Active magnetic bearings for energy storage systems for combat vehicles

Pichot, M. A.; Kajs, J.P.; Murphy, B.R.; Ouroua, A.; Rech, B.; Hayes, Richard; Beno, J.H.; Buckner, Gregory D.; Palazzolo, Alan

doi:10.1109/20.911846

Cited by 58 publications

(22 citation statements)

References 2 publications

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“…With these design choices, combined with the amount of energy to be stored in the flywheel, the following approach can be used to dimension the machine. The homopolar flux density B f 0 is calculated from B max andB f 1 for a square rotor in (8). The minimum airgap flux density (9), the required field winding ampereturns (10), the axial length needed for the field winding (11), and the maximum airgap length (12) can then be calculated.…”

Section: Ac Homopolar Motor Sizingmentioning

confidence: 99%

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Outer-rotor ac homopolar motors for flywheel energy storage

Severson¹,

Nilssen

Undeland

et al. 2014

7th IET International Conference on Power Electronics, Machines and Drives (PEMD 2014)

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Flywheel energy storage technology has been successfully commercialized for applications requiring high power, high cycle-life, and short storage intervals. High idling losses have prevented the use of flywheel technology in applications that require longer storage intervals, such as grid-based, load-following energy storage. This paper proposes the use of an outer-rotor ac homopolar motor to significantly decrease idling losses, increase energy density, and decrease cost. Motor sizing equations, a comparison to the typically-used permanent magnet motor, and 3D finite element analysis of an example design are presented. It is shown that for high-performance flywheel designs, the ac homopolar motor can have a torque density comparable to that of a permanent magnet motor.

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Section: Ac Homopolar Motor Sizingmentioning

confidence: 99%

“…Previous work has concluded that bearing loss can be substantially reduced by using carefully designed magnetic bearings [8] and that frictional windage loss can be nearly eliminated by using a vacuum of approximately 1mTorr [9]. The magnetic losses associated with the motor depend on the type of motor chosen.…”

Section: Introductionmentioning

confidence: 99%

Outer-rotor ac homopolar motors for flywheel energy storage

Severson¹,

Nilssen

Undeland

et al. 2014

7th IET International Conference on Power Electronics, Machines and Drives (PEMD 2014)

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“…Due to the advantages of high speed, no friction, high precision and long service life [1][2][3][4][5], magnetic bearings play an important role in electric drives working under high speed, vacuum and clean conditions. They have been applied in rotating machinery applications like motorized spindles, agile satellites and flywheel systems [6][7][8][9][10][11][12]. The most common configurations for radial magnetic bearings are eight-pole type and four-pole type [13].…”

Section: Introductionmentioning

confidence: 99%

Modeling for Three-Pole Radial Hybrid Magnetic Bearing Considering Edge Effect

Zhu¹,

Shuling²,

Jv³

2016

Energies

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Abstract:In order to overcome the shortcoming of magnetic bearings whereby general mathematical models of the radial suspension forces cannot be accurately established, a mathematical model considering the edge effect is set up. The configuration, operation principle and flux distribution features of a three-pole radial hybrid magnetic bearing (HMB) are analyzed in this paper. The magnetic field division method is employed to calculate the permeance of different regions around the end portion of poles. The total permeance of a single pole is composed of the permeance of the regions. Then, an accurate mathematical model of the radial suspension forces considering the edge effect is deduced by the equivalent magnetic circuit method. From the modeling procedures, it can be seen that the edge effect calculation is only related to the configuration and parameters of the magnetic poles, and is isolated with the other configurations and parameters of the three-pole radial HMB, therefore, the mathematical model is proved universal for calculating different suspension forces of hybrid magnetic bearings. A finite element analysis (FEA) simulation and three-pole radial HMB experiments are performed. The error between the theoretical calculation values and the FEA simulation values of the suspension forces is less than 5%, and the error between theoretical calculation value and experimental value of suspension forces is less than 7%. The comparison between the results of the theoretical calculation, FEA simulation and experiments has verified that the established mathematical model can accurately calculate the suspension forces.

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“…Along with vertical lifting capability, the lateral stiffness affects dynamic performance and may limit operation. For applications such as flywheel energy storage, operation above critical speed may be required to meet energy storage requirements [4]. The low lateral stiffness and damping capabilities of HTSC bearings have been shown to impede operations above critical speeds [5].…”

Section: Introductionmentioning

confidence: 99%

Lumped-Parameter Model to Describe Dynamic Translational Interaction for High-Temperature Superconducting Bearings

Hearn

Pratap

Chen

et al. 2014

IEEE Trans. Appl. Supercond.

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Abstract-This paper discusses a lumped parameter modeling methodology to describe the dynamic vertical and translational force interaction between a bulk superconductor and levitated permanent magnet. The model is formulated to be easily incorporated into larger rigid body system models to aid design of superconducting bearings for flywheel energy storage applications. The proposed modeling technique will significantly reduce the computational expense in order to shorten the design cycle process. The validity of the proposed lumped parameter model is demonstrated by comparing results from Finite Element Method analysis and measurements of the force displacement interaction between a permanent magnet and bulk high temperature superconductor.

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Active magnetic bearings for energy storage systems for combat vehicles

Cited by 58 publications

References 2 publications

Outer-rotor ac homopolar motors for flywheel energy storage

Outer-rotor ac homopolar motors for flywheel energy storage

Modeling for Three-Pole Radial Hybrid Magnetic Bearing Considering Edge Effect

Lumped-Parameter Model to Describe Dynamic Translational Interaction for High-Temperature Superconducting Bearings

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