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acoustic, electromagnetic, etc.)
Acoustic Emission
Acellent Technologies
Desirable SHM Attributes
19
Physics-based material properties measurements to
determine material state throughout life cycle – allow design
conservativeness to be minimized
Intelligent structures (self-diagnostic, self-healing, health
monitoring & diagnostics, manufacturability w/sensors, etc.)
Leading to design optimization, weight saving, less fuel
consumption & environmental impact
SHM Outcomes
20
Develop and demonstrate SHM technologies that can be
used to monitor structural integrity in service conditions
with high reliability & durability.
As in conventional NDT, a single technology will not be
suited for the entire range of applications, based on
different materials, component geometries and damage
scenarios.
Diagnosis must have high reliability over the aircraft
lifetime, since un-justified maintenance actions are quite
costly to the operator and spurious warnings degrades
confidence in the system.
Accuracy and reliability may even be more stringent, since
further optimization of structural design will rely on SHM
with better knowledge of actual flight loads & condition.
Challenges to SHM
21
Components shall qualified, as part of aircraft certification, meaning they
shall perform the specified function while withstanding the specified
environmental conditions.
Include large variations of temperature, vibrations, impacts, Electro-
Magnetic Hazards, chemical fluids, etc… as per RTCA DO 160 and aircraft
integrator directives.
Components qualification shall demonstrate that the system performs
reliably in the specified environmental conditions, in all the aircraft
operational conditions over it’s lifetime.
Specific issues need to be considered particularly:
Easy installation and application on surfaces
Accuracy and reliability when used on painted surfaces
No corrosive damage to surfaces where applied
No delaminating between sensor and monitored structure
Suitable for metal, composite, sandwich structures
Suitable for various damage: cracks, corrosion, delamination, de-bonding…
Clearly different requirements will apply onto the system components:
sensors, processors, computers, wiring, power supply, … depending on the
technologies, architecture and installation location retained.
Micro-Nano-Technologies have the potential for supporting qualification
requirements and the SHM business case.
System Qualification
H. Speckmann, Materials & Processes - Testing Technology, Airbus
22
Implementing SHM
SHM is not a new concept - it is already implemented on military aircraft,
with a different rationale but some converging features.
Still the constraints of airworthiness certification and the existing
cost/benefit have limited its introduction in commercial aviation
There is currently no specific FAA or EASA policy on CBM for civil aircraft. However,
some guidance is provided in FAR-29 (FAA, 2003) on achieving maintenance or
airworthiness credits with HUMS that could be developed.
US DoD stated the requirement to transition to a CBM program by the end of 2015.
Confidence needs to be built that SHM will bring the expected benefits, while
maintaining or improving the safety and efficiency of modern aircraft – by
progressive introduction and proving the reliability & benefits.
1st generation of SHM shall target maintenance cost reduction and
increased aircraft availability - technology will allow saving cost and time in
regulatory inspections.
2nd and 3rd generations of SHM shall integrate a new certifiable design
philosophy and will permit weight reduction.
Sensors and their local processors would be more integrated with microelectronics
allowing more decentralized architecture where local processors perform & record
the first level of SHM processing until transmission to the upper level processor.
H. Speckmann, Materials & Processes - Testing Technology, Airbus
23
LAHMP Health Monitoring System F-15 Flight Tests
In 2003, the Army awarded an SBIR Phase II contract to TRI/Austin to develop a
diagnostic/prognostic system that could monitor aircraft and rotorcraft structural
components in flight.
focused on ruggedizing the system, optimizing performance, reducing power draw,
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