4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft

Dmitry Golovanov; David Gerada; Giacomo Sala; Michele Degano; Andrew Trentin; Peter H. Connor; Zeyuan Xu; Antonino La Rocca; Alessandro Galassini; Luca Tarisciotti; Carol N. Eastwick; Stephen J. Pickering; Pat Wheeler; Jon Clare; Mykhaylo Filipenko; Chris Gerada

doi:10.1109/TTE.2021.3068928

4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft

Dmitry Golovanov, David Gerada, Giacomo Sala, Michele Degano, Andrew Trentin, Peter H. Connor, Zeyuan Xu, Antonino La Rocca, Alessandro Galassini, Luca Tarisciotti, Carol N. Eastwick, Stephen J. Pickering, Pat Wheeler, Jon Clare, Mykhaylo Filipenko, Chris Gerada

Research output: Journal Publication › Article › peer-review

55 Citations (Scopus)

Abstract

This article describes the underpinning research, development, construction, and testing of a 4-MW multithree phase generator designed for a hybrid-electric aircraft propulsion system demonstrator. The aim of the work is to demonstrate gravimetric power densities around 20 kW/kg, as required for multi-MW aircraft propulsion systems. The key design choices, development procedures, and tradeoffs, together with the experimental testing of this electrical machine connected to an active rectifier, are presented. A time-efficient analytical approach to the downselection of various machine configurations, geometrical variables, different active and passive materials, and different thermal management options is first presented. A detailed design approach based on the 3-D finite element analysis (FEA) is then presented for the final design. Reduced power tests are carried out on a full-scale 4-MW machine prototype, validating the proposed design. The experimental results are in good agreement with simulation and show significant progress in the field of high-power-density electrical machines at the targeted power rating.

Original language	English
Pages (from-to)	2952-2964
Number of pages	13
Journal	IEEE Transactions on Transportation Electrification
Volume	7
Issue number	4
DOIs	https://doi.org/10.1109/TTE.2021.3068928
Publication status	Published - 1 Dec 2021
Externally published	Yes

Keywords

Aerospace generator drives
high-power generation systems
high-power high-voltage machines design
hybrid-electric aircraft (HEA)
more-electric aircraft
multiphase motors
variable speed drives

ASJC Scopus subject areas

Automotive Engineering
Transportation
Energy Engineering and Power Technology
Electrical and Electronic Engineering

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10.1109/TTE.2021.3068928

Cite this

Golovanov, D., Gerada, D., Sala, G., Degano, M., Trentin, A., Connor, P. H., Xu, Z., Rocca, A. L., Galassini, A., Tarisciotti, L., Eastwick, C. N., Pickering, S. J., Wheeler, P., Clare, J., Filipenko, M., & Gerada, C. (2021). 4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft. IEEE Transactions on Transportation Electrification, 7(4), 2952-2964. https://doi.org/10.1109/TTE.2021.3068928

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title = "4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft",

abstract = "This article describes the underpinning research, development, construction, and testing of a 4-MW multithree phase generator designed for a hybrid-electric aircraft propulsion system demonstrator. The aim of the work is to demonstrate gravimetric power densities around 20 kW/kg, as required for multi-MW aircraft propulsion systems. The key design choices, development procedures, and tradeoffs, together with the experimental testing of this electrical machine connected to an active rectifier, are presented. A time-efficient analytical approach to the downselection of various machine configurations, geometrical variables, different active and passive materials, and different thermal management options is first presented. A detailed design approach based on the 3-D finite element analysis (FEA) is then presented for the final design. Reduced power tests are carried out on a full-scale 4-MW machine prototype, validating the proposed design. The experimental results are in good agreement with simulation and show significant progress in the field of high-power-density electrical machines at the targeted power rating.",

keywords = "Aerospace generator drives, high-power generation systems, high-power high-voltage machines design, hybrid-electric aircraft (HEA), more-electric aircraft, multiphase motors, variable speed drives",

author = "Dmitry Golovanov and David Gerada and Giacomo Sala and Michele Degano and Andrew Trentin and Connor, {Peter H.} and Zeyuan Xu and Rocca, {Antonino La} and Alessandro Galassini and Luca Tarisciotti and Eastwick, {Carol N.} and Pickering, {Stephen J.} and Pat Wheeler and Jon Clare and Mykhaylo Filipenko and Chris Gerada",

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doi = "10.1109/TTE.2021.3068928",

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Golovanov, D, Gerada, D, Sala, G, Degano, M, Trentin, A, Connor, PH, Xu, Z, Rocca, AL, Galassini, A, Tarisciotti, L, Eastwick, CN, Pickering, SJ, Wheeler, P, Clare, J, Filipenko, M & Gerada, C 2021, '4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft', IEEE Transactions on Transportation Electrification, vol. 7, no. 4, pp. 2952-2964. https://doi.org/10.1109/TTE.2021.3068928

TY - JOUR

T1 - 4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft

AU - Golovanov, Dmitry

AU - Gerada, David

AU - Sala, Giacomo

AU - Degano, Michele

AU - Trentin, Andrew

AU - Connor, Peter H.

AU - Xu, Zeyuan

AU - Rocca, Antonino La

AU - Galassini, Alessandro

AU - Tarisciotti, Luca

AU - Eastwick, Carol N.

AU - Pickering, Stephen J.

AU - Wheeler, Pat

AU - Clare, Jon

AU - Filipenko, Mykhaylo

AU - Gerada, Chris

PY - 2021/12/1

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AB - This article describes the underpinning research, development, construction, and testing of a 4-MW multithree phase generator designed for a hybrid-electric aircraft propulsion system demonstrator. The aim of the work is to demonstrate gravimetric power densities around 20 kW/kg, as required for multi-MW aircraft propulsion systems. The key design choices, development procedures, and tradeoffs, together with the experimental testing of this electrical machine connected to an active rectifier, are presented. A time-efficient analytical approach to the downselection of various machine configurations, geometrical variables, different active and passive materials, and different thermal management options is first presented. A detailed design approach based on the 3-D finite element analysis (FEA) is then presented for the final design. Reduced power tests are carried out on a full-scale 4-MW machine prototype, validating the proposed design. The experimental results are in good agreement with simulation and show significant progress in the field of high-power-density electrical machines at the targeted power rating.

KW - Aerospace generator drives

KW - high-power generation systems

KW - high-power high-voltage machines design

KW - hybrid-electric aircraft (HEA)

KW - more-electric aircraft

KW - multiphase motors

KW - variable speed drives

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JF - IEEE Transactions on Transportation Electrification

IS - 4

ER -

4-MW Class High-Power-Density Generator for Future Hybrid-Electric Aircraft

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Keywords

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