Influence of sleeve conductivity on starting performance of high‐speed permanent magnet synchronous starter generator for micro‐gas turbine

Qiu, H.; Zou, Xutian; Sun, Junbin; Cui, Yang; Yi, Ran

doi:10.1049/iet-epa.2020.0354

Cited by 3 publications

(2 citation statements)

References 27 publications

(33 reference statements)

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“…Ultra-high-speed permanent magnet synchronous motors (UHSPMSM) with high power density, high speed and low noise [1][2][3] have been extensively applied to high-precision machining spindles, micro fuel cells, aviation energy storage devices and micro-electromechanical inertial measurement devices in automatic driving systems [4][5][6][7][8]. However, operating at ultra-high frequency leads to many additional losses to motors, which can reduce the motor efficiency, increase the temperature, and affect the multi-physics characteristics of a system [9][10][11]. The copper losses of UHSPMSM include not only the DC losses but also eddy current losses.…”

Section: Introductionmentioning

confidence: 99%

Copper loss analysis and loss separation method in a dynamic process of ultra‐high speed motor with slotless stator

Gao

Wang

et al. 2022

IET Electric Power Appl

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Different from the copper loss of general permanent magnet (PM) motors, the copper loss of ultra-high-speed permanent magnet motors (UHSPMSM) includes DC losses and eddy current losses, which lead to difficulty in analysis. In consideration of the influence of speed, wire diameter and current harmonic loss, DC copper loss and eddy current copper loss are calculated and analysed, respectively, so as to find the main excitation source of copper loss of UHSPMSM. Then, in order to calculate the Litz wire loss in a slotless stator, a Litz wire loss equivalent model is established, which can be used to accurately and quickly calculate the DC loss and eddy current loss of Litz wire independently. Finally, a copper loss separation method is designed to test copper loss of 550,000 rpm UHSPMSM considering the influence of the rotor PM flux at ultra-high speed. The theoretical analysis and experimental results verify each other. In the end, the experimental results verify the effectiveness of theoretical analysis.

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Section: Introductionmentioning

confidence: 99%

Copper loss analysis and loss separation method in a dynamic process of ultra‐high speed motor with slotless stator

Gao

Wang

et al. 2022

IET Electric Power Appl

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“…In this case, there is a problem that the magnet attached to the rotor surface scatters during high-speed rotation. To prevent this, a retaining sleeve is inserted over the magnet [17][18][19][20]. Rotor retaining sleeves are also commonly used to prevent scattering of magnets.…”

mentioning

confidence: 99%

A study on reducing eddy current loss of sleeve and improving torque density using ferrofluid of a surface permanent magnet synchronous motor

Song¹,

Jeong

Kim

et al. 2021

IET Electric Power Appl

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It has advantages such as high power density and miniaturisation when the motor operates at high speed. However, as a side effect, the loss density is much higher than that of a constant speed motor. In addition, a retaining sleeve is inserted in the high‐speed motors to prevent the rotor from scattering. This insertion deteriorates the performance due to the increase of airgap, and eddy current loss occurs in the sleeve. In order to improve these shortcomings, the sleeve is redesigned in this paper. A groove was dug into the retaining sleeve and ferrofluid was injected. Ferrofluid refers to water or oil mixed with ultra‐fine powder. Since the permeability of ferrofluid is greater than that of airgap, it is possible to have high output and high efficiency. Since the material of the sleeve is non‐permeable, the performance is reduced with the same effect as increasing the airgap. However, if a ferrofluid is inserted by digging a groove in the retaining sleeve, the magnetic flux from the magnet flows into the stator through the ferrofluid, which has the same effect as reducing the airgap. Therefore, the torque density increases. Also, the eddy current loss is reduced through the retained sleeve groove. Moreover, a sleeve skew structure was used to further reduce the eddy current loss. In this paper, the mechanical rigidity at the rated speed was also taken into consideration. As a result, eddy current loss was reduced and torque density was improved. This is verified through the final finite element analysis.

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Equivalent Circuit Modeling of an Induction Reaction Sphere for Microspacecraft Attitude Control

et al. 2021

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Influence of sleeve conductivity on starting performance of high‐speed permanent magnet synchronous starter generator for micro‐gas turbine

Cited by 3 publications

References 27 publications

Copper loss analysis and loss separation method in a dynamic process of ultra‐high speed motor with slotless stator

Copper loss analysis and loss separation method in a dynamic process of ultra‐high speed motor with slotless stator

A study on reducing eddy current loss of sleeve and improving torque density using ferrofluid of a surface permanent magnet synchronous motor

Equivalent Circuit Modeling of an Induction Reaction Sphere for Microspacecraft Attitude Control

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