling approach. Furthermore, the proposed approach is verified by comparing the cogging torque performance with PM randomly assembled models, where several hundreds of models featuring different uncertainties are calculated through the finite element method. The proposed approach is discussed, particularly for the application of mass production and a small amount of prototypes. Two prototypes with different PM assembling sequences are fabricated and further verify the effectiveness of the proposed PM assembling approach.

Published

2022

6. Iron Loss Modelling of Electrical Traction Motors for Improved Prediction of Higher Harmonic Losses

Author

Jan Rens, Lode Vandenbossche, and Ophélie Dorez

Subjects

finite element calculation, motor design, efficiency, harmonics, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Transportation engineering, TA1001-1280

Abstract

A Finite Element (FE) modelling approach is presented to account for the core losses in electrical machines that are generated by higher harmonic frequencies, for example those caused by Pulse Width Modulation (PWM) switching or by space harmonics due to the machine geometry. The model builds further on a post-processing calculation tool that was recently developed to take into account the magnetic skin effect in electrical steel laminations at high frequencies, and extends this by a more detailed loss analysis of the minor hysteresis loops that are caused by the higher harmonics. Further, these tools for high-frequency loss analysis are integrated into a complete electrical machine model with separate consideration of the major and minor loops. The modelling approach relies strongly on extensive magnetic measurement data of the electrical steel, in order to accurately predict the different loss components for minor hysteresis loops as a function of the DC bias field, frequency and amplitude of the minor loop. Results from the model are shown for an automotive traction motor, illustrating the losses caused by PWM harmonics and demonstrating the relevance of including the skin effect in these calculations.

Published

2020

7. Design and Implementation of a Low Power Outer-Rotor Line-Start Permanent-Magnet Synchronous Motor for Ultra-Light Electric Vehicles

Author

Mustafa Tumbek and Selami Kesler

Subjects

outer rotor, line-start, synchronous motor, FEM, motor design, electric vehicle, Technology

Abstract

Recently, while electric vehicles (EV) have substituted the fossil fuel vehicles, the design of the electrical motors with more efficient and less mechanical converters has become mandatory due to the weighting gears, mechanical differentials, and other cost-increasing parts. To overcome these problems, double electrical motors with low speed and high torque have been designed and used in the rear wheels of the EVs without any gearbox and mechanical differential. In this study, a novel outer rotor line-start hybrid synchronous motor is proposed as another solution. For this aim, four different hybrid rotor types, including magnets and rotor bars, have been designed and analyzed. Calculation and estimation of all parameters to design a motor are introduced. All of the analyses were carried out by Finite Elements Method (FEM). One of the analyzed motors, which is called Type-D was selected and implemented because of the best startup performance and better steady-state behavior under the rated load and overload. While holding this motor at synchronous speed under nominal load, in case of overloading, it remained in asynchronous mode, thus maintaining the sustainability of the system. Obtained results prove that the newly proposed outer rotor LSSM has the advantages of both synchronous motor and asynchronous motor. All of the experimental results validate the simulations well. The effects of the magnet alignments and dimensions on the performance of the motors are presented.

Published

2019

8. Optimal Pole Number and Winding Designs for Low Speed–High Torque Synchronous Reluctance Machines

Author

Gurutz Artetxe, Jesus Paredes, Borja Prieto, Miguel Martinez-Iturralde, and Ibon Elosegui

Subjects

AC drives, magnetless machine, synchronous reluctance, synchronous reluctance machines (SynRM), motor design, fractional slot concentrated winding, fractional-slot concentrated-windings (FSCW), Technology

Abstract

This paper studies the feasibility of using synchronous reluctance machines (SynRM) for low speed–high torque applications. The challenge lies in obtaining low torque ripple values, high power factor, and, especially, high torque density values, comparable to those of permanent magnet synchronous machines (PMSMs), but without resorting to use permanent magnets. A design and calculation procedure based on multistatic finite element analysis is developed and experimentally validated via a 200 Nm, 160 rpm prototype SynRM. After that, machine designs with different rotor pole and stator slot number combinations are studied, together with different winding types: integral-slot distributed-windings (ISDW), fractional-slot distributed-windings (FSDW) and fractional-slot concentrated-windings (FSCW). Some design criteria for low-speed SynRM are drawn from the results of the study. Finally, a performance comparison between a PMSM and a SynRM is performed for the same application and the conclusions of the study are summarized.

Published

2018

9. Design and Implementation of a Low Power Outer-Rotor Line-Start Permanent-Magnet Synchronous Motor for Ultra-Light Electric Vehicles

Author

Selami Kesler and Mustafa Tumbek

Subjects

business.product_category, Outer rotor, Electric vehicles, Computer science, Synchronous motors, outer rotor, 02 engineering and technology, Electric vehicle, lcsh:Technology, Automotive engineering, law.invention, law, Mechanical differential, 0202 electrical engineering, electronic engineering, information engineering, motor design, Rotor (electric), Motor design, synchronous motor, Finite elements method (FEM), Power (physics), Design and implementations, Transmission (mechanics), Steady-state behaviors, Synchronous motor, Gears, Electric motor, Finite element method, Control and Optimization, Permanent magnets, 020209 energy, Line start, Energy Engineering and Power Technology, Traction motors, Line start permanent magnets, Electrical and Electronic Engineering, Engineering (miscellaneous), FEM, Fossil fuels, Renewable Energy, Sustainability and the Environment, lcsh:T, 020208 electrical & electronic engineering, line-start, electric vehicle, Vehicles, Line (electrical engineering), Electric lines, Induction motors, Line-start, Magnet, business, Induction motor, Energy (miscellaneous)

Abstract

Recently, while electric vehicles (EV) have substituted the fossil fuel vehicles, the design of the electrical motors with more efficient and less mechanical converters has become mandatory due to the weighting gears, mechanical differentials, and other cost-increasing parts. To overcome these problems, double electrical motors with low speed and high torque have been designed and used in the rear wheels of the EVs without any gearbox and mechanical differential. In this study, a novel outer rotor line-start hybrid synchronous motor is proposed as another solution. For this aim, four different hybrid rotor types, including magnets and rotor bars, have been designed and analyzed. Calculation and estimation of all parameters to design a motor are introduced. All of the analyses were carried out by Finite Elements Method (FEM). One of the analyzed motors, which is called Type-D was selected and implemented because of the best startup performance and better steady-state behavior under the rated load and overload. While holding this motor at synchronous speed under nominal load, in case of overloading, it remained in asynchronous mode, thus maintaining the sustainability of the system. Obtained results prove that the newly proposed outer rotor LSSM has the advantages of both synchronous motor and asynchronous motor. All of the experimental results validate the simulations well. The effects of the magnet alignments and dimensions on the performance of the motors are presented. © 2019 by the authors.

Published

2019

10. Multiobjective Ant Lion Approaches Applied to Electromagnetic Device Optimization

Author

Viviana Cocco Mariani, Sotirios K. Goudos, Leandro dos Santos Coelho, Christos S. Antonopoulos, Spiridon Nikolaidis, Juliano Pierezan, Nikolaos V. Kantartzis, and Achilles D. Boursianis

Subjects

010302 applied physics, metaheuristics, Technology, Mathematical optimization, Computer science, brushless DC motor design, 020209 energy, MathematicsofComputing_NUMERICALANALYSIS, 02 engineering and technology, Random walk, ComputingMethodologies_ARTIFICIALINTELLIGENCE, 01 natural sciences, Multi-objective optimization, Swarm intelligence, Tournament selection, Field (computer science), electromagnetic optimization, Motor design, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, multiobjective optimization, Electromagnetic optimization, ant lion optimizer, Metaheuristic

Abstract

Nature-inspired metaheuristics of the swarm intelligence field are a powerful approach to solve electromagnetic optimization problems. Ant lion optimizer (ALO) is a nature-inspired stochastic metaheuristic that mimics the hunting behavior of ant lions using steps of random walk of ants, building traps, entrapment of ants in traps, catching preys, and re-building traps. To extend the classical single-objective ALO, this paper proposes four multiobjective ALO (MOALO) approaches using crowding distance, dominance concept for selecting the elite, and tournament selection mechanism with different schemes to select the leader. Numerical results from a multiobjective constrained brushless direct current (DC) motor design problem show that some MOALO approaches present promising performance in terms of Pareto-optimal solutions.

Published

2021

11. Driving-Scenario Oriented Optimal Design of an Axial- Flux Permanent-Magnet Motor for an Electric Vehicle

Author

Yee-Pien Yang and Guan-Yu Shih

Subjects

010302 applied physics, Optimal design, Physics, business.product_category, permanent magnet motor, 020208 electrical & electronic engineering, Direct current, electric vehicle, 02 engineering and technology, Energy consumption, 01 natural sciences, Automotive engineering, Quantitative Biology::Subcellular Processes, brushless motor, 0103 physical sciences, Automotive Engineering, Electric vehicle, 0202 electrical engineering, electronic engineering, information engineering, Torque, motor design, business, optimization, Energy (signal processing), Driving cycle, Voltage

Abstract

This paper proposes a driving-scenario oriented optimal design of an axial-flux permanent-magnet (AFPM) motor for an electric vehicle. The target torque and speed (TN) curve is defined as three operation zones— constant torque, maximum direct current, and maximum voltage—based on the driving scenario. The AFPM motor is designed to minimize energy consumption based on the motor weight and the frequent operating points of a driving cycle. The final result shows that the electric vehicle driven by the proposed AFPM motor consumes about 15% less energy than motors designed using traditional methods.

Published

2016

12. Iron Loss Modelling of Electrical Traction Motors for Improved Prediction of Higher Harmonic Losses

Author

Lode Vandenbossche, Jan Rens, and Ophélie Dorez

Subjects

Materials science, finite element calculation, 02 engineering and technology, engineering.material, 01 natural sciences, Traction motor, harmonics, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, motor design, 010302 applied physics, 020208 electrical & electronic engineering, lcsh:TA1001-1280, Mechanics, Finite element method, Hysteresis, efficiency, Harmonics, Automotive Engineering, Harmonic, engineering, Skin effect, lcsh:Electrical engineering. Electronics. Nuclear engineering, lcsh:Transportation engineering, lcsh:TK1-9971, Pulse-width modulation, Electrical steel

Abstract

A Finite Element (FE) modelling approach is presented to account for the core losses in electrical machines that are generated by higher harmonic frequencies, for example those caused by Pulse Width Modulation (PWM) switching or by space harmonics due to the machine geometry. The model builds further on a post-processing calculation tool that was recently developed to take into account the magnetic skin effect in electrical steel laminations at high frequencies, and extends this by a more detailed loss analysis of the minor hysteresis loops that are caused by the higher harmonics. Further, these tools for high-frequency loss analysis are integrated into a complete electrical machine model with separate consideration of the major and minor loops. The modelling approach relies strongly on extensive magnetic measurement data of the electrical steel, in order to accurately predict the different loss components for minor hysteresis loops as a function of the DC bias field, frequency and amplitude of the minor loop. Results from the model are shown for an automotive traction motor, illustrating the losses caused by PWM harmonics and demonstrating the relevance of including the skin effect in these calculations.

Published

2020

13. Electrical Propulsion System for Aviation – Experimental Validation of Efficiency Improvements

Author

Jakub Bernatt, P. Pistelok, and Emil Król

Subjects

Electric motor, Battery (electricity), business.product_category, Permanent magnet synchronous motor, Computer science, Aviation, business.industry, paraglider, Propulsion, Battery pack, Automotive engineering, Airplane, Electrically powered spacecraft propulsion, permanent magnet synchronous motor, electric drives, Automotive Engineering, battery, motor design, business

Abstract

This paper deals with electrical propulsion system for light airplane or paraglider. The electrical drive consists of electrical motor, frequency converter and the batterypack. Electrical motor used in a light paraglider was designed as a permanent magnet synchronous motor (PMSM) in the Research and Development Centre of Electrical Machines KOMEL, Poland. Parameters of the motor, frequency converter and battery pack were shown. In this article, an influence of different propellers (1 fixed, 2 adjustable) and results of laboratory test was described. For increasing the efficiency of the electric propulsion, influence of switching frequency of the converter were tested and presented. The results of laboratory test were discussed.

Published

2012

14. Magnetic material optimization for hybrid vehicle PMSM drives

Author

Patrick Goes, François Henrotte, M.H. Gracia, Dietrich Hectors, Martin Hafner, Kay Hameyer, and Sigrid Jacobs

Subjects

permanent magnet motor, Computer science, finite element calculation, Efficiency, High power density, engineering.material, Automotive engineering, materials, Power (physics), law.invention, PHEV (plug in hybrid electric vehicle), series HEV, Stack (abstract data type), law, Magnet, Automotive Engineering, Lamination, engineering, Train, low loss fully processed electrical steels, motor design, Hybrid vehicle, optimization, Electrical steel

Abstract

The motivation of this analysis is the need of high efficiency and high power density permanent magnet synchronous motor (PMSM) drives for use in electrical vehicle power trains. It is clear that the chosen electrical steel for the lamination stack plays an important role, but proper quantification is missing. The purpose of this paper is to formalize the problem of selecting the optimal steel grade for the construction of PMSM’s. This question is important to steel producers, not only for helping customers selecting the most appropriate existing grade for their application, but also for defining the strategic orientation of the further R&amp, D of enhanced electrical steel grades. The notion of steel efficiency is defined and, after describing the FE implementation of iron loss models, a methodology for material optimisation is proposed.

Published

2009