The Design of the Outer-Rotor Brushless DC Motor and an Investigation of Motor Axial-Length-to-Pole-Pitch Ratio

Tosun, Ozturk; Serteller, N. Füsun Oyman

doi:10.3390/su141912743

Cited by 6 publications

(5 citation statements)

References 28 publications

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“…For this analysis, different geometric ratios related with the output power and the power-density can be used, such as the L/D factor, defined as the ratio of the stack length and the air gap diameter [67], or the L/τ factor, defined as the ratio of the stack length and the pole-pitch [68]. For this study, the L/D factor is chosen and a value of 1.75 has been set as the upper limit, which is a widespread practice in the manufacturing of electric machines to avoid mechanical issues regarding the shaft, the bearings, and the housing.…”

Section: Resultsmentioning

confidence: 99%

Design of a HTS 2 MW Electric Motor for Single-Aisle Regional Aircraft

Alvarez,

Satrústegui,

Scheifler

et al. 2023

IEEE Access

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This paper presents the design of a 2 MW superconducting electric machine capable of replacing a conventional regional aircraft turbine. The main objective of this work is to advance in the path towards the more-electric aircraft, by incorporating and assessing in the same design technologies such as a superconducting rotor and its cooling by means of helium at cryogenic temperatures, the skewed armature winding or the oil-flooded cooling of the stator, to obtain high specific power density and efficiency values. Although the use of these technologies is well known in the literature, no work is found to implement all of them simultaneously, which poses great challenges both for their subsequent manufacture and later performance. After showing and justifying each element of the design of the electric machine, the electromagnetic performance of the motor and of the superconducting coils is assessed, it is thermally evaluated so that it does not exceed the strict temperature limits and a mechanical analysis of the elements of the motor is also carried out. The main finding of this work is the validation of the proposed model, and that, even though the designed engine is feasible at the proposed power level, the specific power density and efficiency values would improve in the case of upscaling the engine for implementation in larger aircraft.INDEX TERMS Aircraft propulsion, electric machine, high-power, high-temperature superconductor, regional aircraft.

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Section: Resultsmentioning

confidence: 99%

Design of a HTS 2 MW Electric Motor for Single-Aisle Regional Aircraft

Alvarez,

Satrústegui,

Scheifler

et al. 2023

IEEE Access

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“…High-power-density motors prioritize lightweight structures and high electromagnetic loads, optimizing power density through strategic rotor and stator configurations. Magnetic circuits design boost efficiency and reduce cogging torque [56,57]. Additionally, enhancements in no-load back EMF and phase current improve motor output power density.…”

Section: Design Of Bldc Motormentioning

confidence: 99%

Optimal Rotor Design and Analysis of Energy-Efficient Brushless DC Motor-Driven Centrifugal Monoset Pump for Agriculture Applications

Antony,

Komarasamy,

Rajamanickam

et al. 2024

Energies

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The agricultural sector emphasizes sustainable development and energy efficiency, particularly in optimizing water pumping systems for irrigation. Brushless DC (BLDC) motors are the preferred prime mover over induction motors due to their high efficiency in such applications. This article details the rotor design and analysis of an energy-efficient BLDC motor with specifications of 1 hp, 3000 rpm, and 48 V, specifically tailored for a centrifugal monoset pump for irrigation. The focus lies in achieving optimal energy efficiency through grey wolf optimization (GWO) algorithm in the rotor design to determine optimal dimensions of the Neodymium Iron Boron (NdFeB) magnet as well as its grade. The finite element method analysis software, MagNet, is used to model and analyze the BLDC motor. The motor parameters, such as speed, torque, flux functions, temperature, and efficiency, are analyzed. For performance comparison, the same model with different magnet models is also analyzed. Validation via 3D finite element analysis highlights improvements in magnet flux linkage, stator tooth flux density, and rotor inertia with increased magnet thickness. Simulation results affirm the consistent performance of the designed BLDC motor, preferably when efficiency is increased. This efficiency and the constant speed lead to an improvement in the overall conversion efficiency of 7% within its operating range, affirming that the motor pump system is energy-efficient.

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“…Table 6 shows the Axial Flux and Hub BLDC motor's constant parameters. The variable parameters selected in the GA for the axial flux and hub BLDC motors are represented by equations ( 4) to (9). Equation ( 4) describes the electromechanical power of both motors.…”

Section: Optimization Of Efficiency To Axial Flux Bldc Motor and Hub ...mentioning

confidence: 99%

“…In addition, features such as the winding method, pole type, and magnet type are also examined during the design phase [8]. The rotor design and optimization of the 10 KW BLDC motor with the desired torque and speed have been carried out in [9], considering the effect of rotor design on BLDC motor performance is effective on torque, speed, and efficiency. To optimize the two-wheel electric motor in terms of required torque, speed, size, mass, and cost, the effect of the air gap length on the efficiency was investigated between the determined mere limited values.…”

Section: Introductionmentioning

confidence: 99%

The Design, Optimization, and Experimental Study of Hub and Axial Flux BLDC Motor Under Operating Conditions For Light Electric Vehicles

Toker¹,

Tosun²,

Serteller³

et al. 2023

Adv. sci. technol. eng. syst. j.

Self Cite

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In this study, we conducted an experimental study and efficiency optimization of the outer rotor (hub) BLDC (brushless direct current) motor and axial BLDC motor for light electric vehicles. Both motors were investigated in the simulation environment and experimentally. The axial flux BLDC motor had a rated power of 10 KW, and a rated speed of 4550 rpm, while the outer rotor (hub) BLDC motor had a rated power of 1 KW and a rated speed of 300 rpm. The speed, efficiency, torque, and weight values of both motors were examined comparatively. The torque/volume values of the hub motor and axial flux motor were used as references for analysis. The hub motor and axial flux motors, with equal volume values, were simulated using ANSYS Electronics Desktop software. The simulation data were also compared with experimental studies. To optimize these motors using a genetic algorithm (GA), lower and upper limit values were determined for various parameters such as the outer and inner diameter of the stator, the outer diameter of the rotor, air gap length, slot height, axial length, air gap flux density, magnet thickness, and tooth width in the hub motor. Similarly, in the axial flux motor, parameters such as the outer and inner diameter of the stator, air gap length, slot height, air gap flux density, magnet thickness, tooth width, stator length, and rotor length were optimized using the GA method. The application of GA optimization has led to a 1.91% increase in the hub motor efficiency and a 3.45% increase in the axial motor efficiency.

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The Design of the Outer-Rotor Brushless DC Motor and an Investigation of Motor Axial-Length-to-Pole-Pitch Ratio

Cited by 6 publications

References 28 publications

Design of a HTS 2 MW Electric Motor for Single-Aisle Regional Aircraft

Design of a HTS 2 MW Electric Motor for Single-Aisle Regional Aircraft

Optimal Rotor Design and Analysis of Energy-Efficient Brushless DC Motor-Driven Centrifugal Monoset Pump for Agriculture Applications

The Design, Optimization, and Experimental Study of Hub and Axial Flux BLDC Motor Under Operating Conditions For Light Electric Vehicles

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