GTEquiz3mod15.21 Engine Monitoring & Ground Operations PDF

Summary

This document provides information on procedures, learning objectives, and safety aspects related to engine monitoring and ground operations for aircraft. It covers a variety of topics such as pre-start procedures, maintenance runs, safety considerations, and damage inspections. The document focuses on practical knowledge and application in the aviation industry.

Full Transcript

Engine Monitoring and Ground Operations
(15.21)
Learning Objectives
15.21.1 Provide a detailed description of procedures for starting and ground run-up (Level
3).
15.21.2 Interpret engine and ambient parameters to calculate engine power output (Level
3).
15.21.3 Provide a detailed explanation of trend monitoring (including oil analysis,
vibration and borescope) (Level 3).
15.21.4 Provide a detailed description of the inspection of a gas turbine engine and
components to criteria, tolerances and data speci ed by the engine manufacturer (Level 3).
15.21.5 Describe compressor washing and cleaning (Level 3).
15.21.6 Describe foreign object damage (Level 3).

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 Maintenance Engine Runs
Purpose of Maintenance Engine Runs
Maintenance engine runs are carried out for a variety of reasons, including:

Testing following repair or overhaul – carried out in a test cell
Fault detection and correction – con rms a reported fault, diagnose the fault, con rm the
recti cation and remedy the fault
Performance monitoring – carried out at various intervals to con rm the power output or
serviceability of an engine, with results closely monitored and graphed
Engine removal and installation – con rms serviceability pre-removal or post installation and
checks for the presence of any leaks
Aircraft system power supply – carried out to enable other systems on the aircraft to be tested
or operated.

B737 - RR Trent 1000 full power run

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 Preparation for Engine Running
Before starting an engine, a good practice is to carry out a walk-around check of the entire aircraft.
This establishes whether anything is out of place that might cause problems or damage. Check all the
main engines – you may need to run more than one engine during the run-up. Engine-related items
that should be checked include opening access panels to check uid levels and visually examining the
engine inlet, fan, tailpipe and LP turbine.

Maintenance ground runs

Aircraft come in various sizes and power ratings. While two aircraft may be roughly the same size,
there may be a large difference in their weights and the thrust available from their engines.

When preparing an aircraft for an engine run, the many considerations come under the following two
main headings:

Position
Conditions.

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 Position
The position or location of the aircraft has a large effect on what power settings can be used when
starting the engines.

Considerations that may apply to running aircraft engines are:

Aircraft size and weight – dimensions and limits must be considered if an aircraft must be
moved to allow for engine running
Engine power – safety distances to be observed, tarmac capable of handling jet blast, enough
weight on aircraft to maintain brakes at high power
Tarmac and surrounding area material – suitable for engine run, weight rated

Boeing 737 with damage due to an engine run-up on loose bricks

Distance to buildings/roads or air eld facilities – possibility of damage to buildings, structures
or vehicles from jet blast
Blast de ectors – devices used to change the direction of the jet thrust, which is normally
directed upwards.

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 Blast de ectors

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 Danger Areas
Danger areas around aircraft dramatically increase as soon as the engines are started. The suction
from an engine intake is capable of drawing personnel into the engine even at low power settings.

Small material such as gravel or sand is easily picked up and erodes compressor and turbine
components. At the same time, the jet exhaust may pick up and blow loose dirt, rocks, sand, bits of
paving and other debris a large distance from the aircraft. For this reason, the aircraft must be parked
in a location where no damage can result from ying particles which are driven from the rear.

As can be seen in the diagram below, the areas in front of and behind an aircraft engine are extremely
dangerous. The areas shown, for a Boeing 737-600 to 900 aircraft with a CFM56 engine, are only one
example. Speci c aircraft restrictions as listed in the applicable Aircraft Maintenance Manual (AMM)
must be observed when any engine run is attempted.

Engine danger areas at idle thrust

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 Engine danger areas at full power

Engine inlet danger areas at full power

Other danger areas around the engine may include the engine and starter turbine discs. Danger also
exists from the propeller of turbo propeller aircraft.

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 Warning - propeller danger

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 Conditions
The conditions for an engine run require serious consideration of the following points:

Fuel requirements – Suf cient fuel must be present to complete the engine run, plus a safety
factor. Also, some aircraft have a minimum fuel state that must be in speci c fuel tanks prior to
start.
Noise – Gas turbine engines produce noise levels considered dangerous to humans if no
protective devices are worn. Also, running an engine at full power just outside a maintenance
facility may curtail work inside.
Weather – Wind direction and velocity can change the stability of the engine. Where possible,
the engine must be pointed into the wind. Excessive wind in any direction affects the
performance gures of the engine. A typical wind direction and velocity restriction graph is
shown below.

Allowed windspeeds

Trim running of engines at high ambient temperatures is often aborted because engine
operating limits are exceeded before the trim graph minimum limits are reached.

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 Support equipment – Equipment requirements vary with aircraft type and the reason for
which the engine is being run. They may include tow motors, tool kits, a re extinguisher,
personnel communication equipment, aircraft steps, wheel chocks and AMMs.

Personnel – The number of personnel required for the run should be kept to a minimum, but
includes ight deck runners, an outside ground observer and a re attendant.

Communication – Aircraft engines are extremely noisy (up to 160 dB) when operating, so
normal means of communication (speaking) are not always effective. Specialised headset
communication equipment may be available to make communication easier; these systems use
long leads that can present a potential danger around engines which are operating.

Maintenance crew during an engine ground run

Protective equipment – The correct protective equipment must be worn at all times when
engines are running. The equipment required depends on the aircraft and the type of engine
run contemplated, but normally includes kidney belts, earmuffs and earplugs, and appropriate
clothing.

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 Engine Running
Local instructions offer guidance regarding the restrictions and authorisations required to carry out
engine run procedures.

Pre-Start
Pre-start is the step of an engine run which involves everything from the noti cation of a
requirement for the engine run to climbing into the aircraft to carry out the engine run. Once you
have been tasked to carry out an engine run, the aircraft maintenance documentation should be
inspected to determine the requirement for the run and to ensure nothing in the documentation
would restrict or prohibit the operation of the engines or aircraft, such as:

Fuel status
A disconnected VHF radio antenna, preventing communication with the tower
Fire bottle squibs that have been removed, stopping use of the re extinguishers, etc.

After con rming the engine run requirements and aircraft serviceability, organise the location for the
run, considering:

Power settings required
Wind
Local ying program
Positions that are available
Other local restrictions.

Determine the personnel and equipment required to complete the engine run, taking into account
what specialised checks may be required during the run.

On arrival at the engine run location, position the aircraft into the wind with appropriate wheel
chocks or tie-downs installed. Position the power cart and any unneeded equipment off to the side of
the aircraft in the event the aircraft jumps the chocks or holdbacks.

The aircraft pre-run walk-around determines that the aircraft, support equipment and surrounding
area are in a safe condition (no foreign object damage, or FOD) for the engine run to commence.

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 Aircraft walk around

Engine Starting and Run
As run procedures vary with engine and aircraft types, the exact procedure for running is laid down
per type; however, this is a guide to how an engine run would be carried out.

Brief all personnel on the required procedures, including responsibilities, safety and
emergency procedures.
Perform the relevant ight deck entry checks.
Perform the relevant pre-start checks and actions.
Contact the control tower for start and/or run clearance. The control tower normally requires
the aircraft type, tail number and location, number of personnel on board (POB) the aircraft,
and duration of the run to be carried out.
Obtain clearance from the external safety observer.
Carry out the start procedure, taking care to remain within the limits of all parameters,
including Exhaust Gas Temperature (EGT), rpm, oil pressure and starter limitations.
Carry out the requirements of the engine run.
Perform relevant shutdown checks and actions.

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 Engine Limitations
All engines have a variety of starting and operating limits that must not be exceeded. These may
include:

Maximum turbine starting temperature
Minimum oil pressure for start and operation
EGT limits during starting and continuous operation as depicted in the example below.

EGT limits

Area of
Maintenance Required
Operation

Starts in Area A must be recorded and immediate corrective action must be taken
A prior to further start attempts. A borescope inspection must be performed prior to
further start attempts.

Starts in Area B must be recorded. Persistent starts in this area are cause for
B
corrective action.

C Any operation in Area C requires removal of the engine for overhaul.

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 Emergency Procedures
Emergency procedures are normally carried out upon the detection of a dangerous situation which, if
not acted upon immediately, could damage the engine or aircraft and injure personnel, either inside
or outside the aircraft.

Emergency situations require that relevant checklist items are performed immediately. Emergency
situations could be:

Engine re
Engine runaway
Engine seizure
Engine overheat
Aircraft re
Aircraft system failure.

Although some of the above may not initially appear to be emergency situations during engine
running, they may rapidly accelerate, within seconds, to life-threatening events.

In all emergency situations, quick reaction times and crew co‑operation are essential to
prevent/minimise damage to the aircraft and prevent crew injury.

Note: If at any time during an engine run an emergency situation appears imminent, the best action to
take is to follow emergency shutdown procedures to abort the engine run.

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 Post-Engine-Run Checks
After completion of the engine run, the aircraft should be returned to its standard con guration:

If tted, remove any specialist engine recording equipment and perform engine run leak checks
as required.
Remove any specialist tie-down equipment.
Re t all blanks.
Ensure engine and gearbox oil levels are within prescribed limits.

Carry out a post-engine-run aircraft walk-around inspection:

Look for evidence of air, fuel or oil leaks.
Look for FOD damage to the engine intakes and exhausts, propellers and airframe.
Re t any panels or doors removed for access or engine running.
Refuel the aircraft as necessary.
Return all equipment used for the engine run.
Complete all necessary documentation.

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 Factors Affecting Engine Performance
Introduction to Factors Affecting Engine Performance
Power output of a gas turbine engine is affected by:

Design factors, such as compressor and turbine ef ciency and engine pressure ratio (EPR)
Operational factors, such as rpm and EGT
External factors, such as airspeed, altitude and Outside Ambient Temperature.

Design Factors
Although design factors cannot be altered, the greater the engine ef ciencies and EPR, the greater
the resultant engine power output.

Engine RPM
Gas turbine engines are generally most ef cient when operating at maximum allowable rpm. Normal
operating range is usually 90%–100% of max allowable. At high engine speeds, thrust increases
rapidly with small increases in rpm. Maximum compressor and turbine ef ciency are only possible at
one speci c rpm, therefore engines are designed for best performance at max power. Operation at
other power settings degrades speci c fuel consumption.

RPM vs thrust

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 Turbine Temperature
Maximum engine thermal ef ciency, fuel ef ciency and power output occur at maximum allowable
turbine inlet temperature, although severe restrictions are laid down with regard to exceeding
maximum EGT to protect the turbine from heat stresses.

Power Limiting
Low altitude and low ambient temperature both produce high air density, which gives high mass ow
for a given engine rpm.

High mass ow allows the engine to produce maximum power before the maximum allowable turbine
temperature is reached. When this condition occurs, the engine is restricted from increasing burner
pressure any further and is said to be power (EPR) limited, thrust limited, N₁ limited or torque limited.

High density altitude and temperature conditions reduce air density and mass air ow. Maximum
allowable turbine temperature is therefore reached before the engine produces maximum power
output. Under these conditions, the engine is said to be temperature limited. If not monitored, these
conditions may lead to engine overheat, leading to turbine fatigue through heat stress.

Some engines are de-rated so that operational limits are less than design limits. This reduces engine
wear and extends engine life. These engines are different from at rated.

Adjustments
In service adjustments to non-FADEC gas turbine engines, fuel control units (FCUs) are usually
limited to:

Throttle rigging
Speci c gravity
Idle rpm
Maximum power.

An FCU suspected of being faulty should be removed and replaced with a serviceable item.

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 Performance Checks
Trimming
Adjustment of idle rpm and maximum thrust settings must be set to match the manufacturer’s
speci cations. Idle adjustment sets engine idling rpm to that speci ed by the manufacturer, allowing
for variations in ambient conditions. Depending on the particular engine, maximum power (or thrust)
adjustment ensures that the engine is producing rated thrust or shaft horsepower as speci ed by the
manufacturer, and again allowing for variations in ambient conditions.

Trimming is carried out whenever engine power output is suspect and after certain maintenance
tasks as prescribed by the manufacturer (e.g. engine, FCU or module change). In a turbojet engine,
EPR is used as a measure of engine power output. In a turbofan engine, EPR or fan rpm may be used; if
the engine is not producing full power, mass ow through the turbine assembly is reduced, and fan
rpm is reduced. Turboprop or turboshaft engines use output shaft torque as a measure of engine
power output.

Part Power Trimming
Some engines may be trimmed at less than take-off power. A stop (called a part power trim stop) is
placed so that the power lever is blocked before reaching the full power position. Engine trimming is
carried out with the power lever against the stop.

Acceleration Check
When technicians perform an acceleration check, the power level is moved from the idle to full power
setting, and engine acceleration time to full power is compared to the manufacturer’s acceleration
time.

Data Plate Speed Check
After manufacture, the engine is test-run and a data plate attached. The data plate records conditions
under which required thrust was obtained during part power trimming (e.g. 87.25% N2 at 1.61 EPR
and 59 °F). The data plate speed check is carried out by running the engine at 1.61 EPR, noting N2
tachometer indication, correcting the observed gure for any temperature variation from 59 °F, and
comparing it with the original rpm gure. Any variation outside manufacturer speci ed tolerances is
an indication that either the FCU needs adjustment or the engine is worn, and maintenance or repair
may be necessary.

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 Trend Monitoring
Purpose of Trend Monitoring
Accurate forecasting of impending component failure allows forward planning of a unit’s
maintenance commitment by taking advantage of manpower and spares availability and reducing
aircraft downtime.

Conventional trend monitoring has taken two paths:

Mechanical parameters – oil consumption, oil analysis, chip detection and vibration
measurements
Performance parameters – fuel ow, thrust, rpm, EGT and pressure readings.

The more recent advances in microprocessor-aided monitoring, displaying and recording of engine
parameters have expanded the information available to both the aircrew and maintenance crew to
determine engine condition.

Engine trend monitoring is based on the consistency with which a gas turbine engine follows its
corrected performance gures at steady-state operating conditions. An engine does not vary from its
new or post-overhaul performance gures unless some internal or external effect forces it to do so. If
the cause of the deviation can be determined, maintenance action can be taken to correct the fault.

Most modern engine manufacturers are making engines which no longer have scheduled overhaul
intervals. The engines are manufactured to be modular. This means each major engine sub-assembly,
such as a compressor assembly or turbine assembly, is a self-contained module. The engine as a whole
is not overhauled, only the engine modules, and then only when a fault occurs. This type of engine
maintenance is known as ‘on-condition’ maintenance.

With engines now being maintained on an on-condition basis, monitoring their performance trends is
crucial. It allows aircraft operators to accurately determine when maintenance on an engine is
required and takes maximum advantage of available spares and manpower. Accurate trend
monitoring also saves aircraft operators money and aircraft downtime.

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 Performance Parameters
The following engine and ight indications are required to operate an effective trend monitoring
program:

Altitude
EPR or N₁ rpm
N₂ rpm
EGT
Fuel ow.

The instrument indications obtained during ight or during an engine ground run are corrected to a
set of standard conditions. The corrected readings are then compared to the average readings
previously obtained or the gures from the post-overhaul engine test.

Graphical Presentation
The data obtained from corrected engine performance gures are plotted on a graph as shown below.
This method displays an easily readable record of the engine’s performance trend over a signi cant
time. Any malfunction or deterioration in performance is quickly recognised and maintenance may be
scheduled at the most convenient time.

Engine performance gures - normal

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 Effective trend monitoring is wholly dependent on accurate observations of engine instruments and
the operator’s ability to detect small deviations in the instrument indications. The deviation of two or
more parameters generally results from a change in engine performance.

If there are minor uctuations (within the tolerances), the engine should continue to operate
normally until its next overhaul.

Engine performance gures - abnormal

The chart above shows the same parameter data for the same model of engine as the previous chart.
This engine was removed for excessive oil consumption. On disassembly, the No. 4 and No. 5 main
bearings and carbon oil seals were found to be leaking bleed air into the bearing compartments,
causing the problem.

Because of the bleed air leak, the engine required more fuel to produce the required thrust. With the
addition of more fuel, the compressor rpm of both the low- and high-pressure compressors also
increased. If you study the chart, you will see that not only are the oil consumption data high, but so
are the fuel ow, N₁ rpm and N₂ rpm data. If these gures were plotted for an engine whose oil
consumption was normal, you would suspect that the engine compressor bleed valves were leaking.

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 Spectrometric Oil Analysis Program
A spectrometric oil analysis program, or SOAP, is another tool available to aircraft operators to help
detect developing problems in an engine. Spectrometric analysis of metal particles suspended in oil is
possible because metallic ions emit characteristic light spectra when vaporised by an electric arc.
Each metal produces a unique spectrum, allowing easy identi cation of the metals present in the oil
samples. The wavelength of spectral lines identi es each metal, and the intensity of a line is used to
measure the quantity of that metal in a sample.

Engine trend monitoring (SOAP)

Alloyed metals in turbine engines may contain amounts of aluminium, iron, chromium, silver, copper,
tin, magnesium, lead, nickel or titanium. Silver is accurately measured in concentrations down to one
part silver in 2,000,000 parts oil. The wavelength of the spectral line identi es the metal. The
intensity of the line measures the quantity of the metal.

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 SOAP analysis

Vibration Monitoring
Engine vibration during ight is also subject to trend monitoring and analysis. Increasing vibration
can indicate a deteriorating engine condition. An increasing vibration trend could be caused by
pending bearing failure or rotating assembly deterioration or damage.

Usually two vibration sensors are tted: one to the fan case and the other on the turbine case.
Vibration intensity at these points can point to the source. A warning lamp on the ight deck warns
the pilot when an unacceptable level of vibration is reached so the engine can be shut down before
more damage occurs.

Vibration monitoring

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 Borescope Inspection
A borescope is a viewing device which allows you to visually inspect areas inside a turbine engine
without disassembling the engine. A borescope may be compared to a small periscope with an
eyepiece at one end and a strong light, mirror and lens at the other end. A conducting cord connects
the probe to a control panel for adjusting light intensity and magni cation.

To aid the inspection process, many gas turbine engines are equipped with openings, or ports, that
allow inspection tools to enter. Some of the common tools used for such inspection are the
borescope, brescope and electronic imaging.

Borescope

Borescope inspections are carried out following suspected engine damage or as part of a trend
monitoring process. Borescope ports are located in the engine gas path, in both the cold and hot
sections.

To provide a view of each N₂ compressor or turbine blade, the engine can be manually rotated
through a manual cranking pad on the accessory gearbox or via a special motor attached to the
starter pad. The N₁ can be rotated by hand-turning the fan.

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 Engine borescope inspection ports

Borescope inspection is often carried out following trend analysis that identi es the following:

Deteriorating performance
Increasing vibrating
Over-temperature
Overspeed.

Borescope inspection

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 Borescope inspections are also part of routine and special maintenance inspections, such as:

FOD
Bird strike
Lightning strike.

Mechanic using a borescope

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 Damage Inspections
Damage Inspection Precautions
Fan compressor and turbine components are often damaged by loose items left in engine intakes or
exhausts.

Before performing any work inside intake or exhaust ducts, ensure all loose items are removed from
your pockets. Before closing up, thoroughly inspect your work area for loose items, including nuts,
bolts, screws, rags, lockwire, tools and personal items.

Fan Blades
CAUTION: Before entering the inlet, place a soft rubber mat in the inlet duct to protect the inlet
lining.

Like propellers, fan blades often suffer minor erosion and stone damage. Blade damage is normally
dressed by blending out the erosion or nick using a ne le and abrasive cloth. Damage and repair
limits are speci ed in the manufacturer’s maintenance and repair manuals. Any damage to fan blade
roots is critical due to the high centrifugal stress loads. Debris, used abrasives, tooling and the
protective mat must be removed before the job is nished. Following blade dressing, an engine
ground run and vibration survey may be necessary to check for fan imbalance.

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 Blade Shingling
A speci c type of damage that may be caused by FOD is fan blade shingling. Shingling is the
overlapping of midspan shrouds on fan blades. Anytime rotating fan blades encounter a force that
pushes a blade sideways, shingling can occur. Common causes of shingling include FOD, compressor
overspeed and compressor stall.

Whenever shingling occurs, you must inspect the top and bottom surfaces of the shrouds involved for
scoring or galling. In addition, any blade that encounters shingling typically must be removed and
inspected in accordance with the manufacturer’s maintenance manual. If any cracks are found during
the inspection, the fan blade must be replaced.

Blade shingling

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 Inlet Guide Vanes
Inspect inlet guide vanes for FOD damage, and blend out damage in accordance with the AMM;
blending should be nished with emery cloth to polish the area and restore the original scratch-free
surface.

Blade blending

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 Compressor Blades
Inspect the compressor for FOD damage, cracking and evidence of blade rub. If damage falls within
predetermined limits, record the extent and location of the damage for further reference and to aid
trend monitoring.

Depending on engine type, it may be possible to carry out in- eld repairs and blend out damage in
accordance with the AMM; blending should be nished with emery cloth to polish the area and
restore the original scratch-free surface. The purpose of blending is to minimise stresses that
concentrate at dents, scratches or cracks.

The illustration shows some examples of blade damage to an axial ow engine.

Blade damage

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 Compressor Washing
Compressor Washing and Cleaning
During normal operation, dirt particles, industrial fallout, salt and volcanic ash accumulate on the
compressor stators and blades. These build up over time and reduce compressor ef ciency. Reduced
EPR, unsatisfactory acceleration and high fuel ow and EGT might indicate a dirty compressor. This
contamination can be removed by one of the following recommended processes:

Water rinsing
Water washing.

Compressor washing

Before washing and/or rinsing, take precautions to ensure water does not enter the engine’s sensors
and fuel control. The AMM describes which sensors and sensing lines need to be removed or blanked
off.

For a rinse, de-mineralised water is used.

For a water wash (performance recovery wash), a detergent and de-mineralised water mixture is
used, followed by a de-mineralised water rinse.

Most turbofan, turboprop and turboshaft engines are dry motored for the rinse or wash process.
After the process is completed, the sensors are reconnected and an idle ground run is carried out to
thoroughly dry out the engine.

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 Turbine Nozzle Guide Vanes and Blades
Inspect nozzle guide vanes for burnt spots, erosion and cracks. Depending on engine type, it may be
possible to carry out in- eld replacement.

NGV damage

Exhaust Section
The exhaust section of the engine is susceptible to heat cracking. Inspect the exhaust section and rear
of the LP turbine for cracks, warping, buckling, hot spots or carbon deposits.

Hot spots or carbon deposits on the exhaust cone are a good indication of faulty fuel nozzle
operation.

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 A compressor grit wash (comprising of ground walnut shells or apricot pits) was used on older
turbojet engines, but with the advancement of cooling technology for turbines where the burnt grit
could clog the cooling holes, this process is not used today.

Video – Compressor Wash –

Relevant Youtube link: Compressor Wash (Video)

Relevant Youtube link: Compressor Wash Fuel-Saving Figures (Video)

Foreign Object Damage
Foreign object damage (FOD) is an ongoing problem for the safe operation of aircraft engines,
especially gas turbine turbofan engines. The engine inlet acts as a huge vacuum cleaner and ingests
small debris, such as concrete chips or rocks from the ramp and tools that have been carelessly left
where they can be sucked up. In ight, birds and ice are the main causes of FOD.

Any FOD damage, regardless of how small it is, results in a loss of performance by the engine and may
be indicated by an increase in EGT and a decrease in EPR or N₁ fan speed.

All technicians must remain extremely vigilant for any FOD lying around the aircraft and remove it
before the engines are started.

FOD damage

Relevant Youtube link: Compressor Damage (Video)

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