Monte Carlo Analysis of Circulating Currents in Random-Wound Electrical Machines

Lehikoinen, Antti; Chiodetto, Nicola; Lantto, Erkki; Arkkio, Antero; Belahcen, Anouar

doi:10.1109/tmag.2016.2535332

Cited by 35 publications

(35 citation statements)

References 34 publications

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“…As Fig. 6(a) reveals, the largest losses can be found near the borders between winding turns, due to the circulating current effects [9]. The error in losses -compared to the reference solution -has been plotted in Fig.…”

Section: B Single Smooth Slotmentioning

confidence: 98%

“…However, these studies have mostly focused on purely series-connected coils, or idealized Litz wires. By contrast, the scarce research on circulating currents has mostly ignored the proximity effects [9]- [12]. Some brute-force and analytical approaches have also been studied, typically with problems with relatively few conductors [13]- [21].…”

Section: Introductionmentioning

confidence: 99%

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Reduced Basis Finite Element Modeling of Electrical Machines with Multiconductor Windings

Lehikoinen

Arkkio

Belahcen

2017

IEEE Trans. on Ind. Applicat.

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Abstract-Finite element analysis of electrical machines with multi-conductor windings can be computationally costly. This paper proposes a solution to this problem, using a reduced basis approach. The field-circuit problem is first solved in a single slot only, with a set of different boundary conditions. These pre-computed solutions are then used as shape functions to approximate the solution in all slots of the full problem. A polynomial interpolation method is also proposed for coupling the slot domains with the rest of the geometry, even if the geometries or meshes do not fully conform on the boundary.The method is evaluated on several test problems. According to the simulations, accurate solutions are obtained. Furthermore, a speed-up factor of 30 is observed when analysing a six-slot phase belt of a high-speed induction machine.Index Terms-Finite element analysis, eddy currents, proximity effects, reduced order systems.

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Section: B Single Smooth Slotmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Reduced Basis Finite Element Modeling of Electrical Machines with Multiconductor Windings

Lehikoinen

Arkkio

Belahcen

2017

IEEE Trans. on Ind. Applicat.

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“…This phenomena is strictly related to the real positions of the strands inside the slot and becomes important when random wound winding are adopted as in this case study. Different works have addressed the evaluation of circulating currents both analytically (essentially based on circuital approach) [31] and FE study [32]. In this work, a FE simulation considering the worst case scenario in terms of conductors distribution within the slot has been carried out in order to estimate the resistance factor (k ac/dc = R ac /R dc ) as function of the frequency.…”

Section: B Electric Machine Fe Simulationsmentioning

confidence: 99%

High-Speed Electric Drives: A Step Towards System Design

Savi

Barater

Nardo

et al. 2020

IEEE Open J. Ind. Electron. Soc.

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Electric drives applications have been worldwide adopted for the transportation electrification. An electric drive system is constituted by two main components: the power electronics converter and the electrical machine. Traditionally the design workflow consisted in the separate realization of these two parts, by different teams or even organizations. This requires strong assumptions regarding operating conditions and may lead to actual performance at system level far from the one expected. In this article, a unified design methodology of the two subsystems is presented considering the true operating conditions, allowing a more accurate assessment of power losses at system level and identifying the influence of the converter design choices on the electric machine performance. As a case study, this article presents a comparative analysis among three different converter topologies designed to drive a 8.5 kW-120 krpm surface PMSM. The study aims at comparing the considered systems in terms of overall efficiency, losses distribution and system complexity. At first converters are simulated in Matlab-Simulink to estimate the losses and the current waveforms, that are then used in the Finite Element model of the electrical machine to estimate the loss components in a real scenario. The models developed are then validated by means of experimental measurements. This article highlights the new understanding that can be gained by considering the interactions between subsystems , allowing a more conscious choice of the converter topology to achieve optimal overall performance.

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“…or ignored the proximity effects altogether [10]- [19]. Some analytical methods have also been studied, along with bruteforce approaches [20]- [23].…”

Section: Introductionmentioning

confidence: 99%

Domain Decomposition Approach for Efficient Time-Domain Finite-Element Computation of Winding Losses in Electrical Machines

et al. 2017

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Finite element analysis of winding losses in electrical machines can be computationally uneconomical. Computationally lighter methods often place restrictions on the winding configuration or have been used for time-harmonic problems only. This paper proposes a domain decomposition type approach for solving this problem. The slots of the machine are modelled by their impulse response functions and coupled together with the rest of the problem. The method places no restrictions on the winding and naturally includes all resistive AC loss components. The method is then evaluated on a 500 kW induction motor. According to the simulations, the method yields precise results 70-100 faster compared to the established finite element approach.Index Terms-Finite element analysis, eddy currents, proximity effects, reduced order systems.

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Monte Carlo Analysis of Circulating Currents in Random-Wound Electrical Machines

Cited by 35 publications

References 34 publications

Reduced Basis Finite Element Modeling of Electrical Machines with Multiconductor Windings

Reduced Basis Finite Element Modeling of Electrical Machines with Multiconductor Windings

High-Speed Electric Drives: A Step Towards System Design

Domain Decomposition Approach for Efficient Time-Domain Finite-Element Computation of Winding Losses in Electrical Machines

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