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References (12)
-
M. Singh, K. Dhanalakshmi, S. Chakrabartty (2007)
Navier-Stokes analysis of airfoils with Gurney flapJournal of Aircraft, 44
-
S. Chakrabartty (1990)
A finite volume nodal point scheme for solving two dimensional Navier-Stokes equationsActa Mechanica, 84
-
S. Chakrabartty, K. Dhanalakshmi, Ramesh (2003)
Navier-stokes analysis of GA(W)-2 aerofoil with deflected flap and redesign of Hansa flap for better performance -
D.M. Somers
Design and Experimental Results for a Natural‐Laminar Airfoil for General Aviation Applications -
D. Somers (1981)
Design and experimental results for a flapped natural-laminar-flow airfoil for general aviation applications -
B. Baldwin, H. Lomax (1978)
Thin-layer approximation and algebraic model for separated turbulent flows -
S.K. Chakrabartty, K. Dhanalakshmi, J.S. Mathur
Navier‐Stokes analysis of flow through two‐dimensional cascades -
S. Chakrabartty, K. Dhanalakshmi (1996)
Navier-Stokes analysis of Korn aerofoilActa Mechanica, 118
-
Russell Cummings, William Mason, S. Morton, D. McDaniel (2015)
Introduction to Computational Fluid Dynamics -
J. Cahill, S. Racisz (1948)
Wind-tunnel investigation of seven thin NACA airfoil sections to determine optimum double-slotted-flap configurations -
A. Jameson, W. Schmidt, Eli Turkel (1981)
Numerical solution of the Euler equations by finite volume methods using Runge Kutta time stepping schemes -
S.K. Chakrabartty, K. Dhanalakshmi, V. Ramesh
Navier‐Stokes analysis and design of aerofoil‐flap configurations for low speed aircraft
- Publisher
- Emerald Publishing
- Copyright
- Copyright © 2011 Emerald Group Publishing Limited. All rights reserved.
- ISSN
- 0961-5539
- DOI
- 10.1108/09615531111177778
- Publisher site
- See Article on Publisher Site
Abstract
Purpose – Air connectivity network is an important part of the overall connectivity network of any country. This becomes even more crucial for the interior regions, which have no access to sea routes and have inadequate road and rail connectivity. In India there is uniform distribution of airports throughout the country but only a few of them are currently used because of poor infrastructure availability at these airports. Any aircraft operating from these airports, having minimal infrastructure, need to have efficient high‐lift systems for short takeoff and landing ability as one of the key requirements. The purpose of this paper is look at the performance of a new high‐lift airfoil configuration for application to a general transport aircraft. Design/methodology/approach – The present study deals with two‐dimensional analyses of a high‐lift system for general transport aircraft. The JUMBO2D, a multi‐block structured viscous code has been used to make preliminary analysis of the proposed high‐lift system. The configuration consists of three elements, namely, the main airfoil with nose droop, a vane and a flap. Findings – In the present work the code has been revalidated by computing for NLF (1) 0416 airfoil (clean) and NACA 1410 airfoil with double‐slotted flap. The computed results compare very well with the experimental data. The proposed high‐lift configuration of general transport aircraft has then been analyzed in detail for both takeoff and landing conditions with and without nose droop. The effect of gap between main element and vane on the aerodynamic performance has also been investigated. Originality/value – This computational study looks at the performance of a new high‐lift airfoil configuration for application to a general transport aircraft.
Journal
International Journal of Numerical Methods for Heat and Fluid Flow – Emerald Publishing
Published: Nov 1, 2011
Keywords: India; Aerospace industry; Transport aircraft; Airfoils; Flow; High lift system