Basic Engine Terms TurboMachine.com home
Accessory
Drive
The accessory drive section is attached to the outside bottom or side of the
engine and is where all the mechanically-driven components are mounted to the
engine. This section takes mechanical energy from the engine to power the engine
and aircraft accessories mounted to the accessory gearbox. These accessories can
include the fuel pump, hydraulic pump, oil pump, alternator, and starter.
Afterburner
The afterburner is an assembly aft of the turbine section that supplies atomized
fuel into the exhaust airflow to increase exhaust temperature and pressure.
Afterburners use large quantities of fuel, and thus are used for short periods
of time only. Afterburners are used on turbojet engines to increase thrust for
short periods of time during takeoff, climb and supersonic flight. Very few
commercial aircraft use afterburners. Afterburners are usually on military
aircraft only.
Augmentor
Augmentors are afterburners on low-bypass turbofan engines. Core airflow and
bypass (fan) airflow are mixed aft of the turbines, in the exhaust. Fuel nozzles
supply atomized fuel into the airflow and an igniter ignites the fuel/air
mixture. Augmentors are used on low-bypass turbofan engines to increase thrust
for short periods during takeoff, climb, and combat flight.
Augmentor
Exhaust Nozzles
Augmentor exhaust nozzles make up the aft end of augmented low-bypass turbofan
engines. It has a flame holder, fuel nozzles, an igniter, and a variable exhaust
nozzle. The fuel nozzles supply atomized fuel into the exhaust airflow and the
igniter makes the fuel/air mixture burn. Augmentor exhaust nozzles are used on
low-bypass turbofan engines to increase thrust.
Combustor
In the combustor, compressed air generated by the compressor is mixed with fuel
and then ignited. Nozzles spray fuel into the stream of air and the mixture of
air and fuel is ignited providing an extremely hot and powerful airflow. The
fuel burns with the oxygen in the compressed air, producing hot expanding gases.
The inside of the combustor is often made of ceramic materials to provide a
heat-resistant chamber. Temperatures in the combustor can reach 2700ºF.
Compressor
The compressor is the first component in the core of the engine. It is made up
of a series of fans with many blades and is attached to the shaft. The
compressor squeezes air that enters it into progressively smaller areas,
resulting in an increase in the air pressure. The result is an increase in the
energy potential of the air. The compressed air is then forced into the
combustion chamber.
Convergent-Divergent Exhaust Nozzle
A variable convergent-divergent (C-D) exhaust nozzle (Iris) is made up of flaps
that interlock. The C-D exhaust nozzle is automatically controlled to improve
subsonic and supersonic flight of jet aircraft.
As the exhaust nozzle converges, the exhaust gases are subsonic. As the exhaust
nozzle diverges the gases become supersonic. Supersonic flight requires a C-D
exhaust nozzle. A variable C-D exhaust nozzle is used on modern supersonic
aircraft. A variable C-D exhaust nozzle is more efficient than a fixed C-D
exhaust nozzle.
Core
The core engine module is aft of the fan module and forward of the turbine
stator case and is made up of three components: compressor rotor and stator,
combustion liner and Stage 1 HPT nozzle. The core is responsible for supplying
approximately 20 percent of the total engine thrust and the torque for operation
of all accessories.
Exhaust
The exhaust section is located behind the turbine section and at the rear of the
engine. It is made up of either a fixed or variable nozzle assembly, depending
on the aircraft application. The exhaust section directs the exhaust gases aft
and further accelerates the exhaust gases to produce forward thrust. Variable
nozzles are usually found on military engines while fixed are typically
associated with commercial turbofans.
Fan
The fan is the first component on the engine. The spinning fan sucks in large
quantities of air. Most blades of the fan are made of titanium. It then speeds
this air up and splits it into two parts. One part continues through the "core"
or center of the engine, where it is acted upon by the other engine components.
The fan module typically supplies approximately 80 percent of the engine thrust.
The second part "bypasses" the core of the engine. It goes through a duct that
surrounds the core to the back of the engine where it produces much of the force
that propels the airplane forward. This cooler air helps to quiet the engine as
well as adding thrust to the engine.
Gas Turbine
Another term for an aircraft engine.
High-Pressure Turbine (HPT)
The HPT module is aft of the compressor rear frame and forward of the LPT stator
case. The HPT module is made up of the HPT rotor and HPT stator and is removes
energy from the combustion gases to turn the high-pressure compressor and
accessory gearbox.
Inlet
The inlet sends air to the forward end of the compressor. The inlet is
aerodynamically designed to insure a smooth, evenly distributed airflow into the
engine.
Laws of
Motion
Sir Isaac Newton proposed three laws of motion.
1. Every object in a state of uniform motion tends to remain in that state of
motion unless an external force is applied to it.
2. The relationship between an object's mass m, its acceleration a, and the
applied force F is F = ma. Acceleration and force are vectors. In this law the
direction of the force vector is the same as the direction of the acceleration
vector.
3. When an object is pushed in one direction, there is always a resistance of
the same size in the opposite direction.
Lift
A force that pushes objects upward.
Low-Pressure Turbine (LPT)
The LPT module is the in the rear of the engine, aft of the HPT stator case. LPT
components include the LPT rotor, LPT nozzle stator case and turbine rear frame.
The LPT removes energy from the combustion gases to drive the low-pressure
compressor (N1) rotor assembly.
Mach 1
Breaking the speed of sound. Mach 1 is equivalent to 760 miles per hour at 70F,
at sea level.
Nozzle
The nozzle is the exhaust duct of the engine. This is the engine part that
actually produces the thrust for the plane. The energy depleted airflow that
passed the turbine, in addition to the colder air that bypassed the engine core,
produces a force when exiting the nozzle that acts to propel the engine, and
therefore the airplane, forward. The combination of the hot air and cold air are
expelled and produce an exhaust, which causes a forward thrust.
Propulsion
(as a field of study in relation to Aeronautics) is the study of how to design
an engine that will provide the thrust that is needed for a plane to take off
and fly through the air.
Regimes of
Flight
The ranges of speed that airplanes fly. Subsonic: 100-350 MPH. Transonic:
350-750 MPH. Supersonic:760-3500 MPH. Hypersonic: 3500-7000 MPH
Shock Wave
A series of air waves that form in front of a fast moving plane. In order to
travel faster than sound the plane must push through these waves. This creates a
sonic boom.
Sonic Boom
When a plane pushes through a shockwave it creates a sonic boom. The noise is
the result of breaking through the airwaves that form in front of a fast moving
plane. The sonic boom sounds when the plane is going faster than 760 MPH.
Sound Waves
Sound is made up of molecules of air that move. When they push together they
form sound waves.
Speed of
Sound
When a plane travels faster than 760 miles per hour at 70F at sea level a sound
barrier forms. If a plane is going at the speed of sound
it is traveling at Mach 1.
Subsonic
Subsonic is a speed of 100-350 MPH. Small planes such as crop dusters and
seaplanes are examples of planes that travel at this speed.
Suck-Squeeze-Bang-Blow
The term that is generally used to describe the operation of a jet engine. The
fan sucks in the air, the compressor squeezes the air down, the combustor
ignites the mixture (bang) and the turbine blows the air out the back creating
thrust and turning the forward fan.
Supersonic
Planes that travel faster than Mach 1 (or the speed of sound) are traveling at
supersonic speeds.
Thrust
The forward force that pushes the engine and, therefore, the airplane forward.
Sir Isaac Newton discovered that for "every action there is an equal and
opposite reaction." Aircraft engine use this principle.
Thrust
Reverser
Thrust reversers serve as an aircraft's main brakes on landing. There are three
types of thrust reversers: translating cowl, clam shell and turboprop reverse
pitch. All three literally reverse the engines thrust by closing in when
deployed by the pilot pushing the air out the front of the engine rather than
the back. This motion decreases the speed of the aircraft and is the loud noise
you hear when landing.
Transonic
This speed of flight includes most of the commercial flights that carry
passengers and cargo. Transonic speed is 350 - 750 MPH.
Turbine
Located behind the combustor, the turbine section uses energy in the rapidly
moving, hot gases coming out of the combustion section to turn a shaft to drive
the compressor and other engine accessories.
Turbojet
Air taken in from an opening in the front of the engine is compressed up to 3 to
12 times its original pressure in compressor. Fuel is added to the air and
burned in a combustion chamber to raise the temperature of the fluid mixture to
about 1,100ºF to 1,300ºF. The resulting hot air is passed through a turbine,
which drives the compressor. If the turbine and compressor are efficient, the
pressure at the turbine discharge will be nearly twice the atmospheric pressure,
and this excess pressure is sent to the nozzle to produce a high-velocity stream
of gas which produces a thrust. Substantial increases in thrust can be obtained
by employing an afterburner. It is a second combustion chamber positioned after
the turbine and before the nozzle. The afterburner increases the temperature of
the gas ahead of the nozzle. The result of this increase in temperature is an
increase of about 40 percent in thrust at takeoff and a much larger percentage
at high speeds once the plane is in the air.
The turbojet engine is a reaction engine. In a reaction engine, expanding gases
push hard against the front of the engine. The turbojet sucks in air and
compresses or squeezes it. The gases flow through the turbine and make it spin.
These gases bounce back and shoot our of the rear of the exhaust, pushing the
plane forward.
Turboprop
A turboprop is a jet engine attached to a propeller. The turbine at the back is
turned by the hot gases generated by the engine, and this turns a shaft that
drives the propeller. A variety of smaller aircraft are powered by turboprops.
Like the turbojet, the turboprop engine consists of a compressor, combustion
chamber, and turbine, the air and gas pressure is used to run the turbine, which
then creates power to drive the compressor. Compared with a turbojet engine, the
turboprop has better propulsion efficiency at flight speeds below about 500
miles per hour. Modern turboprop engines are equipped with propellers that have
a smaller diameter but a larger number of blades for efficient operation at much
higher flight speeds. To accommodate the higher flight speeds, the blades are
scimitar-shaped with swept-back leading edges at the blade tips. Engines
featuring such propellers are called propfans.
Turbofan
A turbofan engine has a large fan at the front, which sucks in air. Most of the
air flows around the outside of the engine, making it quieter and giving more
thrust at low speeds. Most of today's airliners are powered by turbofans. In a
turbojet all the air entering the intake passes through the gas generator, which
is composed of the compressor, combustion chamber, and turbine. In a turbofan
engine only a portion of the incoming air goes into the combustion chamber. The
remainder passes through a fan, or low-pressure compressor, and is ejected
directly as a "cold" jet or mixed with the gas-generator exhaust to produce a
"hot" jet. The objective of this sort of bypass system is to increase thrust
without increasing fuel consumption. It achieves this by increasing the total
air-mass flow and reducing the velocity within the same total energy supply.
Turboshaft
This is another form of gas-turbine engine that operates much like a turboprop
system. It does not drive a propeller. Instead, it provides power for a
helicopter rotor. The turboshaft engine is designed so that the speed of the
helicopter rotor is independent of the rotating speed of the gas generator. This
permits the rotor speed to be kept constant even when the speed of the generator
is varied to modulate the amount of power produced.
Vectoring
Vectoring is the procedure that makes the exhaust nozzle structure turn to make
forward, vertical or side-to-side thrust. Vectoring supplies the directional
thrust necessary for vertical take off and landing (VTOL) and short take off and
landing (STOL) military aircraft. Vectoring also gives aircraft a better rate of
climb and increases control during flight.