Fuel systems.pdf

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Screen and Spacer
Screen and spacer filters work on the same principle as both screen and paper filters. In the screen
and spacer filter, shown below, the elements are disc-shaped and stack onto the element support.

Oil flows in through both sides of the filter discs separated by the spacer, into the perforated tube and
out to the system. These filters are normally used as pressure filters and are fitted downstream of the
pump.

Screen and spacer filter

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 Thread Filters
Thread filters are used as ‘last chance’ filters. They are placed just before the jets that spray oil into a
bearing to prevent blockage of the jet. This is the last chance to filter the oil before it enters the
bearings, thus the name.

They consist of an inner threaded element which is enclosed by an unthreaded outer casing. Oil
passes through the outer casing, across the threads being filtered, into the centre of the inner
element and then on to the oil jet. The filtration required is achieved by selecting a coarser- or finer-
pitched thread on the threaded portion of the filter. The finer the pitch, the greater the degree of
filtration.

Threaded filter

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 Oil Filter Bypass
It is a regulatory requirement that all oil filters be constructed and installed in a way that permits full
oil flow even if the filter becomes completely blocked. Therefore, some means of bypassing the filter
must be provided.

The most common way to meet this requirement is to incorporate an oil bypass valve that
automatically lets oil bypass the filter entirely once it becomes plugged. Since the use of unfiltered oil
to lubricate main bearings can cause extensive damage, most turbine-powered aircraft have a
warning light in the cockpit to notify the operator when the filter is being bypassed. Often a red ‘pop-
out’ clogging indicator is added to the filter housing as a visual bypass warning.

Oil filter bypass

Oil Filter Bypass Warning and Indication
Oil filter impending bypass warning instrumentation is also installed in many engines to tell flight and
maintenance personnel that the main oil filter is approaching a blocked condition or is completely
blocked. It is adjusted to actuate at a differential pressure sufficiently less than what the filter will
start bypassing to permit flight crews to take timely action and prevent bypassing of unfiltered oil.

Such instrumentation is considered a maintenance aid because timely action in most cases prolongs
the life of the engine components.

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 Oil System Components
Oil Coolers
The purpose of all oil coolers is to maintain a specific oil temperature under differing oil heat
conditions which occur at various engine speeds. Oil coolers are of two basic types:

fuel-cooled
air-cooled.

The oil cooler in a turbine engine may be located in either the pressure subsystem or the scavenge
subsystem. When installed in the pressure subsystem, the lubrication system is sometimes referred
to as a hot tank system because the scavenge oil is not cooled before it enters the reservoir.

On the other hand, when the oil cooler is placed in the scavenge subsystem, the lubrication system is
often referred to as a cold tank system because the oil is cooled just before it enters the reservoir.

Oil cooler

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 Fuel-Cooled Oil Coolers
The fuel-cooled oil cooler is the most common engine oil cooler on larger engines, but is also used on
many smaller engines. It consists of a large number of tubes (not unlike drinking straws), called a
matrix, contained within a sealed outer case. The tubes convey the fuel through the cooler while oil is
circulated around the outside of the tubes by baffle plates. Heat is transferred from the oil to the fuel.
This heating of the fuel is desirable to prevent fuel system component icing.

Many fuel-cooled oil coolers contain a combination differential pressure bypass valve and
thermostatic bypass valve at the cooler inlet. When the oil is cold, the valve is open and the oil is
allowed to bypass the cooler and flow directly into the oil system. As the oil heats up, the
thermostatic bypass valve expands and closes the bypass passage, which forces the oil to travel
through the cooler.

If the cooler becomes blocked, the pressure of the oil increases until it forces the differential pressure
bypass valve off its seat. This causes the oil to bypass the cooler and be available for use, uncooled, by
the engine. This condition is shown in the top diagram below, which illustrates the oil flow when the
bypass valve is open. The bottom diagram illustrates the oil flow when the bypass valve is closed.

Fuel-cooled oil cooler, "Bypass valve open"

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 Fuel-cooled oil cooler, "Bypass valve closed"

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 Air-Cooled Oil Coolers
Air-cooled oil coolers use the same principles of operation as the fuel-cooled oil cooler. Its oil is
cooled by air that flows through the matrix.

The air-cooled oil cooler also uses the same bypass and thermostatic valve systems as the fuel-cooled
oil cooler. Air is directed through the cooler by a thermostatically controlled air scoop, which
regulates the temperature of the oil by controlling the quantity of air that is allowed to pass through
the cooler.

Air cooled oil cooler

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 Oil Jets
After the oil passes through the pressure pump and filter, it must be distributed to the points which
require lubrication. The oil jets serve this purpose. The pressure oil is forced through the calibrated
orifice and delivered in the form of an oil spray or a fluid stream onto bearings, oil seals, gears and
other parts.

The fluid stream is by far the most commonly used system, especially where high pressure loads are
involved. In most cases, this stream of oil is directed onto the bearing surface by what is sometimes
called a direct-lubrication oil jet. Some engines use compressor bleed air to deliver an air/oil mist
spray through a mist- and vapour-lubrication oil jet. This allows for a wider area of lubrication from a
single oil jet and is utilised in some of the larger engines.

A newer type of oil jet is coming into use called an under-race lubrication jet. This system routes oil
down the rotor shafts and bearing journals, then feeds it through slots acting as oil jets in the bearing
inner races. It is claimed that this system achieves superior cooling compared to conventional spray
jet lubrication.

Aviation Australia
Oil Jets

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 © Aviation Australia
Under race lubrication

Vents
Vents, or breathers, are fitted to oil tanks and bearing chambers to prevent an undesirable build-up of
excess air pressure. This pressure results from sealing air leaking across carbon and labyrinth type oil
seals. The diagram below shows this application to a labyrinth type oil seal.

Some air pressure is required within the tank to assist gravity feeding of the oil, and in the bearing
chambers, to allow proper scavenge and oil jet spray. The most common type of vent system is the
centrifugal breather.

As the oil-laden air enters the rotating slinger chamber of the breather, centrifugal force flings the oil
outwards to drain back into the sump while the clean vent air is routed overboard, or to a pressurising
and vent valve in the reservoir and then overboard.

Aviation Australia
Oil Vent
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 Oil vent system

Most vent systems use a vent pressurising valve to maintain 5–7 psi head of pressure within the tank
and bearing chambers. The vent-pressurising valve consists of an aneroid bellows with sea-level air
pressure trapped inside, and a spring-loaded pressure relief valve in the overboard vent line. At sea
level the vent is open, but it closes as the altitude increases in order to maintain the vent pressure the
same as it is at sea level.

The aneroid capsule typically begins to close at an altitude of about 8000 ft and completely closes at
about 20 000 ft. The vent system then acts as a pressurising check valve and maintains the pressure
at 5–7 psi.

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 Oil system vent valve

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 Chip Detectors and Magnetic Plugs
Many scavenge subsystems contain permanent magnet chip detectors (MCDs) that attract and hold
ferrous metal particles. These chip detectors are used for several reasons: First, any metal particles
that are attracted to the detector are prevented from circulating in the engine and causing additional
wear. Second, the collection of metal particles on an MCD provides valuable information when
troubleshooting engine problems.

As a general rule, the presence of small fuzzy particles or grey metallic paste is the result of normal
engine wear and is therefore not a cause for concern. However, metallic chips or flakes indicate
serious internal wear which must be investigated further.

Normally one MCD is located in each of the following locations:

Engine forward-bearing sump
Engine rear-bearing sump
Accessory gearbox
Transfer gearbox.

Their location is normally labelled to identify the scavenge system they belong to. When removed,
the MCD closes off a valve to prevent oil leakage.

Chip detector

A quick-disconnect bayonet fitting attachment is common.

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 Some chip detectors incorporate an electric circuit that operates an indicator light in the cockpit.
With this type of MCD, sometimes called an indicating chip detector, a positive electrode is placed in
the centre of the detector while a negative or ground electrode is placed on the detector shell.

In this configuration, when metallic debris bridges the gap between the positive and ground
electrodes, the indicator circuit is completed and the warning light illuminates. The flight crew must
then respond to the warning and take the necessary precautions to prevent engine damage and
ensure flight safety.

Quick disconnect bayonet fitting

Aviation Australia
Chip detector warning circuit

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 Lubrication System Types
Pressure Relief Valve System
A typical pressure relief lubrication system consists of an oil reservoir, pressure and scavenge pumps,
a pressure relief valve (pressure regulating valve), several oil filters, oil jets, an oil cooler and vent
lines.

In a turbine engine, the pressure within the bearing chambers increases dramatically with increases
in engine speed. As the pressure within the bearing chambers increases, the pressure differential
between the bearing chambers and the lubrication system decreases.

The lower the pressure differential, the less oil flows to the bearings. To prevent this from happening,
some of the pressurised air within the bearing chambers is typically routed to the back side of the
pressure relief valve to augment the spring pressure. This way, as the engine speed increases, the
pressure within the lubrication system also increases.

Pressure relief valve engine lubricating system

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 Full Flow Systems
In a full-flow system, no pressure relief valve is used; therefore, the amount of oil that flows to the
bearings is directly related to how fast the engine and oil pump are run. In this case, the size of the oil
pump is determined by the oil flow required at the engine’s maximum operating speed.

Full flow engine lubricating system

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 Oil System Indication
Oil System Indicators
Gauge connection provisions are incorporated in the oil system for oil pressure, oil quantity, low oil
pressure, oil filter differential pressure switch and oil temperature.

A turbine engine pressure gauge is typically connected to the oil system downstream of the main oil
filter. This location ensures an indication of the actual pressure being delivered to the engine. As an
additional feature, some oil pressure systems incorporate a low-pressure warning light. When
aircraft electrical power is turned on and the engine is not running, each engine’s low oil pressure
light illuminates.

However, when the engine is starting, the warning light should extinguish once oil pressure increases
above the low limit marked on the oil pressure gauge.

The oil temperature sensor is located in the pressure line before the oil goes to the engine bearings
and after it passes through all other oil system components (filter, coolers, relief valves)

Engine oil system indication

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 ECAM / EICAS Engine Oil Indication
In today’s aircraft, the engine oil indication and warning system is displayed electronically in the
cockpit on the ECAM or EICAS displays.

Oil system information on a digital display (EICAS/ECAM)

Relevant Youtube link: Lubrication System 1 (Video)

Relevant Youtube link: Lubrication System 2 (Video)

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 Fuel Systems (15.11)
Learning Objectives
15.11.1.1 Identify engine fuel system components and describe their operation (Level 2).
15.11.2.1 Describe the operation of engine fuel metering systems (Level 2).
15.11.2.2 Describe the operation of electronic engine control (FADEC) (Level 2).

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 Fuel System Components I
Engine Fuel Systems
Gas turbine engines convert the latent energy of fuel into heat to provide energy for engine
operation and thrust for the aircraft. The function of the fuel system is to provide the engine with fuel
in a form suitable for combustion and to control its flow to the required rates necessary for easy
starting, acceleration and stable running in all engine operating conditions.

For a gas turbine engine to deliver the power required, it needs a system that supplies fuel in
sufficient quantities to allow for varying conditions, ambient temperature, altitudes and power
settings.

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 Fuel System Layout
The layouts of aircraft and engine fuel systems vary with the type and size of aircraft.

However, most systems include the following components:

Fuel tank
Boost pump
Low-pressure (LP) shut-off valve
Low-pressure transmitter
Fuel heater
High-pressure (HP) fuel pump
Fuel filters
Fuel pressure differential switch
Fuel control unit
High-pressure shut-off valve
Fuel flow transmitter
Pressurising and dump valve
Fuel burners.

Simplified fuel system for a gas turbine engine (73-00)

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 Low-Pressure Shut-Off Valves
Low-pressure shut-off valves (LPSOVs) on modern aircraft (normally mounted behind the engine
firewall) are used to isolate the engine fuel system from the airframe in case of fire or system
maintenance.

The two common types of shut-off valves are:

Motor-driven gate valve
Solenoid-operated valve.

Motor-Driven Gate Valve
The motor-driven gate valve shown below uses a reversible electric motor linked to a sliding valve
assembly. The motor moves the valve gate in and out of the passage through which the fuel flows,
thus shutting off or turning on the fuel flow.

Motor-driven gate valve

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 Solenoid-Operated Valve
A solenoid valve has an advantage over a motor-driven valve: it is much quicker to open or close. The
valve shown below is a solenoid-operated, poppet type valve. When electrical current momentarily
flows through the opening solenoid coil, a magnetic pull is exerted on the valve stem that opens the
valve. When the stem rises high enough, the spring-loaded locking plunger is forced into the notch in
the valve stem. This holds the valve open until current is momentarily directed to the closing solenoid
coil. The magnetic pull of this coil pulls the locking plunger out of the notch in the valve stem, the
spring closes the valve and shuts off the flow of fuel.

Solenoid-operated poppet valve

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 Low-Pressure Transmitters
For aircraft fitted with more than one fuel tank, it is desirable to have a means of warning the pilot
that fuel in the supplying tank is exhausted (or the boost pump is not operating) and that the fuel
selector must be set to draw fuel from another tank. The low fuel pressure switch is held open by
normal fuel pressures, but it closes when the pressure falls. This turns on the warning light in the
cockpit.

Fuel pressure warning lights

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 Fuel Heaters
Turbine-powered aircraft that operate at high altitudes and low temperatures for extended periods
have the problem of water condensing out of the fuel and freezing on the fuel filters. To prevent this,
these aircraft have a fuel temperature gauge and/or a filter differential pressure warning light that
illuminates when ice obstructs the filter.

The purpose of the fuel heater is to protect the fuel system from ice formation and to thaw ice that
forms on the fuel filter screen. This is achieved by using hot air that has been heated by the
compressor section of the engine. A fuel heater is depicted in the illustration below.

Fuel heater

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 High-Pressure Fuel Pumps
Engine-mounted fuel pumps are required to deliver a continuous supply of fuel at the proper
pressure at all times during operation of the aircraft engine. They must be capable of delivering
maximum needed flow at high pressure to obtain satisfactory nozzle atomisation and accurate fuel
regulation.

The two common types of engine-driven fuel pumps are:

Spur gear type
Piston type.

Spur Gear Type Pumps
Gear type pumps have approximately straight-line flow characteristics, whereas fuel requirements
fluctuate with flight or ambient air conditions. Hence a pump of adequate capacity at all engine
operating conditions has excess capacity over most of the range of operation. This characteristic
requires the use of a pressure relief valve for disposing of excess fuel.

A typical constant displacement gear pump is illustrated below. The fuel enters the pump at the
impeller, which gives an initial pressure increase and discharges fuel to the two HP gear elements.
Each of these elements discharges fuel through a check valve to a common discharge port. Shear
sections are incorporated in the drive system of each element. Thus, if one element fails, the other
continues to operate. The check valves prevent circulation through the inoperative unit. One element
is capable of supplying sufficient fuel for moderate aircraft speeds.

A relief valve is incorporated in the discharge port of the pump to allow fuel in excess of that required
by the engine to be recirculated to the inlet side of the HP elements.

Gear type pump

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 Piston Type Pumps
The variable displacement pump system differs from the constant displacement pump system. Pump
displacement is changed to meet the varying fuel flow requirements, that is, the amount of fuel
discharged from the pump can be made to vary at any one speed. This is due to the inclination of the
cam-plate; movement of the rotor imparts a reciprocating motion to the pistons, thus producing a
pumping action. The stroke of the pistons is determined by the angle of inclination on the cam-plate.
The degree of inclination is varied by the movement of a servo piston that is mechanically linked to
the cam-plate and is biased by springs to give the full stroke position of the plungers. The piston is
subject to servo pressure on the spring side and on the other side to pump delivery pressure, thus,
variations in the pressure difference across the servo piston cause it to move with corresponding
variations of the cam-plate angle and therefore pump stroke.

With a variable flow pump, the fuel control unit can automatically and accurately regulate the pump
pressure and delivery to the engine.

Variable displacement piston type pump

Relevant Youtube link: Pressure Compensated Pump (Video)

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 Fuel Filter
Because the HP fuel pump, fuel control unit, pressurisation valve, dump valve and burners are
manufactured to very fine tolerances and fitted with many small orifices, a filter is installed to protect
the fuel control components from contaminants. The filter must be capable of removing particles
measuring as small as 10 microns.

Fuel filter internal diagram

The three most common types of filters in use are the micron filter, the wafer screen filter and the
plain screen mesh filter. The individual use of each of these filters is dictated by the filtering
treatment required at a particular location.

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 Fuel filters physical example

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 Fuel Pressure Differential Switch
The differential pressure switch is used in the fuel system to detect the presence of icing on the fuel
filter. It illuminates a cockpit warning light when the pressure differential reaches a set amount.

A fuel pressure differential switch takes a pressure reading from near the fuel flow transmitter and
from between the fuel filter and HP pump. It indicates whether the fuel filter is becoming blocked by
ice or foreign material in the fuel, enabling the pilot to select fuel heating to remove ice from the filter.

Filter differential pressure sensor

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 Fuel Control Systems
Fuel Control Units
The control of power (or thrust) in a gas turbine engine is affected by regulating the quantity of fuel
injected into the combustion chamber. If too much fuel is supplied to the combustion chamber, the
turbine section may be damaged by excess heat, the compressor may stall or surge because of back-
pressure from the combustion chambers, or a rich blowout may occur. A rich blowout occurs when
the mixture is too rich to burn. Too little fuel entering the combustion chambers causes a lean
blowout, which occurs when the mixture is too lean to burn.

The usual method of varying the fuel flow to the combustion chamber is via a fuel control unit. Fuel
control units operate under either hydro-pneumatic, hydromechanical or electro‑hydromechanical
control.

Fuel controls

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 Hydromechanical
For many years the majority of fuel control units have been hydromechanical in operation. This
means their operation is controlled both by hydraulic (fuel) and mechanical means to control the fuel
flow to the engine.

Hydro-pneumatic
A hydro-pneumatic fuel control unit uses engine air pressures and mechanical forces to operate its
fuel scheduling mechanisms.

Electro‑hydromechanical
Later model gas turbine engines are controlled by electronic fuel control systems known as
electro‑hydromechanical fuel control units. These systems use computers, Electronic Engine Control
(EEC), that sense inputs to set the hydromechanical section of the fuel control unit that limits the fuel
flow to the engine.

Fuel Flow Control
The fuel control unit (FCU) is an engine-driven fuel metering device. It controls the fuel flow to the
required quantity necessary for:

Easy starting
Acceleration
Deceleration
Stable running at all engine operating conditions.

The FCU maintains a correct combustion zone air-to-fuel mixture ratio of 15:1 by weight
automatically (engine power selection is achieved by a manual throttle). Automatic controls must
prevent the engine from exceeding maximum limitations.

To do this, one or more fuel pumps are used to deliver the fuel to the fuel spray nozzles, which inject it
into the combustion system in the form of an atomised spray.

Because the flow rate must vary according to the amount of air passing through the engine to
maintain a constant selected engine speed or pressure ratio, the controlling devices are fully
automatic with the exception of engine power selection, which is achieved by a manual throttle or
power lever.

A fuel shut-off valve control lever is also used to stop the engine, although in some instances these
two manual controls are combined for single-lever operation.

It is also necessary to have automatic safety controls that prevent the engine gas temperature,
compressor delivery pressure and rotating assembly speed from exceeding their maximum
limitations.

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 The fuel system often provides for ancillary functions, such as oil cooling and the hydraulic control of
various engine control system actuators, for example, compressor airflow control such as bleed
bands, variable stater vanes (VSVs) and variable guide vanes (VGVs).

Control of the gas turbine engine’s power or thrust is affected by regulating the quantity of fuel
injected into the combustion system.

When a higher thrust is required, the throttle is opened and the pressure to the fuel spray nozzles
increases due to the greater fuel flow. This increases the gas temperature, which in turn increases the
acceleration of the gases through the turbine to give a higher engine speed and a correspondingly
greater airflow, consequently producing an increase in engine thrust.

This relationship between the airflow induced through the engine and the fuel supplied is, however,
complicated by changes in the following:

Aircraft altitude
Air temperature
Aircraft speed.

These variables change the density of the air at the engine intake and consequently the mass of air
induced through the engine. A typical change of airflow with altitude is shown in the graph below. To
meet this change in airflow, a similar change in fuel flow must occur; otherwise, the ratio of airflow to
fuel flow changes and increases or decreases the engine speed from that originally selected by the
throttle lever position.

Fuel flow changing with altitude

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 The method of varying the fuel flow to the spray nozzles is by adjusting the output of the HP fuel
pump. The FCU varies the HP fuel pump output by:

Varying piston stroke (piston type pump)
Recirculating excess fuel delivery back to pump inlet (gear type pump).

Pump output is varied through a servo system in response to the following:

Throttle movement
Air temperature and pressure
Rapid acceleration and deceleration
Signals of engine speed, gas temperature and compressor delivery pressure.

A typical FCU takes inputs from sensors on the engine and airframe to adjust and compensate for
changes in operating conditions:

Compressor inlet pressure (Pt2)
Compressor inlet temperature (T2)
Compressor speed (N1, N2 and, in some engines, N3)
Engine burner (combustor) pressure (Pb)
Throttle position
Fuel density (SG – specific gravity).

In modern FADEC engines, fuel density is compensated for automatically. In older engines, fuel type
and therefore density are adjustable on the FCU.

Hydromechanical Fuel Control System
Starting
Prior to being activated, the FCU is in the following conditions:

Fuel shut-off valve closed
Power lever at idle
Governor speeder spring in an expanded condition
Governor flyweights in an underspeed condition
Burner and inlet pressure bellows sensing barometric pressure and the multiplying linkage in
the decrease position
Differential pressure regulating valve closed
Metering valve held off the minimum flow stop by the balanced spring pressures of the
governor and main metering valve.

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 After the start button is pressed, the engine begins to rotate and the flyweights in the governor begin
to open, overcoming initial speeder spring tension and moving the roller cage upwards, thus reducing
the metering valve opening.

The fuel pump pressurises the fuel system until the relief valve pressure in the pump is reached.
When the engine has been accelerated by the starter to a set rpm, or after a certain period, the fuel
shut-off valve is opened. The following are the results of that action:

Fuel flows to the burners, causing a differential pressure across the metering valve. Therefore
the differential pressure regulator senses the difference and begins to regulate the fuel
pressure.
Once combustion commences, the engine begins to accelerate and the burner pressure
increases, causing the burner pressure bellows to move the multiplying linkage to begin
opening the main metering valve through the roller cage.
As the engine accelerates towards idle rpm, the speed governor and pressure bellows begin to
regulate metering valve opening, commencing governed operation at idle speed.

Hydromechanical fuel control starting

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 Governed or Steady Operation
During governed or steady operation, consider that the power lever is set at a certain position and
not changed. After the engine speed is set, the engine is subject to certain operating variables, such as
aircraft speed and altitude, to which it must react.

If an aircraft is increasing speed or descending, it increases inlet ram air pressure and mass airflow.
Alternatively, an aircraft that is climbing and/or slowing decreases inlet air pressure and mass airflow.

The inlet and burner pressure bellows sense these changes and move the multiplying lever in an
appropriate direction to maintain the fuel mixture ratio. At the same time, the engine speed governor
reacts to any speed variations, moving the pilot servo rod valve to return the engine to a steady
governed state.

Hydromechanical fuel control governed or steady state operation

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 Acceleration
Movement of the power lever in an increase direction causes the spring cap to slide down the pilot
servo valve rod and compress the flyweight speeder spring.

In doing so, the spring base pushes down and forces the flyweights in at the top to an underspeed
condition, moving the pilot valve rod downwards.

The pilot servo valve slows the movement of the pilot servo control rod, preventing sudden fuel ratio
changes by using its fluid displaced top to bottom as a restrictor.

When the pilot valve rod moves down, the roller moves down the inclined plane and to the left. As it
moves left, the roller forces the metering valve to the left against its spring, allowing increased fuel
flow to the engine.

As fuel flow increases, the differential pressure valve senses a decreased differential and closes to
maintain the differential. With increased fuel flow, the engine speeds up and drives the fuel control
shaft faster. As the engine speed increases, the burner pressure increases, which expands the burner
pressure bellows that moves the multiplying linkage to the left, further increasing the fuel flow.

The new flyweight force comes to equilibrium with the speeder spring force as the flyweights return
towards an upright position. They are now in position to act at the next speed change.

Hydromechanical fuel control acceleration

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 Deceleration
Movement of the power lever in a decrease direction causes the spring cap to slide up the pilot servo
valve rod and release pressure on the flyweight speeder spring. In doing so, the spring base moves up
and the flyweights move to an overspeed condition, moving the pilot valve rod upwards.

The pilot servo valve slows the movement of the pilot servo control rod, preventing sudden fuel ratio
changes by using its fluid displaced top to bottom as a restrictor.

When the pilot valve rod moves up, the metering valve spring forces the metering valve and the roller
to the right as it moves up the inclined plane, allowing less fuel flow to the engine.

With decreased fuel flow, the differential pressure valve senses the increased differential across the
metering valve and opens to maintain the differential. The engine slows and drives the fuel control
shaft slower. This slowing of the engine decreases the burner pressure, which through the bellows
moves the multiplying linkage to the right, further decreasing the fuel flow.

As the new flyweight force comes into equilibrium with the speeder spring force, the flyweights
return towards an upright position.

They are now in position to act at the next speed change.

Hydromechanical fuel control deceleration

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 Shutdown
Prior to shutdown, the engine must be allowed to stabilise at idle for a period to ensure a gradual
cooling of the turbine and scavenging of propeller control oil in turbo propeller engines. On a
simplified fuel control unit, shutdown occurs according to the following procedure:

With the engine at idle governed speed, the fuel shut-off valve is closed.
When the shut-off valve is closed, there is no fuel flow to give a differential fuel pressure, thus
closing the differential pressure regulating valve, causing the fuel pump pressure relief valve to
control maximum fuel pressure.

Once combustion ceases, the engine speed begins to decrease, sending the governor into an
underspeed condition. At the same time, the burner pressure decreases, moving the multiplying
linkage to close the metering valve.

Hydromechanical fuel control shut down

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 Hydro-Pneumatic Fuel Control
Hydro-pneumatic fuel control units rely heavily on compressor discharge pressures to maintain the
correct air-fuel ratio. A basic system is shown in the illustration below and provides:

Rpm control
Acceleration and deceleration control
Minimum and maximum flow control.

It has inputs of:

Rpm command (power lever)
Actual rpm
Inlet temperature
Compressor outlet pressure.

Operation of Control
Unmetered fuel pressure is supplied to the FCU by the fuel pump.
The pressure regulator maintains a constant pressure drop across the metering head, ensuring
constant flow.
Excess fuel is bypassed back to the pump inlet.
The air section is operated by compressor discharge air (Pc).
When modified, this air becomes Px and Py, which act to position the metering valve.

Tt2 Sensor
The Tt2 sensors (bimetallic discs) are a typical means of sensing inlet duct temperature. They control
a metering device, which affects pressures Px and Py. This reduces the acceleration rate under hot
conditions, preventing excessive turbine temperature and the risk of compressor stall or surge.

Power Lever Position

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 When the Power Lever Is Advanced:

The flyweights droop in, the speeder spring force being greater than the flyweight force.
The governor valve closes off the Py bleed.
Px and Py pressures equalise on the surface of the governor.
Px air contracts the acceleration bellows and the governor bellows rod is forced downwards.
The diaphragm allows this movement.
The main metering valve moves to open.
The flyweights move outwards as engine speed increases and the governor valve opens to
bleed Py air.
Reduced Py value allows the governor bellows and rod to move up to a new stabilised position.
The metering valve resumes a new position through the action of the torque rod assembly.

When the Power Lever Is Retarded:

The flyweights move outwards, speeder spring force being less than flyweight force due to high
engine rpm.
The governor valve opens, dumping Py air
Px air expands the governor and deceleration bellows to its stop.
The governor rod also moves up and the main metering valve moves towards close.
Px air decreases with engine speed decrease, but the acceleration bellows holds the governor
rod up.
As engine speed slows, the flyweights move back in, closing the Py bleed at the governor valve
and the backup valve.
The deceleration bellows moves downwards. The metering valve moves slightly open to
produce a stabilised fuel flow.

The fuel pump supplies more fuel than is required and the bypass valve returns excess back to the
pump inlet. The bypass valve incorporates a pressure regulator to ensure the pressure differential
across the metering valve is unaffected by movement of the metering valve. Therefore, fuel flow is
controlled only by metering valve position.

The rpm is the primary control parameter, and compressor discharge pressure and inlet air
temperature are secondary parameters. Together they control the metering valve via a servo bellows
assembly.

"On-speed" rpm is maintained by the governor in conjunction with the governor bellows pressure Py.
The flyweights of the governor respond to an rpm change by increasing or decreasing the opening of
the governor valve, which in turn alters Py and thus the extension of the governor bellows. The
bellows assembly opens the metering valve slightly when there is a fall in rpm and closes it slightly
when there is a rise in rpm.

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 Hydro-pneumatic fuel control system

Unlike a hydromechanical FCU, which has a mechanical linkage between the power lever and the fuel
metering valve, the hydro-pneumatic FCU has none and utilises a pneumatic coupling between the
two.

A hydro-pneumatic fuel control differs from a hydromechanical fuel control in that the former uses a
pneumatic computing section that determines fuel flow rates based on the position of the power
lever, N1 rpm, compressor discharge air (Px and Py), and outside air pressure and temperature.

In the simplified schematic above, the N1 governor is connected to the pneumatic computing section,
and it controls compressor turbine speed and senses compressor discharge air. Therefore, functions
of the governors and pneumatic computing section are interdependent.

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 Governor Section
For acceleration, an input force from the power lever increases compression on the speeder spring.
This moves the flyweights of the governor inwards and closes the governor valve. With the governor
valve closed, acceleration control pressure (Px) and governor pressure (Py) both increase with
compressor pressure (Pc), causing the bellows assembly to gradually open the metering valve. System
design ensures that increasing fuel flow matches increasing airflow through the engine and that
acceleration takes place without risk of stall or surge. When the desired rpm is reached, the governor
again maintains on-speed rpm.

During deceleration, the reverse sequence occurs. The rate of deceleration is controlled by the
deceleration bellows, which ensures smooth deceleration without the risk of flameout.

The computing section automatically compensates for altitude by utilising an evacuated bellows to
reset the metering valve position.

Changes in ambient temperature are compensated by a sensor that allows compressor discharge
pressure to be bled to ambient.

Acceleration is controlled by the evacuated bellows, which repositions the fuel metering valve as Px
changes.

Deceleration is controlled by the deceleration bellows, which repositions the fuel metering valve as
Py changes.

Flow Control
Flow control units regulate the fuel system by bypassing excess unwanted fuel back to the inlet side
of the fuel pump.

Electro‑Hydromechanical Control System
Electro‑hydromechanical fuel control systems are sometimes referred to as electronic fuel controls
because the majority of the system is made up of electronic circuits. Because of the need to precisely
control many functions in the operation of modern high-bypass turbo fan engines, electronic engine
control systems have been developed. These systems prolong engine life, save fuel, improve
reliability, and reduce crew workload and maintenance costs. Two types of EEC systems in use are:

Supervisory Electronic Engine Control
Full Authority Digital Engine Control (FADEC).

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 Supervisory Electronic Engine Control System
The supervisory EEC is a control that works with a proven hydromechanical fuel control. It includes a
computer that receives information regarding various engine operating parameters and adjusts a
standard hydromechanical FCU to obtain the most effective engine operation for the selected power
setting.

As can be seen in the diagram, the control amplifier (Supervisory EEC) receives a signal from turbine
gas temperature (EGT) and two compressor speed signals (N1 and N2).

The hydromechanical unit responds to EEC commands and actually performs the functions necessary
for engine operation and protection. The hydromechanical element controls the basic operation of
the engine, including starting, acceleration, deceleration and shutdown. The EEC, acting in a
supervisory capacity, modulates the engine fuel flow to maintain the designated thrust. The pilot
simply moves the throttle lever to a desired thrust setting position, such as full take-off thrust or
maximum climb. The control adjusts engine pressure ratio (EPR) as required to maintain the thrust
rating, compensating for changes in flight and environmental conditions.

As the engine nears full power, the electronic circuit starts to function as a fuel-limiting device to
control maximum EGT and N1 and N2 compressor speeds.

If a problem develops, controls automatically revert to the hydromechanical system with no
discontinuity in thrust. A warning signal is displayed in the cockpit, but no immediate action is
required by the pilot. The pilot can also revert to the hydromechanical control at any time. Although
the EEC uses aircraft electrical power for some of its functions, electric power for its basic operation
is supplied by a separate engine-driven permanent magnet alternator (PMA).

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 © Aviation Australia
Supervisory electronic engine control systems

Full Authority Digital Engine Control
Modern large high-bypass turbofan engines use the Full Authority Digital Engine Control (FADEC)
system. The EEC is the primary component of the FADEC engine fuel control system. The EEC is a
dual-channel computer that controls engine operation. It is normally mounted on the fan casing and
cooling is either by natural fan case cooling air or directly by a dedicated fan air duct. A true FADEC
system has no hydromechanical fuel control backup system.

The system uses electronic sensors that feed engine parameter information into the EEC. The EEC
gathers the needed information to determine the amount of fuel flow and transmits it to the fuel
metering valve. The fuel metering valve simply reacts to the commands from the EEC. The EEC is the
computing section of the fuel delivery system, and the metering valve meters the fuel flow.

Power for the EEC comes from the aircraft electrical system or the PMA. When the engine is running,
the PMA supplies power directly to the EEC. The PMA has a dual coil, so each channel is supplied
power independently.

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 The electronic computer may have many inputs and outputs:

EPR Engine pressure ratio
N1 Fan speed
N2 Intermediate-pressure compressor speed
N3 High-pressure compressor speed
Tt2 Inlet total temperature
Tt8 High-pressure turbine inlet temperature
Pt2 Inlet total pressure
28V DC inlet power
PMA Permanent magnet alternator
PLA Power lever angle
VIGV An inlet guide vane angle
Ps6 High-pressure compressor discharge static pressure
Wf Fuel flow
ACC Active clearance control (compressor and turbine blade cooling air supplied by fan air).

The FADEC system performs all functions necessary to operate a turbofan engine efficiently and
safely during all operating conditions from start-up to shutdown.

Benefits of using electronic engine control are reduced crew workload, increased reliability and
reduced fuel consumption.

Flight crew workload is decreased because the pilot need only set target thrust and monitor the EPR
and/or N1 indication. The EEC automatically accelerates or decelerates the engine to the required
setting without the pilot having to monitor the engine gauges. Reduced fuel consumption is attained
because the EEC controls the engine operating parameters to attain maximum thrust for the amount
of fuel consumed. Also, optimising airflow control allows the engine to work nearer the surge line,
thus increasing thrust while reducing the chance of surge or stall.

To provide a high degree of reliability, FADEC systems are designed with several redundant and
dedicated subsystems. An EEC consists of two redundant channels (A and B), housed in the same unit,
that send and receive data. Each channel consists of its own processor, power supply (PMA), memory,
sensors and actuators. In addition, any one channel can take information from the other channel. This
way, the EEC can still operate even if several faults exist.

If both channels are serviceable, the active channel alternates with each engine start. The other
channel is in standby mode. Should both channels fail, there is a second backup and systems vary
depending on engine manufacturer. For example, in one system the actuators are spring-loaded to a
failsafe position so the fuel flow goes to maintain engine flight idle. In another system, the EEC goes
into a Soft Reversionary mode using the last known ambient pressure signal, or into a Hard
Reversionary mode which uses a fixed corner-point ambient temperature for the engine.

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 The EEC also controls several other subsystems of the engine through torque motors and solenoids,
such as fuel and air oil coolers, bleed valves, variable stator vanes, turbine cooling air valves and the
turbine case cooling system. The EEC is provided with feedback via valves and actuators fitted with
dual sensors.

The hydromechanical unit provides an interface between the EEC signal and fuel flow. It is achieved
by an electrical hydraulic servo valve (EHSV) or torque motors actuating a fuel metering valve (FMV),
thus controlling fuel supply to the nozzles.

The Engine Rating Plug selects the proper software in the EEC for the thrust rating of the engine. The
plug attaches to the engine fan case with a lanyard. When removing the EEC, the plug remains with
the engine; it is not interchangeable.

Engine rating plug

Engine trimming is eliminated by the use of full authority EEC, as the engine fuel control system has
fault sensing, self-testing and correcting features designed into it, greatly increasing its reliability and
maintainability.

As shown in the diagram below, the full authority EEC receives data from various areas. It then
analyses the data and sends commands to position the actuators and solenoids and schedule fuel flow
through the hydromechanical section of the FCU.

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 Electronic engine control interface

Factors Controlling FCU Performance
The FCU must sense the various operating and environmental parameters to supply engine fuel in the
correct quantities. Parameters that directly affect the FCU are:

Power lever angle
Rpm
Air temperature
Air pressure
Burner pressure
Fuel density.

Power Lever Angle
The power lever angle is the pilot’s main control over the engine. The power lever angle schedules the
fuel required to the engine without taking into account the other operating parameters.

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 Rpm
To be able to produce the varying powers required, the engine must be able to operate at different
speeds. Equipment is included to sense rpm so that the FCU can provide the appropriate fuel flow for
the rpm at which the engine is operating.

Air Pressure
For a turbine engine, with an increase in altitude, air pressure decreases and the weight of the total
air mass that flows through the engine at a given rpm reduces. Therefore an increase in altitude
reduces thrust for a given throttle setting.

Air Temperature
Air temperature has a direct relationship with air density, i.e. an increase in temperature leads to a
decrease in density. Therefore, for a turbine engine, an increase in air temperature reduces the
weight of the total air mass that flows through the engine at a given rpm, requiring the FCU to reduce
the fuel flow to maintain the combustion process. As can be seen in the graph below, temperature
affects engine performance.

Air temperature has an effect on the engine performance

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 Burner Pressure
Static pressure in the combustion chamber is a useful measure of mass airflow. If the mass airflow is
known, the air-fuel ratio can be more carefully controlled. As aircraft use bleed air from the engine
compressor to provide various services, it is imperative that the burner pressure is known to
accurately regulate fuel when these services are being used.

Combustion chamber pressure and inlet pressure acting through bellows and lever assemblies can
accurately control the fuel being introduced into the engine to control the air-fuel mixture.

Fuel Density
As the different types of fuels that may be used in gas turbine engines have different densities or
specific gravities, the fuel control unit needs a method of adjusting for the various flows that occur if
different fuels are used.

Variation of the fuel differential pressure valve spring tension can be used to change the fuel flow to
accommodate for different fuels’ specific gravities.

Specific gravity adjustment, shown below, is a means of resetting the tension on the differential
pressure regulator valve spring within the fuel control when an alternate fuel is used. Modern aircraft
automatically measure the density of the fuel and input this information into the EEC.

Fuel control fuel specific gravity adjustment

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 Fuel System Components II
High-Pressure Shut-Off Valve
The HP shut-off cock is a valve mounted in the FCU/hydromechanical unit and is used to give a
definite shut-off of the fuel line from the FCU/hydromechanical unit to the fuel burner nozzles.

The HP cock may be connected directly to the engine power lever or to an independent lever/switch.

However, on turbo-propeller aircraft, it is normally connected in conjunction with the propeller
feather control lever to give a movement through gates of engine run (HP cock open) to engine stop
(HP cock closed), then propeller feather (HP cock closed).

Fuel Flow Transmitter
Fuel flow meters are used in fuel systems to show the amount of fuel consumed per hour by the
engine, thus allowing the pilot or a Fuel Management Computer to accurately calculate the available
flight time remaining. As fuel flows through the meter, it spins a small turbine wheel, and a digital
circuit reads the number of revolutions in a specified period and converts this to a fuel flow rate.

Fuel flow transmitter

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 Pressurising and Dump Valve
A fuel pressurising and dump valve is normally required on engines using duplex type fuel nozzles. It
divides the fuel flow into primary and main manifolds and drains fuel from these manifolds on
shutdown.

Fuel pressurising and dump valve

Pressurising Valve
The fuel pressurising valve controls the fuel flows required for all engine operation. For starting and
idle, all fuel passes through the primary manifold. As the throttle is advanced above idle, fuel pressure
increases, and at a preset pressure, the pressurising valve begins to open the main manifold. Fuel is
continuing to flow through the primary manifold.

Dump Valve
The dump valve gives the capability to ‘dump’ or drain fuel from the fuel manifolds after shutdown.
Manifold dumping is a procedure which sharply cuts off combustion and prevents fuel boiling, or
after-burning, as a result of residual engine heat. This boiling tends to leave solid deposits which
could clog finely calibrated passageways.

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 Operation
The construction and operation of pressurisation and dump valves varies with different
manufacturers. However, the following is a description of the operation of a typical pressurisation
and dump valve as shown in the illustration below.

When the power lever is opened, a pressure signal from the FCU moves the dump valve against the
spring pressure, closing the dump port and opening the passageway to the manifolds. Metered fuel
pressure builds at the inlet check valve until the spring tension is overcome and fuel is allowed to flow
through the filter to the primary manifold. At a speed slightly above idle, the fuel pressure is sufficient
to overcome the pressurising valve spring force, and fuel also flows to the main manifold.

On shutdown, when the fuel lever is moved to OFF, the pressure signal holding the dump port closed
and the fuel passage open is lost. Spring pressure closes the fuel passage and opens the manifolds to
the fuel dump, or return, line.

Pressuring and dump valve operation

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 Drain Valves
The combustor drain valve shown below is a mechanical device located in the low point of a
combustion case. It is closed by gas pressure within the combustor during engine operation and is
opened by spring pressure when the engine is not in operation. This valve prevents fuel accumulation
in the combustor.

Fuel accumulates in the bottom of the lower combustion chamber following shutdown or a false start.
When the air pressure in the combustion chamber reduces to near atmospheric, the valve opens and
allows the accumulated fuel to drain away. It is imperative that this valve is in good working order;
otherwise, a hot start during the next start attempt or an after-fire on shutdown is likely to occur.

Combustor drain valve

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 Drain Tank
Dump fuel, in years past, was allowed to spill onto the ground or be siphoned from a drain tank in
flight. Current international regulations, however, prohibit this form of environmental pollution, and
now the drain tank fuel must be captured, perhaps by hand-draining.

To prevent hand-draining, several types of recycling systems have recently been developed. One such
system returns fuel to the aircraft fuel supply. Another pushes fuel, which formerly would have been
dumped, out of the fuel nozzles by introducing bleed air into the dump port. This prolongs
combustion slightly until fuel starvation occurs. In the system shown below, a full tank causes a float
valve to actuate and drain the tank via an educator type flow system.

Drain tank

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 Fuel Nozzles
Fuel Nozzles
Fuel nozzles are the terminating points of the fuel system. They are located in the inlet of the
combustion liner. Some mix air with fuel in correct proportions to atomise or vaporise the fuel. Air
shrouds direct cooling air over the spray nozzle to aid atomisation. The highly polished nozzle
delivers a precisely patterned, highly atomised spray. Fuel cannot be burned in a liquid state. It must
first be mixed with air in correct proportions by atomisation or vaporisation.

The pressure-atomising type of nozzle receives fuel under high pressure from a manifold and delivers
it to the combustor in a highly atomised, precisely patterned spray. The cone-shaped, atomised spray
pattern provides a large fuel surface area of very fine fuel droplets. This optimises fuel-air mixing and
ensures the highest heat release from the fuel. The most desirable flame pattern occurs at higher
compressor pressure ratios. Consequently, during starting and other off-design speeds, the lack of
compression allows the flame length to increase.

Various stages of fuel atomisation

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 If the spray pattern is also slightly distorted, the flame, rather than being held centred in the liner, can
touch the liner surface and cause a hot spot or even burn through. Another problem that distorts the
spray pattern is contaminant particles within the nozzle or carbon build-up outside the nozzle orifice.
This can cause hot streaking, which is an un-atomised stream of fuel which forms and tends to cut
through the cooling air blanket and impinge on the liner or on downstream components such as the
turbine nozzle.

Simplex Fuel Nozzles
The simplex design is basically a small, round orifice which provides a single spray pattern. It
incorporates an internally fluted spin chamber to impart a swirling motion and reduce axial velocity
of the fuel to provide atomisation as it exits the orifice. The internal check valve in the simplex nozzle
is there to prevent dribbling of fuel from the fuel manifold into the combustor after shutdown.

Simplex fuel nozzle

The simplex fuel nozzle was used in early jet engines and is still used in modern small engines, such as
those used as APUs. This fuel nozzle gives good atomisation at the higher fuel flows, that is, at the
higher burner pressures, but was unsatisfactory at the low pressures required at low engine speeds
and especially at high altitudes.

Because simplex nozzles are effective only at high pressure/high rpm, they are commonly used in
constant speed applications, such as in APUs.

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 Duplex Fuel Nozzles
Duplex fuel nozzles have two separate fuel flows:

Primary flow
Secondary flow (also known as main flow).

There are two categories of duplex fuel nozzles:

Single line
Dual line.

The duplex burner requires a primary and secondary fuel manifold and has two independent orifices,
one much smaller than the other. Initial fuel flow is through the smaller orifice (primary); the larger
orifice (secondary) opens to discharge fuel at higher fuel flows.

Primary flow has a wide spray pattern used for engine start-up to idle. Secondary fuel flows with
primary above idle. Combined primary and secondary flow has a narrower pattern. The narrow
pattern ensures that the flame will not impinge on the combustion liner.

Duplex nozzle fuel spray patterns

A duplex nozzle is able to give effective atomisation over a wider flow range than the simplex spray
nozzle.

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 Single-Line Duplex Nozzles
The single-line duplex type receives its fuel at one inlet port and requires a flow divider to distribute
fuel through two spray orifices. The round centre orifice, called the primary fuel, sprays at a wide
angle during engine start and acceleration to idle.

The annular outer orifice, referred to as secondary fuel, opens at a preset fuel pressure to flow along
with the primary fuel. Fuel of much higher volume and pressure flowing from this outer orifice causes
the spray pattern to narrow so that the fuel will not impinge on the combustion liner at higher power
settings. Secondary fuel flows with primary from idle to full power.

Single line duplex fuel nozzle

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 Dual-Line Duplex Nozzles
A second type of duplex nozzle, called a dual-line duplex type, is quite similar to the single-line except
that it contains no flow divider check valve to separate primary and secondary fuel.

The check valve in this system is located in the Pressurising and Dump Valve and is labelled
‘Pressurising Valve’. The pressurising valve acts as a single, main flow divider for all of the fuel nozzles,
whereas in the single-line duplex nozzle, each has its own flow divider in the form of its check valve.

Only primary fuel is supplied for starting and low flow conditions. This fuel comes from a flow divider.
Fuel sprays out from the centre primary orifice in a wide spray. The air shroud directs cooling air over
the spray nozzle. Cooling air from compressor discharge also aids atomisation of the fuel. Fuel is
discharged from both primary and secondary orifices for high speed conditions.

Dual-line duplex fuel nozzles

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 Air Blast Fuel Nozzles
The air blast fuel nozzle is a newer design and is being more widely used in various-sized engines
because it enhances the atomisation process and produces finer fuel droplets. This nozzle is said to be
more effective during starting, when low fuel pressure causes atomisation problems. By using high-
velocity airflow, air blast nozzles more completely atomise the fuel than can be accomplished with
fuel under pressure alone. Some nozzle designs completely vaporise the fuel by the high-velocity air
as it enters the combustion chamber. This nozzle also has an advantage in that it utilises a lower
system working pressure than the basic atomising types of nozzles.

Air blast fuel nozzles

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 Vaporising Fuel Nozzles
The vaporising fuel nozzle, shown below, connects to a fuel manifold in an arrangement similar to the
atomising type. Instead of delivering the fuel directly into the primary air of the combustor, as the
atomising type does, the vaporising tube premixes the primary air and fuel. Combustor heat
surrounding the nozzle causes the mixture to vaporise before exiting into the combustor flame zone.

There are two types of vaporiser nozzle:

Tee-shaped – dual outlets
Cane-shaped – single outlet.

Vaporising fuel nozzle

Whereas the atomiser nozzle discharges in the downstream direction, the vaporiser discharges in the
upstream direction and the mixture then makes a 180° turn to move downstream. This arrangement
provides a slow-moving, fine spray over a wide range of fuel flows and is said to produce more stable
combustion in some engines than can be achieved by atomising nozzles, especially at low revolutions
per minute. Some vaporisers have only one outlet and are referred to as cane-shaped vaporisers.

Because vaporising nozzles do not provide an effective spray pattern for starting, there can be an
additional set of small atomising type spray nozzles which spray into the combustor during starting.
After light-off, start fuel is terminated on spool-up to idle. This system is generally referred to as a
primer or starting fuel system.

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 Vaporising fuel nozzle fuel vapour flow

Relevant Youtube link: Fuel Systems 1 (Video)

Relevant Youtube link: Fuel Systems 2 (Video)

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 Air Systems (15.12)
Learning Objectives
15.12.1 Describe the main operational features of engine air systems designed for engine
internal cooling (Level 2).
15.12.2 Describe the main operational features of engine air systems designed for engine
internal sealing (Level 2).
15.12.3 Describe the main operational features of engine air systems designed for engine
external air services such as customer bleed (Level 2).
15.12.4 Describe the main operational features of engine air systems designed for engine
anti-ice (Level 2).

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 Engine Internal Cooling Systems
Engine Internal Air/Cooling
Internal Air System
The engine internal air system is defined as the airflows which do not directly contribute to engine
thrust. The system has several important functions to perform for safe and efficient engine operation.
These functions include internal engine and accessory unit cooling, bearing chamber sealing,
prevention of hot gas ingestion into the turbine disc cavities, control of bearing axial loads, control of
turbine blade tip clearances and engine anti-icing.

Internal Cooling System
The purpose of the engine internal cooling system is to ensure that certain parts of the engine do not
absorb heat to the extent that it is detrimental to their safe operation. The main areas that require
internal cooling air are the combustors and the turbines.

Rolls Royce SPEY / F28 Engine Diagram

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 Combustor Cooling
You may recall from Gas Turbine Principles that of the total airflow introduced into the combustor,
only about 20%–30% was used for combustion. The remaining 70%–80% was bypassed around the
snout area. In this example, of the air that is bypassed, 40% is used for flame stabilisation and dilution.
This allows us to pass the remaining 40% of the airflow around the flame tube for cooling to ensure
that its safe operating temperature is not exceeded.

Combustor Cooling Example

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 Turbine Cooling
High thermal efficiency depends on high turbine entry temperatures, and the maximum turbine entry
temperature is limited by the ability of the nozzle guide vanes and the turbine blades and discs to
withstand the hostile conditions encountered. Continuous cooling of these components allows the
temperature of the environment in which they operate to exceed the melting point of the component
materials without affecting their integrity. Conducted heat transferred from the turbine blades into
the discs means the discs must also be cooled so that thermal fatigue and uncontrolled expansion
rates do not occur.

Blade and Nozzle Guide Vane Cooling
Turbine vane and blade life depends not only on the shape of the blades, but on the methods used to
cool them. Therefore, the design of the internal air passages is important. The methods used to cool
the components has undergone steady improvement over the history of the gas turbine engine.
Single-pass internal cooling, as used during the 1960s, was of great practical value, but development
has led to multi‑pass internal air film cooling of both vanes and blades and impingement cooling of
vanes and blades with external air film cooling.

Turbine Blade Cooling Designs

The ‘pre-swirl nozzles’, as illustrated below, reduce the temperature and pressure of the cooling air
fed into the disc for blade cooling. The nozzles also impart a swirl velocity to the air to assist efficient
entry of the air into the rotating cooling passages.

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 Pre-Swirl Nozzle Cooling System

Hot Gas Ingestion
It is important to prevent the ingestion of hot mainstream gas into the turbine disc cavities as this
causes overheating and results in unwanted thermal expansion and fatigue.

Prevention of hot gas ingestion is achieved by continuously supplying the required quantity of cooling
air into the disc cavities to oppose the inward flow of hot gas. The flow and pressure of the cooling air
are controlled by the interstage seals.

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 Turbine Disc Cooling
Cooling air for the turbine discs enters the annular spaces between the discs and flows outwards over
the disc faces. Airflow over the faces is controlled by the interstage seals. When the air has completed
its task, it is discharged into the main gas stream. The diagram below illustrates the flow of cooling air
through the turbine.

Turbine Disk Cooling

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 External Cooling
The engine bay or pod is usually cooled and ventilated by atmospheric air being passed around the
engine and then vented overboard. An important function of the airflow is to purge the nacelle of any
flammable vapours. Keeping the airflow to a minimum correspondingly minimises engine drag. A
typical external cooling system is depicted below.

External Cooling System

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 Engine Internal Bearing Sealing
Bearing Sealing
The purpose of the seal pressurisation system, or bearing sealing, is to supply air to the seals that
require it at the pressure that they need to prevent leakage of oil or air from the various bearing
chambers. It also controls the cooling airflow to prevent the ingress of mainstream gases into the
turbine disc cavities.

The choice of sealing method depends on the surrounding temperatures and pressures, wearability,
heat generation, weight, space available, etc. The types of seals used are:

Labyrinth seal
Carbon seal
Ring seal
Hydraulic seal
Brush seal.

Air for pressurising these seals is supplied from various stages of the compressor. Air is tapped from
the compressor by air transfer ports in the disc or drum, and travels down the inside of the shaft to
the turbine. The compressor stage that the air is tapped from determines the air pressure to the seal.

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 Labyrinth Seals
A labyrinth seal consists of a finned rotating member with a static bore which is lined with a soft
abradable material or a high-temperature honeycomb structure. Initially, the fins rub on the liner and
cut into it to give minimal clearance between the two. Across each fin in the seal, there is a pressure
drop which gives a restricted flow from one side of the seal to the other.

This seal is used for sealing bearing chambers and prevents oil leakage by providing airflow from
outside the chamber to the inside. This positive pressure in the chamber also assists the scavenge oil
system. The three types of labyrinth seals, shown below, are:

Fluid and abradable lined seal
Continuous groove interstage air seal
Thread type oil seal.

Fluid and Abradable Lined Seal

Continuous Groove Interstage Air Seal

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 Thread type oil seal

Carbon Seals
Carbon seals consist of a static ring of carbon which constantly rubs against a collar on a rotating
shaft. They rely on a high degree of contact and do not allow oil or air leakage. Any heat generated by
friction is quickly dissipated by the oil system. Due to their construction, and carbon’s heat resistance,
carbon seals can be used in ‘hot areas’ of the engine, i.e. the turbine.

Aviation Australia
Carbon seal

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 Ring Seals
A ring seal comprises a metal ring housed in a close-fitting groove in the static housing. The normal
running clearance between the ring and the rotating shaft is smaller than that obtained by the
labyrinth seal. This clearance is obtained because the ring is allowed to move in its housing whenever
the shaft comes into contact with it.

Ring seals are used for bearing chamber sealing, except in areas of extreme heat where oil
degradation due to the heat could cause the ring to seize within its housing.

Aviation Australia
Ring seal

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 Hydraulic Seals
Hydraulic seals are often used between two rotating members to seal a bearing chamber, but unlike a
labyrinth or ring seal, they do not allow a controlled flow of air across the seal. Hydraulic seals are
formed by a seal fin immersed in an annulus of oil which has been created by centrifugal force. Any air
pressure differential, inside and outside the bearing chamber, is compensated by a difference in oil
level on either side of the fin.

Hydraulic seal

Brush Seals
Brush seals comprise of a static ring of fine wire bristles. They are in continuous contact with a
rotating shaft, rubbing against a hard ceramic coating. This type of seal has the advantage of
withstanding radial rubs without increased leakage.

Brush seal internal diagram

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 Brush seal physical component

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 Control of Bearing Loads
Engine shafts experience varying axial gas loads which act forwards on the compressor and
rearwards on the turbine. The shaft between them is therefore always under tension, and the
difference between the loads is carried by the location bearing, which is fixed in a static casing. The
internal air pressure acts on a fixed-diameter pressure balance seal to ensure the location bearing is
adequately loaded throughout the engine thrust range.

The air balance chamber aids the compressor thrust bearing (No. 2) in combating high gas-path
pressures, which try to push the compressor forwards. The balance chamber and thrust bearings help
restrain the compressor against the axial pushing force.

Some engines do not need an air balance chamber because the opposite (rearward) thrust load, at the
turbine, adequately cancels out the forward pushing loads on the compressor.

Control of Bearing Loads

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 Engine External Air Systems
Customer Bleed Air
Customer bleed air is air that is tapped from a turbine engine compressor and used for such airframe
functions as anti-icing, air conditioning and pressurisation of the cabin, and other services.

Depending on engine configuration, bleed air is tapped from the compressors at different locations to
suit the aircraft requirements and maintain optimal engine efficiency. Low-pressure (LP) bleed air is
taken from the early stages of the compressor at high rpm, while high-pressure (HP) bleed air is taken
from the later stages of the compressor at low rpm.

Rolls Royce SPEY Bleed Air Example

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 Pre-cooler
To reduce the temperature of the hot engine bleed air going to aircraft services, it passes through a
pre-cooler. As a cooling medium, cold airflow from the engine’s fan area is ducted and controlled
through a heat exchanger. The fan air exhausts overboard after passing through the heat exchanger. A
fan air temperature sensor controls the Fan Air Modulating Valve position, allowing more or less
cooling airflow. The bleed air temperature is cooled to 200–250 °C, depending on engine type.

Bleed Air Pre-cooler Installation

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 Bleed air pre-cooler at low power

Bleed air pre-cooler at high power

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 Bleed Air Pre-cooler With Air Supply Overheat

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 Pressure-Regulating Valves
A simplified schematic of a bleed air Pressure-Regulating and Shut-Off Valve is shown below. These
valves have many uses in both engine and airframe pneumatic systems. They utilise:

A solenoid valve to signal ON or OFF
A comparison of upstream and downstream air pressures to modulate a butterfly valve to
deliver a constant pressure to the aircraft system.

Bleed air Pressure Regulating and Shut-off Valve (PRSOV)

Engine Ice Formation
Ice can form on aircraft surfaces and engines when the Outside Air Temperature (OAT) on the ground
or the Total Air Temperature (TAT) in flight is 10 °C or below and visible moisture in any form is
present. It can also occur when operating the engine at high speeds during ground runs or where
surface standing water is being ingested.

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 Visible moisture can be in the form of:

Clouds
Fog with visibility of 1 mi or less
Rain
Snow
Sleet
Ice crystals.

Anti-icing
The pneumatic anti‑ice system provides surface heating of the engine and/or power plant where ice is
likely to form. Protection of the rotor blades is rarely necessary due to their centrifugal action, but
the first-stage inlet guide vanes and nose cone may require protection, as may the inlet cowling. The
hot air for the anti-icing system is usually taken from the HP compressor. It is ducted through
pressure-regulating valves to the parts requiring anti-icing. Spent air from the nose cowl anti-icing
may be exhausted into the intake or vented overboard.

The system illustrated below, a typical anti-icing system, contains two electric motors that drive air
shut-off valves. The air shut-off valves are both opened at the same time when the cockpit switch is
actuated. Engine anti-icing is required to eliminate the formation of ice in the intake, which would
effectively change the airflow characteristics of the intake.

Engine Anti-icing System

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 When the anti‑ice switch is actuated, a light illuminates in the cockpit and a slight rise in exhaust gas
temperature and rpm are noticed.

Engine Anti-icing Schematic

When the anti-ice valves are opened, bimetallic spring coils inside the air regulator valves control the
amount of airflow according to the temperature of the air.

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 Anti-ice Bimetallic Regulator Valve

The bimetallic spring controls the airflow in the following manner:

As the temperature of the air passing through the valves increases, the bimetallic spring, which is
attached to a valve disc, expands. This expansion is translated into rotary movement of the valve disc.
Rotating the valve disc partially covers the ports through the stator plate in the valve and reduces the
airflow. The airflow through the valve needs to be controlled because air that is too hot may
adversely affect the material strength of the inlet components and engine performance as the
anti‑ice air is ingested into the engine.

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 Bleed Air System
Construction
Due to the high pressures, temperatures and moisture content involved with engine bleed air, the
ducts, or plumbing, are usually constructed from stainless steel to resist fatigue and corrosion. To
prevent the hot ducts from transmitting heat through the duct walls to the aircraft structure, they are
covered with an insulating material that varies depending on the manufacturer. Flexible elbows are
also incorporated into the system to allow the ducting to be bent and retain flexibility.

Flexible Elbow

Flexible Elbow

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 To join all components, including plumbing, a crush type seal is placed between the mating faces of
each component before the joint is clamped with a V-band type clamp, which brings the joints tightly
together. These joints are covered with an insulation blanket which is lock-wired around the bare
metal, effectively insulating it.

Bleed Air Duct, Seal and “V” Clamp

Temperature Compensators
Due to the length of the ducting in larger aircraft and the wide temperature variation to which the
ducts are subjected, thermal expansion could cause problems. To relieve this problem, expansion-
absorbing units called temperature compensators are used. A typical temperature compensator is
shown below. The compensators provide a slip joint to allow the ducts to ‘grow’.

Temperature Compensator

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 Check Valves
One-way check valves are incorporated in the system to control airflow from the pressure sources to
the various pneumatic components and/or systems. These valves could be located in the ducts from
the:

APU
External air source connection.

They prevent the loss of manifold pressure into the APU or out the ground air connection when these
sources are not in use.

Check Valve Diagram

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 Shut-Off Valves
Shut-off valves are usually located aft of the firewall or in the pylon on which the engine is mounted.
They are also located in the ducting leading to the starter system if a pneumatic starter is used. They
control airflow, in the case of the main engine shut-off valve, to prevent or allow airflow into or from
the engine, or in the case of the starter valve, to allow air to flow to the starter for engine start, then
cease when the starter is no longer required.

These valves are normally motor-driven butterfly valves and are electrically actuated from the
cockpit. The illustration below shows the valves in the open and closed positions.