Thrust Reversal
In a typical turbofan jet engine the oncoming airflow is compressed
throughout a series of compressor stages, mixed with a fuel (typically
kerosene) and combusted, drastically increasing pressure and temperature, and
then expanded through a nozzle to provide thrust towards the rear of the
aircraft. By accelerating the fluid towards aft, Newton’s Third Law implies
that this impulse must be reacted by an equal and opposite force in the
opposite direction, thus propelling the aircraft forward. However, modern jet
engines are also capable of producing thrust in the opposing direction. How is
this possible without completely changing the direction of airflow from the
exhaust to the intake which would seriously damage various engine components?
Diagram of a typical gas
turbine jet engine. Air is compressed by the fan blades as it enters the
engine, and it is mixed and burned with fuel in the combustion section. The hot
exhaust gases provide forward thrust and turn the turbines which drive the
compressor fan blades. (Photo credit: Wikipedia)
Thrust reversal is achieved by momentarily diverting the hot exhaust
gases towards the front of the aircraft or changing the propeller/compressor
pitch so that the thrust produced is directed forward. Thus thrust will act
against the forward direction of travel and provide a means of deceleration.
Thrust reversal is used in some flight scenarios in order to,
● Alleviate
the stress and reduce wear on the brakes or to enable shorter landing
distances. Reverse thrust can reduce the braking distance by a third or more!
● Momentarily
increase the braking force during emergencies or just after touchdown when the
aircraft is still traveling at a high velocity and the residual aerodynamic
lift is significant. Lift reduces the normal reaction force with the ground and
therefore limits friction and grip on the tyres.
● Rapid
deceleration in flight to enable quick changes of speed. Most aircraft cannot
operate thrust reversal in flight and the majority that can are
propeller-driven.
● Helping
to push an aircraft back from a gate. A maneuver called
“powerback”.
Almost everyone who has sat in a row near the wings will have heard
reverse thrust in action before. Next time you land wait for the sudden
high-pitched increase in engine noise just after touchdown.
The method to achieve thrust reversal varies greatly between the
different types of engines:
● Since
the 1930s propeller-driven aircraft generate reverse thrust by changing the
angle of attack of their controllable pitch propellers:
○ Older
reciprocating engines and modern turboprop engines both have the ability to set
the propeller angle to “flat pitch”. As a result the propellor airfoils produce no forward or reverse thrust, but
large amounts of drag instead. This allows the engine speed to be kept at a
constant speed while descending.
○ The classic
approach is to pitch the propeller blades to a negative angle of attack in
order to direct the thrust forward.
● In jet
engines thrust reversal is not accomplished by running the engine in reverse
but by diverting the high-velocity exhaust jet blast to the front of the
engines. This can be achieved in different ways:
1. The
target-type thrust reverser: After the combustion chamber, reverser blades
angle outward in order to prematurely redirect the high-speed jet radially
outwards and towards the front of the engine. This construction generally gives
the appearance of flower petals.
2. The
clamshell type: Two reverser buckets are hinged at the aft of the engine, and
when deployed, intrude into the exhaust of the engine. In this manner the jet
blast is captured and re-oriented towards the front.
3. In a
turbofan engine some of the air intake is not passed through the main part of
the engine, but redirected along an outside channel without being combusted.
This bypass duct is aptly named “cold flow” and this arrangement is used to
save fuel and reduce engine noise. Furthermore, the bypass flow can also be
used to channel air radially outwards and forwards to provide thrust reversal.
The three different types of thrust mechanisms explained
above (1).
Youtube has some great videos showing thrust reversal in action: Reverse Thrust 1
http://www.youtube.com/watch?v=sdVFVGom7es The following video is especially great since the flow reversal of the air can actually be seen by water sprayed up on the tarmac ahead of the turbines: Reverse Thrust 2 http://www.youtube.com/watch?v=eqQcg7e8eYc