Questo sito utilizza cookie di terze parti per inviarti pubblicità in linea con le tue preferenze. Se vuoi saperne di più clicca QUI 
Chiudendo questo banner, scorrendo questa pagina, cliccando su un link o proseguendo la navigazione in altra maniera, acconsenti all'uso dei cookie. OK

Gurney flaps in sailing, do they help?

L'anteprima di questa tesi è scaricabile in PDF gratuitamente.
Per scaricare il file PDF è necessario essere iscritto a Tesionline.
L'iscrizione non comporta alcun costo. Mostra/Nascondi contenuto.

1 1. On theoretical background of Gurney flap Nomenclature C d = section drag coefficient ; C l = section lift coefficient ; C p = pressure coefficient; L = magnitude of lift (downforce); L/D = lift to drag ratio; Re c = Reynolds number based on chord; V 0 = freestream velocity; b = span of the foil; c = wing chord; f p = principal frequency; Γ = circulation; ρ = density. 1.1 Overview The Gurney flap is a mechanically simple device consisting of a short strip, fitted perpendicular to the pressure surface along the trailing edge of an airfoil; in particular it is immovable and rigidly mounted by bolts or rivets. It’s just a right-angled plate or an L- shaped steel or aluminium extrusion and, when possible, it is made of carbon fibre. Its first aim was to enhance the spoiler’s downforce in motor racing cars for lateral traction required during high-velocity turns; the racing driver and race car manufacturer Daniel Gurney is generally credited with inventing the device that bears his name. The earliest reference to a Gurney flap was made by Liebeck [1] who carefully studied the spoiler of a race car modified by a 1.25% on chord ( %c afterwards) Gurney flap in wind tunnel; he proposed it changes the Kutta-Joukowski condition on airfoil performing in subsonic condition. Regarding the Kutta-Joukowski condition, as known, when an airflow invests an airfoil, a stagnation point S 1 originates and two fluid particles A and B, above and below S 1, travel along their respective surfaces at equal speed; see Fig. 1a. Because the upper surface is longer than the lower one, B arrives at the trailing edge ahead of A; it attempts to go around and meets A in S 2 , the second stagnation point, see Fig. 1b. Kutta-Joukowski condition says that

Anteprima della Tesi di Floriano Bonfigli

Anteprima della tesi: Gurney flaps in sailing, do they help?, Pagina 1

Tesi di Laurea

Facoltà: Ingegneria

Autore: Floriano Bonfigli Contatta »

Composta da 151 pagine.

 

Questa tesi ha raggiunto 1595 click dal 12/07/2004.

 

Consultata integralmente 2 volte.

Disponibile in PDF, la consultazione è esclusivamente in formato digitale.