Table of Contents
22.4.1 Lubrication media
Lubrication media in form of greases/pastes, oils,
dry lubrication films, as sprays with
solvents are a requirement for the function of many aeroengine components. This applies also for a
short-term use like during the tensioning of bolts and nuts as also for permanent function. Typical are
actuator hinges or the bearing of axles of variable compressor guide vanes. Basically
only approved/specified products must be used. As not approved apply also
products out of date. During the
application attention must be payed, that media don't have unaware contact with incompatible
components respectively materials.
A mixture of different sorts of lubrication greases before or after the use needs, in case of
doubt always the approval of the responsible inspection respectively the OEM. An
unauthorised use of media, which are not explicit scheduled in instructions/specifications respectively manuals, is
forbidden.
A problem are lubricants for hot parts. Here especially attention must be payed at the lubrication
of screw threads. So a seizing/galling of the sensitive austenitic materials like stainless steels and
Ni-alloys, should be prevented and the specified torque guarantees the scheduled pretension (Ill.
23.3.1.1-2, Fig. "Influence of pretension at fatigue" and Fig. "friction forces on bolt connections"). During the disassembls, the connection should be
detatchable without damages after long operation periods. Thereby the bolt connection and other parts which
came into contact with the lubrication grease (e.g., rotordisks of Ni-alloys and heat restant steels), must
not be deteriorated from the influence of the grease (e.g., containing
MoS2, Fig. "Unsuitable lubricant leading to fracture").
Fig. "Approved lubrication media" (Lit. 22.4-19): The persued
operation properties of anti friction media can be found
from spezifications and brochures of suppliers.
In contrast, potential problemes and dangers are
mostly discussed unsufficiently. Therefore in the following, especially specific dangers during the use
are deepened. Besides lubrication greases, dry lubricants stay in the foreground.
The experience shows, that metals and metal compounds (e.g., sulphides ) are used for the anti
friction effect. However, just these have a high failure/damage potential. Thereby
operation influences like a high temperature, water, corrosive media and tension stresses are important.
Containing molybdenum disulphide
(MoS2 ): The particle size of the
MoS2 is, depending from the thickness of the lubricant
film and the roughness of the sliding
surface, of high importance of the anti friction effect. For smooth/polished surfaces like these of bearing, markedly finer particles
are necessary. Too coarse particles leads to extreme
abrasion/wear. So it is understandable, why the
change to other products, alone with the argument of the same composition, is dangerous.
The temperature limitation of use for
MoS2 containing producs lays under 400 °C. It depends
from potential deteriorating mechanisms of the materials, which will be lubricated. In this range
already markedly decomposition by oxidation into
MoO3 and SO2 occurs. Is
MoS3 existing, which acts
intense pic (volume 2, Ill. 6.2-15.1), serious friction problems
appear. With the absorption of humidity, the coefficient of fricttion markedly rises from 0,02 up to more than 1.
If humidity effects this compound it is the contrary of a anti-friction
agent! This is the reason for many negative experiences with
this anti friction medium in the normally humid atmosphere (sketches in the middle and below, Ill.
22.4.1-4).
Is MoS2 containing lubrication media used at temperatures like those, typical for hot parts, sulphur
can be released. Especially at Ni-alloys catastrophic
sulfidation damages (Fig. "Significance of using approved lubricants" and Ill.
23.3.1.2-9) with the failure of the component can be triggered (volume 1,
<U>page</U> 5.4.3-3 and Ill. 5.4.5.1-4). Are cross
sections in contact with MoS2 under sufficient
high tensile stresses, spontaneus crack formation
and fracture must be expected (Fig. "Unsuitable lubricant leading to fracture").
Also during an application by spraying (e.g., of an anti-friction agent) attention must be payed, that
no hot parts are contaminated with MoS2
.
Polytetrafluorethylene (PTFE, „Teflon ®“): If at high temperatures
fluorine or its compounds are released, for metallic materials the danger of corrosion, similar to chlorine, exists. Especially
dangerous is stress corrosion (stress corrosion cracking = SSC) at components under sufficient hich tensile
stresses. To the potential endangered materials belong
titanium alloys and high strength
steels. Terefore attention must be payed, that also no unintended depositions, e.g., during the use of sprays like release agents
or anti seize agents, get on components with high operation temperatures.
Graphite is used in lubricants and protects metallic surfaces against seizing/galling. However it
oxidises already markedly at relative low temperatures (from about 300°C). Graphite is resistant up to
about 1300°C without the access of oxygen. So it can stay over long operation periods in tight threads,
also at typical hot part temperatures in aeroengines. With this it would be also helpful, loosening
connections without damage. Its lubricity
needs the access of humidity (vapour, air moisture). Gets
graphite unintended or by abrasion/wear into electric isolating areas, it can trigger
shorts respectively creepage
currents.
Attention! Graphite containing anti-friction pastes can be easily confused with MoS2 containing paste, because of the similar colour and consisteny. This is from experience a high danger, because, as already mentioned, MoS2 can trigger dangerous failures of hot parts.
Hexagonal boron nitride is an inert dry lubrication that contains its lubricity in an
oxidising atmosphere up to about 600°C operation temperatures.
Metal oxide forming high temperature lubricants
(„Neverseez ®”) contain metals like nickel,
copper and zinc in a compound with petroleum as carrier oil. This evaporates at operation temperature
and leaves oxides of nickel, copper and zinc. These prevent a seizing/galling. This allows the loosening of
a connection/bolting without damages, also after longer operation periods. However here attention
is necessary. If even so, high break loose torques arise, a
not with non destructive testing
detectable deterioration is possible. This can prevent a further use of the bolts.
Further the effects of the metallic contents from the lubrication grease must be tested during an approval.
The danger of the formation of a corrosion cell prohibits the use in contact with corrosion
susceptible alloys. This applies for low operation temperatures, during which no protecting oxides can develop
and at least temporary humidity exists (e.g., condensate during stand still).
Silver containing pastes let expect a lubrication effect (e.g., at threads). This may apply similar
pastes, like are also used for the heat dissipation at electronic components. At hot parts from nickel
alloys, silver can act dangerously
deteriorating in different manners (volume 3, Ill. 12.4-14). This goes
from the promotion of a sulfidation, deterioration by
diffusion (loss of strength) up to a spontaneous
crack formation during tensile stresses and the influence of
molten silver (Fig. "Brittle failure modes of bolts and nuts", LME volume 4,
Ill. 16.2.2.3-10.1). Similar dangerous are pastes with metallic
lead to estimate. Also here it must be
reckoned during high temperatures with initial fusings and
LME at steels, nickel alloys and titaniujm
alloys (volume 4, Ill. 16.2.2.3-10.2).
At Titanium alloys already above 200 °C, the direct
contact with solid silver acts embritteling
(SMIE, volume 4, Ill. 16.2.2.3-11). Basically the use of silver should be omitted for
alloys of Al and Mg because of watery corrosion due to formation of a corrosion
cell.
Fig. "Properties and application range of lubricants" (Lit. 22.4-2, Lit. 22.4-9 and Lit. 22.4-10): This chart contains a selection with remarks about the properties and the application range of frequently used lubricants. In this chapter also at other locations it is pointed at several of these auxilary media.
Fig. "Environmental influences of lubricants" (Lit. 22.4-16): The behavior of lubricants can change totally under environmental influences. This must be recognised during testing and approval/certification. So the following factors play a role:
- Access of environmental/surrounding media (Fig. "Approved lubrication media" and Fig. "Beware unsuitable lubricants").
- Contact with auxilary materials.
- Component specific operation parameters.
- Materials/tribological system.
Also during change, respectively the introduction of new
auxilary materials/media or new products (also
the change of the producer/product) like washing fluids and solvents, anti icing agents or
contakt sprays, pay attention at the effects at already used auxilary media. If necessary a
proof of the harmlessness is needed from the OEM. In case of doubt, basically the agreement of the
responsibles must be obtained. Typical, potential deteriorating
mechanisms are:
Intrusion of foreign particles into the lubrication gap: A leakage flow through the bush bearings
of variable guide vanes (sketch in the middle) can transport corrosive dust particles and dispose
these between the sliding faces. So with the use of
MoS2 containing lubricants (also as infiltration and
in sliding bushings), the danger of corrosion and jamming of the system exists (Fig. "Approved lubrication media").
The ingression of liquid media: These can act corrosive, intensified by the lubricant. Larger
amounts and with a solving effect can elutrate and cause the metallic contact between the sliding faces
(wear/abrasion).
Entering of vapours: This already applies for
air humidity if it changes the lubricating properties
of the auxilary medium at operation conditions. Also
vapours of solvents or oil vapour can
alarming influence not sufficient tested auxilary materials.
Fig. "Beware unsuitable lubricants": During the testing of the thrust reverser, the function of the pivoting mechanism was proved in serveral test cycles. Thereby, after a short engine run, the pivot bearings have been treated with salt water spray, that afterwards acted overnight. Already after frew test cycles the bush bearings jammed with catastropic damages by orverloading the actuating mechanism. Investigations showed, that obviously the used MoS2 containing dry lubricant film at the sliding faces, together with corrosive water, caused corrosion products with a volume increase (Fig. "Approved lubrication media"). Thereby certainly the deteriorated anti-friction properties of the MoS2 during contact with water, have been from especially significance. After a conversion to the synthetic aeroengine oil with which a periodic lubrication was carried out, no more failures occurred. This proved itself during the following long years series operation.
Fig. "Maintenance of lubricated systems" (Lit. 22.4-16): Understandably the
maintenance has an essential influence at the
safety of a lubricated system. Thereby the
re-lubrication plays a crucial role. Do here failures occur,
respectively will be deviated from specifications/instructions, especially in the manual, catastrophic failures
can occur (Fig. "Ill maintained lubrication leading to crash 1"). Also media of cleaning
activities in the surrounding of dry or grease
lubricated components, their function can be affected (Fig. "Environmental influences of lubricants"). This applies also for abrasive cleaning
particles (e.g., from cleaning `felts') and dust (e.g., compressor wash, chapter19.2.3).
Of course only the auxilary media and lubricants, which are
explicite approved/specified for the particular application
by the responsible, may be used. An auxilary medium, which is sheduled for
an application, can fail at an other component with other operation conditions. Therefore an
unauthorised deviation is potential dangerous and must be omitted.
Fig. "Warning signals" (Lit. 22.4-3): Several components
send before a catastrpophic failing `warning
signals'. They only must be registered, indentifyed and know, how to interpret. Understands the
experienced technician the „language“ of the part, he can intercept dangerous consequences of function
deviations in time. To this belongs the remedy respectively the introduction of the adequate measures.
Typical „warn signals” are:
High moving/actuating forces and breakaway
forces can indicate by relating, high power
consumption, respectively the rise of forces and hydraulic pressure in the actuation mechanism. Examples are
actuators of thrust reversers or the thrust nozzle adjustment at aeroengines of fighters. Also an
asymmetric movement, standby position or overload features at systems of power transmissions (e.g.,
jackscrews, levers), are symptoms. Do those arise, naturally not only the deteriorated area must be
repaired respectively exchanged. It is essential to identify the
cause, i.e. if necessary the sluggish
joint/bushing and to clear the failure
mechanism.
Unusual pronounced „stick-slip-effects“
(Fig. "Influences of the stick slip effect" and Ill. 20.1.14) are caused by deteriorated
sliding properties. They often draw attention by noise emission. Typical is
squeaking (high-frequency, an example are brakes in a car) or
creaking (low-frequency, an example is an old door),
chattering/rattle and „wobbling”. Also
vibrations can be the result of a movement. They can create instabilities
in control systems and admeasurement systems/valves, which show in the aeroengine behaviour or
at displays/instruments.
Features of the lubricated area and appearance of the
lubricant: Already abnormal amounts of
escaping lubricant can apply as a hint at deviations in the tribological system. The cause are an
unsuitable lubricant and/or unusual operation influences/conditions (e.g., high temperatur). This applies
contrary also for unexpected gumming or brittle
deposits (Fig. "Ill maintained lubrication leading to crash 1").
Especially alarming is the so called
„bleeding“ of the lubrication gap. An indication are red brown
up to almost black run-down signs (Fig. "Lubrication caused fretting wear"). Usually those occur during fretting
(fretting corrosion at steels, volume 2, Ill. 6.1-3 and Ill. 6.1-4). In such a tribological system, fine wear/abrasion
products oxidise. The flushing of these wear paricles let expect an unacceptable
increase of the clearance, if it not yet happened.
Unusual discolourated remains of lubricant can also point at the reaction with other media like
solvents or wash fluids.
Deposits at sliding surfaces/contact
surfaces announce with colour, structure and consistency
problems and allow conclusions at the causes (volume 2, Ill. 6.1-3). Also here red brown discolourations hint
at fretting corrosion. Naturally the inherent colour of the lubricant (frequently black for
MoS2 or graphite) must be considered.
It is especially alarming, if there are no remains of the
lubricant (Fig. "Ill maintained lubrication leading to crash 1"). This applies just,
if during correct maintenance respectively assembly those must be expected. Then the conclusion
at deficits, during the prescribed lubrication processes and relubricatios,
is obvious.
Features of wear, respectively fatigue at sliding faces and pitch surfaces
(races,flanks): At anti friction bearings such a deterioration can attract external attention with
vibrations. In grease lubricated bearings,
often particles caused by wear and fatigue can be found. At bush bearings, the advanced wear
arises usually as a markedly increased clearance.
Exterior discolouration of bush bearings/anti friction bearings respectively
casings/boxes: Are tempering
colours concerned, this is a clear sign of a too high operation temperature. The cause
may be the increase of the friction forces and with this the frictional heat. This again points at an
already dangerously advanced bearing failure. Such an indication on a grease lubricated bearings is
also supported by leaking grease, that fluidised too much. Simultaneously the seal of the bearing can
be deteriorated by over temperatures.
Fig. "Significance of using approved lubricants": Concerned is an aeroengine of a fighter (sketch above). The assembly of the turbine module should be carried out `especially fine'. To increase the torque efficiency of the bolts (Fig. "Influence of pretension at fatigue" and Fig. "friction forces on bolt connections"), e.g. to guarantee the necessary pretension with the specified fastening torque, the bolts of the coupling (curvic coupling, detail in the middle) have been treated with MoS2 containing lubrication grease. Prescribed was synthetic aeroengine oil. Unintended, the toothing was contaminated with remains of lubricant. Part temperatures in the range of 500 °C decomposed the MoS2 and a sulfidation attack (detail below left, Lit. 22.4-19) occurred. These, also if small deteriorations/notches (in the range of a tenth millimeter), unfortunately have been located where they are relevant for the lifetime of the part because of the very high loads. A fracture mechanics evaluation could not certain enough rule out a dangerous cyclic crack growth. Therefore several suspect turbine modules had been disassembled. These expensive parts (turbine disk, sketch right) had to be scrapped.
Fig. "Unsuitable lubricant leading to fracture" : In this case it
was tried to improve an assembly process. Like in Fig. "Significance of using approved lubricants" the
required initial tension should be guaranteed with a
`better' lubricant of the central bolt thread. This thread
is in the middle sketch located at the right end of the central tension bolt. This tensions over
toothed couplings (curvic couplings) the turbine wheels of the gas generator.
The thread, which is treated with a MoS2
containing lubricant, is moved through the hub bore of
the turbine wheels. These consist of a Ni alloy casting. The hub bore of the 1st turbine stage wheel is
so tight that lubricant, which laps the thread, is wiped off into the hub bore. This is during service
extremely high loaded.The position of the centering lappped-type flange of the central bolt was just
exactly positioned in this zone. So it was possible, that at a materials temperature of more than 500 °C
the decomposed grease released sulfur. Because of the access of air hindrance, no burning occurred. In
the micropores which are for these casting materials in certain limits inevitable and so
specified/accepted. Into such, which have been opened by the machining of the bore, sulfur intruded. This caused a sort
of stress corrosion cracking with very fast, accelerated crack propagation. Already with an axial
length of few millimeters, the crack gets instable (volume 3, Ill. 12.2-1).
The fracture of the wheel with fragment exit (uncontained failure) occurred. An extensive and immediate readjustment at about
100 already delivered aeroengines, which have been assembled according to the suspect procedure,
was necessary.
Fig. "Ill maintained lubrication leading to crash 1" (Lit. 22.4-3): This crash of an airliner into the sea is caused by the failing of the
elevon actuator. Parts of the airplan could be salvaged. The investigation arose as
cause of the crash a failure at the adjustment spindle of the
elevon. So this was no aeroengine failure. However
the occurrences are in causative connection with
maintenance deficts. They are also interresting for
the field of aeroengines.
The sequence of the flight accident and findings at the wreckage pointed at the failing of the
elevon (left side, frame above reight). This is actuated by a
screw nut on a threaded spindle with a length
in
the range of meters, with about 10 cm in diameter (left side, frame below right). It is driven by
electric motors.
Parts of the elevon actuating system with spindle and actuating nut could be recovered. The
threaded sleeve inside the actuating nut (lleft side, below left), was broken and showed pronounced
wear damages. Thread pitches down to the root radius had disappeared and so the nut got out of engagement.
The forced fracture at the end comes from a circumferential
LCF crack (low cycle fatigue) with
accordant crack propagation features (striations). Inside the nut
no residues of a lubricant have been found. However in the neighboring outside section there were red brown and black residues of the
lubrication grease (Fig. "Warning signals"). The bore for a local lubrication was blocked by a hard black deposit
(Fig. "Warning signals"). This deposit contained wear particles from the nut.
About 20 cm long copper coloured wear/abrasion
chips out of the nut had warped aroud the
spindle (right side above). It was noticeable that the spindle showed in the operating distance, except tiny
rests, no traces of old or fresh lubricant. Outside the operating distance, remains of lubricant have
been found in the thread roots.
The investigation of further according actuating nuts from other
airplanes of the operator showed wear damages similar in type in different stages.
Investigations of the lubricant remains arose, that these
didn't fit to one of the both specified
products. This pointed at a mixture of the
greases. During tests in connection with one of the the greases
(Aeroshell Grease 33, Ill. 22.4-2) a dark redbrown discolouration was observed. This obviously concerned
a desired, i.e. harmless reaction of the
additives. Extensive wear tests showed, that a mixture of
the specified/approved greases (Aeroshell 33 and Mobilgrease 28) not noteworthy differ from the
single greases. Also 5 % water or deicing fluid did not change this favourable behaviour.
Only during deficit of grease, a wear was observed, similar to the wear of the accident
parts. Therefore the mixture of the greases could be ruled out as cause of the extreme
wear.
The failure sequence arose, according to the investigations, as follows (right side below):
At the beginning the wear in the moving nut caused the blockage of the
actuation.
Then during the frequent actuating trials, a
shear of the remaining nut thread occurred. The nut
was torn over the spindle up to the stop. It came to an extreme, aerodynamically caused swelling load ot
the elevon. This lead to a cyclic overload of the threaded
bushing, with crack formation and subsequent
forced fracture. With this the elevon got free over the stop and triggered the final crash process.
The cause of the etremely wear of the actuating nut must be seen in an unsufficient
mantenance caused lubrication.
Thereby possibly additional effects acted:
- Lacking lubrication, respectively re-lubrication.
- The technician was not informed about the procedure during the re-lubrication. For example he did not know, that during lubrication grease must be visibly extruded out of the engaged threads.
- Extension of the lubrication period by the operator from 1600 flight hours to 8 months (ca. 2250 h). Thereby, without sufficient experience and coverage/proof, it was acted from the assumption, that this is justified with a change of the lubrication grease product.
A later inspection of the responsible authority (FAA) arose in thre maintenance field of the operator
a multitude of deficits:
Management:
- The position of the maintenance director was since two years not occupied and is since a short time administrated by two persons.
- The position of the plant manager is vacant.
- The director for the safety is simultaneously responsible for the quality control and the training. He has no direct report authorisation at the highest management level.
Maintenence training:
- The manual of the operator does not discribe training handouts or the practical trainings.
- The training program is only informal in the discretion of the instructors. There is no structured plan, the determination of the subject matter and criteria of success.
Manitenance program:
- The maintenance manual (general maintenance manual) does not render the actual, at the operator used processes.
- The maintenance manual does not contain action instructions for extensive planning and controlling (heavy check).
- The maintenance manual does not contain a complete approach for the problems of an aircraft after a heavy check (airworthiness release).
- In single cases the documentation of the maintenance was incomplete.
- Deficits in the labelling and the trace back of spare parts.
- Shift transfer did not always take place, according to the maintenance manual. Deviations of the documentation (deviating forms, lacking signings).
- Work sheets for special tasks are only provided with a stamp, but not with a signature of the issuer.
- Though notations of a not finshed work process are existing, they lack for the completion.
- Changes on the work sheets without coumter-signature of the engineering or the quality control.
- The maintenance manual contains no instructions like work sheets, which must be distributed and monitored during the maintenance.
Continuous problem analysis and monitoring.
- Manuals show no copies of examples of check lists for such a program.
- The monitoring is not continuous. Check intervals in periods of one or two years with an overdrawing of half a year.
- Check/inspection methods and techniques with the, at the operator used program, do not correlate with the prescribed safety standards.