Flight Anomaly Detection for Airborne Wind Energy Systems

Volkan Salma; Roland Schmehl

doi:10.1088/1742-6596/1618/3/032021

Flight Anomaly Detection for Airborne Wind Energy Systems

Volkan Salma, Roland Schmehl

Wind Energy

Research output: Contribution to journal › Conference article › Scientific › peer-review

2 Citations (Scopus)

28 Downloads (Pure)

Abstract

Airborne wind energy (AWE) systems use tethered flying devices to harvest wind energy beyond the height range accessible to tower-based turbines. AWE systems can produce the electric energy with a lower cost by operating in high altitudes where the wind regime is more stable and stronger. For the commercialization of AWE, system reliability and safety have become crucially important. To reach required availability and safety levels, we adapted an fault detection, isolation and recovery (FDIR) architecture from space industry. This work focuses on, "flight anomaly detection" layer of the FDIR. Tests verifies that proposed architecture is capable of detecting flight anomalies without generating false alarms.

Original language	English
Article number	032021
Journal	Journal of Physics: Conference Series
Volume	1618
Issue number	3
DOIs	https://doi.org/10.1088/1742-6596/1618/3/032021
Publication status	Published - 2020
Event	Science of Making Torque from Wind 2020, TORQUE 2020 - Online, Virtual, Online, Netherlands Duration: 28 Sept 2020 → 2 Oct 2020

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10.1088/1742-6596/1618/3/032021

Salma_2020_J._Phys. _Conf._Ser._1618_032021Final published version, 1.3 MBLicence: CC BY

Cite this

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title = "Flight Anomaly Detection for Airborne Wind Energy Systems",

abstract = "Airborne wind energy (AWE) systems use tethered flying devices to harvest wind energy beyond the height range accessible to tower-based turbines. AWE systems can produce the electric energy with a lower cost by operating in high altitudes where the wind regime is more stable and stronger. For the commercialization of AWE, system reliability and safety have become crucially important. To reach required availability and safety levels, we adapted an fault detection, isolation and recovery (FDIR) architecture from space industry. This work focuses on, {"}flight anomaly detection{"} layer of the FDIR. Tests verifies that proposed architecture is capable of detecting flight anomalies without generating false alarms.",

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year = "2020",

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language = "English",

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AU - Salma, Volkan

AU - Schmehl, Roland

PY - 2020

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N2 - Airborne wind energy (AWE) systems use tethered flying devices to harvest wind energy beyond the height range accessible to tower-based turbines. AWE systems can produce the electric energy with a lower cost by operating in high altitudes where the wind regime is more stable and stronger. For the commercialization of AWE, system reliability and safety have become crucially important. To reach required availability and safety levels, we adapted an fault detection, isolation and recovery (FDIR) architecture from space industry. This work focuses on, "flight anomaly detection" layer of the FDIR. Tests verifies that proposed architecture is capable of detecting flight anomalies without generating false alarms.

AB - Airborne wind energy (AWE) systems use tethered flying devices to harvest wind energy beyond the height range accessible to tower-based turbines. AWE systems can produce the electric energy with a lower cost by operating in high altitudes where the wind regime is more stable and stronger. For the commercialization of AWE, system reliability and safety have become crucially important. To reach required availability and safety levels, we adapted an fault detection, isolation and recovery (FDIR) architecture from space industry. This work focuses on, "flight anomaly detection" layer of the FDIR. Tests verifies that proposed architecture is capable of detecting flight anomalies without generating false alarms.

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SN - 1742-6588

VL - 1618

JO - Journal of Physics: Conference Series

JF - Journal of Physics: Conference Series

IS - 3

M1 - 032021

T2 - Science of Making Torque from Wind 2020, TORQUE 2020

Y2 - 28 September 2020 through 2 October 2020

ER -

Flight Anomaly Detection for Airborne Wind Energy Systems

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REACH: Resource Efficient Automatic Conversion of High-Altitude Wind

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Flight Anomaly Detection for Airborne Wind Energy Systems

Abstract

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REACH: Resource Efficient Automatic Conversion of High-Altitude Wind

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