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Your search keyword '"De Visscher, I."' showing total 14 results
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14 results on '"De Visscher, I."'

1. Towards physics-based operational modeling of the unsteady wind turbine response to atmospheric and wake-induced turbulence

Author

UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, Marichal, Y, De Visscher, I, Chatelain, Philippe, Winckelmans, Grégoire, Wake Conference 2017, UCL - SST/IMMC/TFL - Thermodynamics and fluid mechanics, Marichal, Y, De Visscher, I, Chatelain, Philippe, Winckelmans, Grégoire, and Wake Conference 2017

Abstract

The objective of the present work is to develop a tool able to predict, in a computationally affordable way, the unsteady wind turbine power production and loads as well as its wake dynamics, as a function of the turbine dynamics and incoming wind conditions. Based on the lessons learned from a previous study about the characterization of the unsteady wake dynamics, the framework for an operational wake model is presented. The approach relies on an underlying vorticity-based skeleton consisting of different components, such as a regularized Vortex Sheet Tube (VST) and Vortex Dipole Line (VDL). Physically based evolution equations, accounting for the various flow phenomena occurring in the wake (such as advection, turbulent diffusion/core spreading, source/sink terms, etc.), are then derived. Once calibrated, the wake model is shown to be in good agreement with results of high-fidelity Large Eddy Simulations (LES) obtained using an Immersed Lifting Line-enabled Vortex Particle-Mesh method.

Published
2017

6. Crosswind Thresholds Supporting Wake-Vortex-Free Corridors for Departing Aircraft

Author

Dengler, Klaus, Holzäpfel, Frank, Gerz, Thomas, Wiegele, Andreas, De Visscher, I., Winckelmans, G., Bricteux, L., Fischer, H., and Konopka, J.

Subjects
Crosswind threshold, CREDOS, departure corridor, wake-vortex drift, aircraft separation, Wolkenphysik und Verkehrsmeteorologie
Abstract

During two field measurement campaigns aircraft wake vortex trajectory and wind measurement data have been collected at Frankfurt airport. Three different approaches to analyse the data have been used in order to estimate crosswind threshold values supporting vortex-free corridors for departing aircraft. Although several competing effects as wake vortex transport in and out of ground effect, temporal and spatial wind variability, and the spreading of aircraft trajectories after take-off complicate the analyses, all three approaches lead to similar crosswind thresholds. Employing standard instrumentation at 10 m height a minimum crosswind threshold of 3.5 – 4.6 ms-1 has been identified to clear a safety corridor of 150 m width from wake vortices with a 95% probability within 60 seconds. Alternative estimations of crosswind thresholds employing different instrumentation and different height ranges are reported. Crosswind thresholds can be reduced if the wind is measured close to the air mass in which the vortices evolve. A definite crosswind threshold for operational use cannot be deduced solely from this study since critical factors like risk and safety assessment have not yet been taken into account.

Published
2012

13. Crosswind thresholds supporting wake-vortex-free corridors for departing aircraft.

Author

Dengler, K., Holzäpfel, F., Gerz, T., Wiegele, A., De Visscher, I., Winckelmans, G., Bricteux, L., Fischer, H., and Konopka, J.

Subjects
VORTEX motion, AIRPLANE takeoff, WIND measurement, AIR masses, GROUND-cushion phenomenon, AIRPORTS
Abstract

During two field measurement campaigns aircraft wake vortex trajectory and wind measurement data have been collected at Frankfurt airport. Three different approaches have been used to analyse the data in order to estimate crosswind threshold values supporting vortex-free corridors for departing aircraft. Although several competing effects such as wake vortex transport in and out of ground effect, temporal and spatial wind variability, and the spreading of aircraft trajectories after take-off, complicate the analyses, all three approaches lead to similar crosswind thresholds. Employing standard instrumentation at 10 m, a minimum crosswind threshold of 3.5-4.6 m s−1 has been identified to clear a safety corridor of 150 m width from wake vortices with a 95% probability within 60 s. Alternative estimations of crosswind thresholds employing different instrumentation and different height ranges are reported. Crosswind thresholds can be reduced if the wind is measured close to the air mass in which the vortices evolve. A definite crosswind threshold for operational use cannot be deduced solely from this study since critical factors such as risk and safety assessment have not yet been taken into account. Copyright © 2011 Royal Meteorological Society [ABSTRACT FROM AUTHOR]

Published
2012
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14. Reducing flight upset risk and startle response: A study of the wake vortex alert with licensed commercial pilots.

Author

Borghini G, Ronca V, Giorgi A, Aricò P, Di Flumeri G, Capotorto R, Rooseleer F, Kirwan B, De Visscher I, Goman M, Pugh J, Abramov N, Granger G, Alarcon DPM, Humm E, Pozzi S, and Babiloni F

Subjects
Humans, Male, Adult, Accidents, Aviation prevention & control, Female, Safety, Young Adult, Pilots, Aviation, Aircraft, Reflex, Startle physiology
Abstract

The study aimed at investigating the impact of an innovative Wake Vortex Alert (WVA) avionics on pilots' operation and mental states, intending to improve aviation safety by mitigating the risks associated with wake vortex encounters (WVEs). Wake vortices, generated by jet aircraft, pose a significant hazard to trailing or crossing aircrafts. Despite existing separation rules, incidents involving WVEs continue to occur, especially affecting smaller aircrafts like business jets, resulting in aircraft upsets and occasional cabin injuries. To address these challenges, the study focused on developing and validating an alert system that can be presented to air traffic controllers, enabling them to warn flight crews. This empowers the flight crews to either avoid the wake vortex or secure the cabin to prevent injuries. The research employed a multidimensional approach including an analysis of human performance and human factors (HF) issues to determine the potential impact of the alert on pilots' roles, tasks, and mental states. It also utilizes Human Assurance Levels (HALs) to evaluate the necessary human factors support based on the safety criticality of the new system. Realistic flight simulations were conducted to collect data of pilots' behavioural, subjective and neurophysiological responses during WVEs. The data allowed for an objective evaluation of the WVA impact on pilots' operation, behaviour and mental states (mental workload, stress levels and arousal). In particular, the results highlighted the effectiveness of the alert system in facilitating pilots' preparation, awareness and crew resource management (CRM). The results also highlighted the importance of avionics able to enhance aviation safety and reducing risks associated with wake vortex encounters. In particular, we demonstrated how providing timely information and improving situational awareness, the WVA will minimize the occurrence of WVEs and contribute to safer aviation operations., Competing Interests: Declaration of Competing Interest Declarations of interest: none, (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2024
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