You're on your first solo stall. Power is back to idle.
Nose and wings are level while speed bleeds away. You feel
elevator buffetting through the stick as the stall warning
sounds. The nose will drop very soon and you'll recover
from the stall. Piece of cake. Except there's one small
problem. While busy holding the nose and wings level, you
somehow missed a developing yaw. Unconsciously, you rested
a little more weight on the left pedal and now - gosh, the
nose drops and the left wing flicks down viciously.
Taken by surprise, you respond in slow
motion: forward stick, right rudder, full throttle and
unconsciously, right aileron. No joy, the rotation seems to
continue. You hear the sounds of rising airspeed and a
racing engine as the rotation slows. You catch the right
aileron and correct it - whew! The ground is getting closer
- fast! So you pull back on the stick smoothly and firmly.
Bang! Bang! Your wing spars fracture and you're now a
wingless lawn dart!
As I wrote this, my pulse quickened, as it probably did for
those of you who fly. Parts of the situation above probably
parallel our own fears or personal experiences when first
learning to fly. But why should we worry about spins/spiral
dives when flying sims? Being a lawn dart isn't a big deal
- after all, it's not fatal! Besides, all the control laws
of new fangled jet sims like EF2000, F22 ADF etc prevent
spins don't they?
True for the jet jockeys. But with some
high fidelity prop sims like Fighter Squadron etc, if they
are any good, you could experience inadvertent spins more
often than you expect. This may be especially the case when
you're in an intense dogfight against tough opponents. So
let's delve a little more into spins and how to recover
from them.
Autorotation
Let's look at an example in which the aircraft enters a
normal spin to the left. Yawing (to the left in our
example) at the point of stall causes a lift imbalance
between each wing because the right wing is moving faster
than the left. The lift imbalance causes a left roll and
stalling of the left wing.
Differential angles of attack for both
wings also cause differential drag. Greater drag from the
left wing gives rise to a left yaw, which then feeds back
into the lift imbalance between the wings. Hence, a
self-sustaining feedback loop is established between yaw
and roll.
Incipient Spin
The incipient phase of a spin occurs when the aircraft
transitions from a horizontal to a vertical flight path.
Airspeed increases during this time. What happens next
depends on whether the aircraft enters a stable or unstable
spin.
To understand this, think of the aircraft as a simple stick
(representing the longitudinal axis) with two unequal
weights attached to each end. In turn, the stick is
attached to a pole and can pivot about the attachment
point. As the stick is rotated as shown, the weights drive
outwards, tending to make the stick (aircraft) move towards
the horizontal.
Spin rotation speeds depend on an aircraft's individual
characteristics but typical rotation speeds are around 360
degrees per second. Vertical descent speeds are typically
in excess of 6000 feet per minute. For piston aircraft, the
engine usually cuts out leaving the propeller to stop while
turbine aircraft may experience engine flameouts. So spin
recovery usually involves engine airstarts - always a fun
exercise!
<>Stable Spin
If the rotation is sufficiently fast, the aircraft's nose
pitches up to a shallower nose-down angle. As this happens,
both wings become fully stalled and airspeed stabilises. At
this point, the aircraft is established in a stable spin
with the controls remaining in the pro-spin position (full
back stick and left rudder - in our example) on their own.
In a stable spin, equilibrium is reached between the
natural pitch down tendency due to the aircraft's
aerodynamic stability, and the pitch up tendency due to the
inertia forces.
Given the influence of mass distribution and the centre of
gravity's (CG) location, it is easy to visualise the
effects of an aft CG (decreased pitch stability) and
greater mass dispersion (increased inertia forces). The
spin becomes flatter (remember the dreaded flat spin in Top
Gun?) and more difficult from which to recover.
Unstable Spin
What happens when the inertia forces cannot generate
sufficient pitch up motion to offset the pitch down motion
due to the aircraft's aerodynamic stability? The nose
simply pitches down, thereby unstalling the wings. No
problem, after all, this is what we want - right? It turns
out that life isn't as simple.
Remember that entry into the spin involved significant yaw
rate and angle? Under such conditions, the blanketing
effect of the vertical tail means the elevators are
ineffective in holding the nose up. The aircraft enters a
spiral dive in which speed and G forces (outward from the
spiral) build up very rapidly. If the pilot doesn't recover
sufficiently fast, he will become an expensive lawn dart!
You may have watched with perhaps morbid fascination, World
War 2 movies of mortally wounded B-17 Flying Fortresses in
their spiral dives. Many broke up as they went down, no
doubt due to massive structural failure of their airframes.
It was not a pretty sight. One can only imagine the terror
of the crewmen pinned helplessly by G forces in the
spiralling aircraft; knowing that only death would release
them.
In developing spiral dives, structural failure can occur as
the pilot attempts to pull out of the dive. Wing structures
appear to fail at loads below stated limits of the
aircraft. For example, an aircraft rated to 6Gs may
experience wing buckling or even wing loss at 4-5Gs, as the
pilot tries to pull out of a spiral dive. Why does this
happen? The reason more often than not, is due to the
failed wing exceeding its rolling G limit. This and other
interesting topics will be discussed in a later article.
Alright, enough of theory and onto flying technique.
Entering into a Spin
The actions for entering into a stable spin are
straightforward:
[1] Close the throttle and hold the nose level as in a
power-off clean level stall.
[2] As the airspeed bleeds to 1.1Vs apply positive and
full back stick and rudder.
[3] Hold the controls in the pro-spin position and
watch for spin stabilisation.
Recognising a Stable Spin
[1] Airspeed stabilises (value depends on aircraft
type).
[2] Controls remain in a pro-spin position.
[3] Descent rate stabilises.
[4] Propeller may stop turning.
[5] Turn indicator points in spin direction.
Note that if the airspeed does not stabilise but continues
to increase, then the aircraft is in a spiral dive and the
pilot must commence recovery immediately.
Recovering from a Spin
Most aircraft will recover through use of the following
technique:
[1] Close the throttle.
[2] Release the stick. (ie hands off!)
[3] Check the spin direction.
[4] Apply full opposite rudder and hold.
[5] Centralise the rudder when the spin stops.
[6] Recover from the dive gradually.
[7] Execute an airstart during the dive recovery.
Closing Comments
There are some types of aircraft in which the above
"hands-off" recovery technique does not work. Such aircraft
typically require positive forward stick to pitch the nose
down to unstall the wings. This characteristic may be due
to aircraft design, an aft CG location, greater mass
dispersion or a combination of all three factors.
My former chief flight instructor (one-time airforce test
pilot) told me of a nasty experience with a De Havilland
Chipmunk which refused to recover from a spin. When he
entered the spin, he noticed it appeared to have a very
shallow nose angle. Anyway, with the altimeter unwinding
merrily towards 5000 feet, he began recovery. He became a
little concerned when the aircraft simply refused to
respond to the full opposite rudder. Then it dawned upon
him that the very shallow nose angle indicated a flat spin!
He then tried positive forward stick - no response.
With precious little altitude left, he resorted to pitching
the stick back and forth - timing each reversal to help
increase the pitch oscillation. Grudgingly, the aircraft
pitched out of the shallow rotation plane, after which a
normal recovery followed.
Unknown to him, the aircraft had been
fitted with a larger engine and as a result, required a
counter-weight in the rear fuselage. The increased mass
placed at each end of the fuselage greatly increased the
inertial forces generated during the spin, thereby causing
the rotational plane to flatten. Following a hasty landing
and shutdown, a young mechanic sauntered up to stick a
"Spins Prohibited" placard in the cockpit. He had forgotten
to do so a few days earlier!
Taken by surprise, you respond in slow
motion: forward stick, right rudder, full throttle and
unconsciously, right aileron. No joy, the rotation seems to
continue. You hear the sounds of rising airspeed and a
racing engine as the rotation slows. You catch the right
aileron and correct it - whew! The ground is getting closer
- fast! So you pull back on the stick smoothly and firmly.
Bang! Bang! Your wing spars fracture and you're now a
wingless lawn dart!
