COMPLEX SYSTEMS / TASKS
Many modern aircraft
systems are such that any one system may involve more than one trade/license
category. Any one system / component may be related hydraulically,
electrically, electronically or mechanically to many other systems /
sub-systems.
On modern aircraft the
computer system (computer, data buses and related interface units) connect
almost all the aircraft systems together, one way or other. A good example is
the Air Data Computer.
The Digital Air Data Computer
(DADC) takes (mainly) Pitot and static pressures and converts them to digital
signals where they are then put on the data bus for other computers to use.
Air data can be used in
so many systems, but 2 are taken as an example, the pressurization computer
(controlling cabin pressurization), will use some of this data as will the
FADEC (Full Authority Digital Engine Control computer) to help run the engines.
So, several trades are
involved: four license categories under BCARs sect L (Electrical, Instrument,
Aeroplane’s and Engines) and 2 under JAR66 (mechanical and avionics).
It is important when
tasks are performed on aircraft, that all engineers know the exact extent of
their responsibilities applicable to their license/approval. It is also
important that the engineer has some knowledge of all systems beyond his/her
immediate certification responsibilities. This will mean that he/she will have
a better understading of any consequences occurring to “other systems”,of
actions taken with “immediate responsibility systems”.
When all separate trade
area work is completed and serviceable it is important that nothing is left out
(particularly at trade boundary interfaces). The aircraft as a whole should be
serviceable.
To this and the
following points should be studied.
·
Duties & responsibilities of each
engineer.
·
Maintenance manuals.
·
Tasks cards (job cards).
·
Recording
·
Sufficient inspections.
·
Stage inspection/duplicate inspection.
·
Supervisory checks.
·
Liaison between trades.
Duties and
Responsibilities of a Licensed Engineer.
All national
authorities specify these duties, and for the UK, the CAA publish them in
Airworthiness Notices. Notice number 3 specifies the certification
responsibilities in relation to the ANO and JAR 145.
It relates to type
licenses/authorizations issued under BCARs sect L and JAR66.
It also relates to
those type licensed engineers who perform work on aircraft outside their
licence responsibilities.
The notice defines such
terms as:
·
Maintenance
·
Overhaul
·
Repair
It specifies the
various types of certification that can be signed and it states the areas of
responsibilities of the following type licence/approval/authorization
categories:
·
Category A - Aeroplanes - Maintenance
·
Category B - Aeroplane/Rotorcraft
- Overhaul
·
Category C - Engines – Maintenance
·
Category D - Engines –
Overhaul
·
Category A&C - Rotorcraft
– Maintenance
·
Categoty X - Instrument –
Maintenance
·
Category X - Electrical –
Maintenance
·
Category X - Autopilots –
Maintenance
·
Category X - Combined –
Maintenance
·
Category R - Radio – Maintenance
·
JAR66 Category A - Line
Maintenance
·
JAR66 Category B1 - Aeroplanes/Engines
– Maintenance
B1.1 - Aeroplanes Turbine
B1.2 - Aeroplanes Piston
B1.3 - Helicopters Turbine
B1.3 - Helicopters Piston
·
JAR66 Category B2 - Avionic systems –
Maintenance
·
JAR66 Category C - Aircraft – Base
Maintenance
The Notice specifies
areas of trade responsibility together with exclusions where work is NOT
permitted by certain licence/authorization holders.
It will state,
particularly in relation to JAR66 categories, areas normally considered outside a specific trade into which
responsibilities extend.
Manuals
– Hard Copy or CD Form
These include:
·
Maintenance Manuals (AMM)
·
Wiring Manuals
·
Illustrated Parts Catalogue (IPC)
·
Structure Repair Manuals (SRM) etc
The appropriate manual
should always be studied before carrying out a task. Even if the task is well
known, reference should be made to the manual in case you might have forgotten something or if there
has been an amendment since the last time the task was performed.
Check that is the
correct manual and check amendment state and the ‘effectivity’.
Check the
work/procedure stated in the manual against your training/duties and
responsibilities as a licensed engineer. If they are all compatible, then you
can proceed with work. If they are not then other, more qualified, personel
will have to be brought in to assist/complete the task.
If you feel the manual
is incorrect in any detail/procedure then double check that you have the
correct manual, it is up to date and the effectivity is verified. Check that
you are working/looking at the correct aircraft component location. If after
this check you still feel the manual is incorrect then the manufacturer should
be contacted either direct or through your company publications office. Work
should not proceed until clarification has been obtained from the manufacture.
Work
Cards/Job Cards
Many organizations
produce work cadrs/job cards. The procedure is printed on the cards with
provision made for signatures at regular intervals, stage inspection and
duplicate inspections.
The information on the
cards is similar to that in the manual and is specific to the task in hand and
is laid out in a, usually, more readable and logical manner.
If the task is long and
/ or complex the job card can be written out in such a way as to break it down
into stages. If the cards are kept up to date with signatures and dates etc
recorded as and when each stage is completed then a continuous record is
maintained.
This continuous record
is important, particularly in relation to shift working or when handing over a
part completed job to another engineer.
During the handover, a
de-briefing should occur between the ‘outgoing man’ and the ‘incoming man’. The
de-briefing should include:
·
Checking the cards are signed and
up-to-date
·
A verbal explanation of the progress of
the job to-date
·
An indication of any possible problems that
many arise
·
A situation report
·
A progress report on the spares
situation
·
Expected (by management) completion date
and time
·
Possible exchange of telephone numbers
for liason purposes
Stage
inspections/duplicate inspections called for on the job card should be carried
out and signed for when stated and completed cards retained (after job
completion) as part of the aircraft records.
Electronic
Aids to Fault Finding
Making maintenance
information more accessible to the aircraft engineer is one way to improve the
engineer’s efficiency and improve the standard of workmanship. On-board fault
computers as fitted to many modern aircraft is an example of how electronics have
come to the aid of the engineer.
A more recent
development is the belt warn notebook computer with a head-up display worn on
the head by the engineer whilst working. The Rockwell Trekker is a good example
of this type of technology.
The small computer is
worn on the waist belt and the screen (liquid crystal display) is fitted by a
strap to the head of the engineer. Control of the computer is by voice commands
which leaves both hands free to get on with the work.
Contents of the AMM can
be voice commanded and the pages/pictures are “floated” as a virtual image on
the 1 inch square liquid crystal monocular head-up display.
The computer is
strapped to the waist of the engineer and the monocular unit (with mic) is
place on the head – with a cable attaching to the waist unit.
This system allows both hands free to get on with the work and
at the same time reduces the time spent “information gathering”. The man/woman
can get on with the job whilst at the same time reading about it. There is no
interruption between “information gathering” and “job execution”.
Laptop
Computers
These, like the PC, can
be used to read manufacture’s data such as AMMs etc. Can be used at the work
location for better information access.
Boeing has recently
(2001) launched a new software package for the laptop. This software includes
such things as Flight Manuals, Minimum Equipment List, Operations Manual etc.
Called the Boeing Laptop Tool it can also be customised to include individual
aircraft data such as weights etc. Presumably other manufacturers will follow
suit.
On-board
Fault Computers
As systems on aircraft
have become more sophisticated the need has arisen to provide on-board fault
finding/BIT equipment. These simplify line maintenance by providing an on-board
fault recording system/and instant checks to verify component operational
serviceability.
The data generated is
usually in 2 forms, operational data and maintenance data.
Operational Data will
give the flight crew real-time information on the systems’s status. It will
allow them to act accordingly either using an alternative system or checking
with technical ground staff (radio or com/sat) on possible in-flight
rectification procedures.
Maintenance Data.
This is generated by each system’s built
in test equipment (BITE) which is consolidated before down loading by
maintenance staff to prepare the necessary
rectification, spares procurement etc.
In
general there are 3 classes of failure:
1. Failures
which have an operational impact on the current flight. These may also have an
impact on subsequent dispatch depending on the minimum equipment list (MEL) and
are always reported to the maintenance staff. Datalinking (comsat and sometimes
by radio) can send this information ahead of the aircraft to alow maintenance
to prepare the necessary rectification procedures, spares location etc.
2. Failures
with no immediate flight operational consequences. Detail are only made
available to the flight crew by request on a status page. Rectification of a
class 2 failure will depend in existing deferred defects and the MEL.
3. Minor
failures with no operational significance for the current flight which are not
even displayed for the flight crew. They are available to the maintenance staff
on request but cause no dispatch restrictions.
Each system detects and
stores data about it’s own failures (internal failure) and those of its
neighbouring systems which are known as external failures.
In the normal reporting
mode all systems report both types of failures to the on-board maintenance
system which memorises and correlates them, and displays them on the screen
when requested.
The interactive menu
allows engineers to establish a dialogue with any system to get detailed information
on failures, status etc. The normal mode also creates a post-flight report
which lists all the flight deck indications and the associated maintenance
messages. This provides a powerful tool in fault rectification, as well as
verbal flight crew reports and aircraft logbook entries.
