Aircraft Takeoff Performance in a Changing Climate for Canadian Airports

Zhao, Yijie; Sushama, Laxmi

doi:10.3390/atmos11040418

Cited by 10 publications

(7 citation statements)

References 34 publications

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“…Very low temperature may increase the runway's slipperiness and undermine the planes' braking effectiveness (Nuijten, 2016). Another effect of extreme temperatures is the planes' maximum takeoff weights, which are affected by the changing air density due to humidity and temperature uctuations and are especially in uential for airports with higher altitudes and shorter runways (Zhao, 2020).…”

Section: Introductionmentioning

confidence: 99%

Unraveling Extreme Weather Impacts on Air Transportation and Passenger Delays using Location-based Data

Hsu

Liu

LIU

et al. 2023

Preprint

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Extreme weather poses significant threats to air transportation systems, causing flight rerouting and cancellations, as well as passenger travel delays. With the growing frequency of extreme weather hazards, it is essential to understand the extent to which disruptions in flights and subsequent cancellations impact passenger delays. This study focuses on quantifying the impacts of a recent extreme weather event (2022 Winter Storm Elliott) on the U.S. air transportation system by investigating passenger delays measured based on dwell time at airports using privacy-preserving location-based datasets. The study determines total dwell time and dwell time per anonymized user at airports during the extreme weather event and computes the impact based on changes in values compared to the same period in the previous year. The results show that the storm event caused passengers significant delays, as characterized by a substantial increase in airport dwell time. Factor analysis shows that airports with a greater passenger flow and a greater portion of flights from decentralized airlines aggravated passengers delays during the winter storm. The vulnerability of airports was mainly due to the direct storm exposure, and the influence of network cascading impacts were limited. The findings of this study provide novel insights and quantification of the extent of extreme weather impacts on air transportation at individual airports and national levels. These outcomes could inform airport owners and operators, as well as airlines, about the extent of vulnerability and provide useful information for weather-related risk assessment of air transportation systems.

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Section: Introductionmentioning

confidence: 99%

Unraveling Extreme Weather Impacts on Air Transportation and Passenger Delays using Location-based Data

Hsu

Liu

LIU

et al. 2023

Preprint

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“…The evolution and decay of aircraft wake vortices are closely related to the surrounding atmospheric conditions. Research has shown that wind disturbances can affect the propagation and dispersion of wake vortices [4]. In particular, vertical wind directly impacts the structure, vortex strength, decay rate, and altitude of the vortex core, which subsequently affects wake turbulence separation and the extent of the danger zone.…”

Section: Introductionmentioning

confidence: 99%

“…These models provide valuable insights into wake vortex characteristics, but they may have limitations when capturing all the complex interactions in real-world conditions [5,10]. 4.…”

mentioning

confidence: 99%

Numerical Study of Aircraft Wake Vortex Evolution under the Influence of Vertical Winds

Yuan,

Liu,

et al. 2023

Applied Sciences

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Separating wake vortices is crucial for aircraft landing safety and essential to airport operational efficiency. Vertical wind, as a typical atmospheric condition, plays a significant role, and studying the evolution characteristics of wake vortices under this condition is of paramount importance for developing dynamic wake separation systems. In this study, we employed the SST k-ω turbulence model based on an O-Block structured grid to numerically simulate the simplified wing model. We analyzed the variations in the wake vortex structure and parameters of the Airbus A320 during the near-field phase under different vertical wind directions and speeds. The results indicate that favorable vertical winds cause a “flattening” deformation in the wake vortex. Vertical winds reduce the initial vortex strength, accelerate the rate of vortex decay, and influence the trajectory of the vortex core. Notably, under wind speeds of 1~3 m/s, the decay rate is more significant than under 4 m/s. When vertical wind speeds are substantial, it can lead to irregular motion and interactions within the vortex core, forming secondary vortices.

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“…On airplanes, many phenomena occur. The condition when the plane takes off has a lot of big influences that play a role in the process (Bardera-Mora et al, 2019;Zhao and Sushama, 2020). Like the aerodynamics formula, an airplane requires lower pressure on the upper side and higher pressure on the lower side to fly.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Use of Bio Flap on NACA 4415 with Numerical Methods

Julian,

Siswanto,

Wahyuni

et al. 2023

ASIIMETRIK

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This study was conducted using the Computational Fluid Dynamics (CFD) method using the Reynolds Averaged Navier Stokes (RANS) approach. The type of airfoil used in this study is the asymmetry NACA 4415 airfoil type. In this paper, computational tests were carried out on the airfoil with the addition of bionic flaps on its trailing edge. This study's update tests three variations of the Reynolds number: Re = 106, Re = 5 × 105, and Re = 3 × 105. The airfoil test was carried out at AoA 0°–25°. The addition of bionic flaps causes a decrease in lift performance at low AoA, but at high AoA, it can increase lift performance on airfoils. In addition, adding a bionic flap on the airfoil can delay the occurrence of a stall. At AoA 10°–13°, the Cd of the three variations of the Reynolds number experiences an increase in performance. Then, from this computational test, the resulting Coefficient moment (Cm) is a pitch down because the torque is below zero.

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Aircraft Takeoff Performance in a Changing Climate for Canadian Airports

Cited by 10 publications

References 34 publications

Unraveling Extreme Weather Impacts on Air Transportation and Passenger Delays using Location-based Data

Unraveling Extreme Weather Impacts on Air Transportation and Passenger Delays using Location-based Data

Numerical Study of Aircraft Wake Vortex Evolution under the Influence of Vertical Winds

Analysis of the Use of Bio Flap on NACA 4415 with Numerical Methods

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