Stability Improvement of Onboard HVdc Grid and Engine Using an Advanced Power Generation Center for the More-Electric Aircraft

Xiaoyu Lang; Tao Yang; Zhen Huang; Cheng Wang; Zhenyu Wang; Serhiy Bozhko; Patrick Wheeler

doi:10.1109/TTE.2021.3095256

Stability Improvement of Onboard HVdc Grid and Engine Using an Advanced Power Generation Center for the More-Electric Aircraft

Xiaoyu Lang, Tao Yang, Zhen Huang, Cheng Wang^*, Zhenyu Wang, Serhiy Bozhko, Patrick Wheeler

^*Corresponding author for this work

University of Nottingham

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

In the high-power settings of engine, such as maximum take-off, more power should be extracted from the high-pressure spool of engine (HPS) than the low-pressure spool of engine (LPS) to avoid the overspeed and potential instability of the HPS. However, as revealed in this article, extracting more power from the HPS will degrade the onboard high-voltage direct current (HVdc) grid stability for the conventional single dc bus power generation center. To address this conflict, in this article, an advanced power generation center (APGC) incorporating an extra back-to-back (BTB) converter is introduced to improve the stability for both engine and HVdc grid. The BTB converter connects the HP power generation channel and the LP channel, providing an additional power flow path between the HP channel and LP channel. A transfer function-based impedance model and a state-space model of the HVdc grid are proposed to study the HVdc grid stability. The analytical findings of the HVdc grid stability and stability improvement using the APGC architecture have been verified through simulation and experimental results.

Original language	English
Pages (from-to)	660-674
Number of pages	15
Journal	IEEE Transactions on Transportation Electrification
Volume	8
Issue number	1
DOIs	https://doi.org/10.1109/TTE.2021.3095256
Publication status	Published - 1 Mar 2022
Externally published	Yes

Keywords

DC power system
more-electric aircraft (MEA)
multiple power sources
power control
power generation system
voltage stability

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10.1109/TTE.2021.3095256

Cite this

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title = "Stability Improvement of Onboard HVdc Grid and Engine Using an Advanced Power Generation Center for the More-Electric Aircraft",

abstract = "In the high-power settings of engine, such as maximum take-off, more power should be extracted from the high-pressure spool of engine (HPS) than the low-pressure spool of engine (LPS) to avoid the overspeed and potential instability of the HPS. However, as revealed in this article, extracting more power from the HPS will degrade the onboard high-voltage direct current (HVdc) grid stability for the conventional single dc bus power generation center. To address this conflict, in this article, an advanced power generation center (APGC) incorporating an extra back-to-back (BTB) converter is introduced to improve the stability for both engine and HVdc grid. The BTB converter connects the HP power generation channel and the LP channel, providing an additional power flow path between the HP channel and LP channel. A transfer function-based impedance model and a state-space model of the HVdc grid are proposed to study the HVdc grid stability. The analytical findings of the HVdc grid stability and stability improvement using the APGC architecture have been verified through simulation and experimental results.",

keywords = "DC power system, more-electric aircraft (MEA), multiple power sources, power control, power generation system, voltage stability",

author = "Xiaoyu Lang and Tao Yang and Zhen Huang and Cheng Wang and Zhenyu Wang and Serhiy Bozhko and Patrick Wheeler",

note = "Publisher Copyright: {\textcopyright} 2015 IEEE.",

year = "2022",

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doi = "10.1109/TTE.2021.3095256",

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AU - Yang, Tao

AU - Huang, Zhen

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AU - Wang, Zhenyu

AU - Bozhko, Serhiy

AU - Wheeler, Patrick

PY - 2022/3/1

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N2 - In the high-power settings of engine, such as maximum take-off, more power should be extracted from the high-pressure spool of engine (HPS) than the low-pressure spool of engine (LPS) to avoid the overspeed and potential instability of the HPS. However, as revealed in this article, extracting more power from the HPS will degrade the onboard high-voltage direct current (HVdc) grid stability for the conventional single dc bus power generation center. To address this conflict, in this article, an advanced power generation center (APGC) incorporating an extra back-to-back (BTB) converter is introduced to improve the stability for both engine and HVdc grid. The BTB converter connects the HP power generation channel and the LP channel, providing an additional power flow path between the HP channel and LP channel. A transfer function-based impedance model and a state-space model of the HVdc grid are proposed to study the HVdc grid stability. The analytical findings of the HVdc grid stability and stability improvement using the APGC architecture have been verified through simulation and experimental results.

AB - In the high-power settings of engine, such as maximum take-off, more power should be extracted from the high-pressure spool of engine (HPS) than the low-pressure spool of engine (LPS) to avoid the overspeed and potential instability of the HPS. However, as revealed in this article, extracting more power from the HPS will degrade the onboard high-voltage direct current (HVdc) grid stability for the conventional single dc bus power generation center. To address this conflict, in this article, an advanced power generation center (APGC) incorporating an extra back-to-back (BTB) converter is introduced to improve the stability for both engine and HVdc grid. The BTB converter connects the HP power generation channel and the LP channel, providing an additional power flow path between the HP channel and LP channel. A transfer function-based impedance model and a state-space model of the HVdc grid are proposed to study the HVdc grid stability. The analytical findings of the HVdc grid stability and stability improvement using the APGC architecture have been verified through simulation and experimental results.

KW - DC power system

KW - more-electric aircraft (MEA)

KW - multiple power sources

KW - power control

KW - power generation system

KW - voltage stability

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Stability Improvement of Onboard HVdc Grid and Engine Using an Advanced Power Generation Center for the More-Electric Aircraft

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Keywords

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