Drag

Question 1

Profile Drag

Answer 1

Combination of Skin Drag and Form Drag

Question 2

Skin Drag

Answer 2

Surface roughness of the surface of aerofoil skin
Traps and slows air molecules in boundary layer
Direct result from friction in boundary layer

Question 3

Form Drag

Answer 3

Pressure differences
Static pressure to rear is lower so creates force rearward

Air speed
Frontal Area
Shape/Streamline
Surface

Question 4

Boundary Layer

Answer 4

All skin friction occurs within
Molecules at surface at a stand still
Layers above slowed down until outside boundary lower
Greater viscous air = greater shearing force

Laminar/Turbulent flow within

Question 5

Laminar Boundary Layer

Answer 5

Few mm deep
Shallow velocity gradient
Not much friction/less heat/less energy loss

Question 6

Turbulent Boundary Layer

Answer 6

Thick measured in cm - more mass = more turbulent = more skin friction than laminar
Flow in all directions
High energy exchange between layers
Steep velocity gradient
Greater K resist separation compared to laminar

Question 7

Transition Point

Answer 7

Point of change from laminar to turbulent flow
Laminar flow when viscous force more dominant
Turbulent flow when high inertial forces dominant

Question 8

Factors determining transition point

Answer 8

Speed:
- High speed = greater laminar flow - transition point further back
- Low speed - Greater turbulent flow - transition point closer to LE

Surface Roughness:
- More friction reduce flow of energy laminar to turbulent earlier

Question 9

Adverse Pressure Gradient

Answer 9

High static pressure moves from lower surface to upper surface of wing
Causes separation at boundary layer
Reduction in surface area therefore drop in lift force

Question 10

VMD Means

Answer 10

Minimum drag speed best lift/drag ratio
Induced = parasite
Thrust equal drag to maintain stable constant speed in lvl flight

Question 11

Speed Stability

Answer 11

Natural tendency to return to original speed

Drop in say speed would result in a reduction drag force so natural acceleration back up to the set speed

Speeds greater than VMD

Question 12

Speed Unstable

Answer 12

Back of drag curve - natural tendency to diverge
Speed increases drag increases
Danger of stalling

Question 13

Speed Netural

Answer 13

No tendency to return or diverge
Located around VMD

Question 14

Effect of Alt on Drag Curve

Answer 14

IAS no difference (density not taken into account)
TAS whole drag curve moves right as altitude increase

Question 15

Effect of weight on the drag curve

Answer 15

Increase in weight moves drag curve up and right
Higher induced drag for mass (induced drag curve moves up and right)

Faster VMD/stall speed increases

Question 16

Effect on configuration on drag curve (flaps/landing gear etc)

Answer 16

Increase parasite drag
Induced drag constant
Total drag curve moves up and left

Slower VMD

Question 17

Parasite drag + CL

Answer 17

No variation as CL increases parasite drag is the same

Question 18

Induced drag with CL

Answer 18

Coefficient of induced drag varies with the square of coefficient of lift

CDI = CL2/Aspect ratio

Question 19

Drag Polar Curve

Answer 19

Total Drag (Induced + Parasite) against coefficient of list

Cl/Dmax occurs at Vmd

More efficient wing steeper cl for cd
Flaps move up and to the right (increase parasite and increase in clmax)

Question 20

Factors impacting induced drag

Answer 20

Speed - Slower more (Double speed quarter of drag)
Mass - Heavier more drag (More Cl/More induced AOA)
Manoeuvre - More cl more di
Aspect ratio - High aspect less vortices/less AOA so less induced drag

CDI = Cl2/AR

Question 21

Interference Drag

Answer 21

Occurs in 3D flow
Around structural joints (Wings and fuselage)
Use of filets to smooth joints and reduce

FILLET OF FISH

Question 22

Value of induced drag in S+L varies with

Answer 22

1/V2

Question 23

Effects of fitting tip tanks on induced drag and parasite drag

Answer 23

Parasite drag will increase as surface area has increased more friction

Induced drag will decrease as tanks prevent flow around the tip of wing to decrease the vortices

Question 24

How do CDI vary with speed

Answer 24

If speed drops by a half (1/4) therefore CDI will be 1/16

Question 25

VMD in jet and prop

Answer 25

Jet = 1.6VS
Prop = 1.3VS

Question 26

Aerofoil polar is a graph showing relation between

Answer 26

Lift coefficient and drag coefficient

Question 27

Increasing altitude on vmd as a TAS

Answer 27

Density reduced therefore TAs increase meaning higher Vmd as more drag from skin friction

Question 28

Polar Drag Curve - Point A on the graph

Answer 28

At the bottom below the tangent line
Best rate of climb speed Vy
Best range (jet)

Question 29

Polar Drag Curve - Point B - Tangent line

Answer 29

VMD -
Best prop range speed
Best glide range speed
Best L/D ratio
Best endurance (jet)
Best angle of climb (VX)

Question 30

Polar Drag Curve - Just past the tangent line (between VMD and VS) - VMP

Answer 30

Best rate of climb Vy
Value for minimum sink rate