Fatigue testing explained

Fatigue testing is a specialised form of mechanical testing that is performed by applying cyclic loading to a coupon or structure. These tests are used either to generate fatigue life and crack growth data, identify critical locations or demonstrate the safety of a structure that may be susceptible to fatigue. Fatigue tests are used on a range of components from coupons through to full size test articles such as automobiles and aircraft.

Fatigue tests on coupons are typically conducted using servo hydraulic test machines which are capable of applying large variable amplitude cyclic loads.[1] Constant amplitude testing can also be applied by simpler oscillating machines. The fatigue life of a coupon is the number of cycles it takes to break the coupon. This data can be used for creating stress-life or strain-life curves. The rate of crack growth in a coupon can also be measured, either during the test or afterward using fractography. Testing of coupons can also be carried out inside environmental chambers where the temperature, humidity and environment that may affect the rate of crack growth can be controlled.

Because of the size and unique shape of full size test articles, special test rigs are built to apply loads through a series of hydraulic or electric actuators.Actuators aim to reproduce the significant loads experienced by a structure, which in the case of aircraft, may consist of manoeuvre, gust, buffet and ground-air-ground (GAG) loading. A representative sample or block of loading is applied repeatedly until the safe life of the structure has been demonstrated or failures occur which need to be repaired. Instrumentation such as load cells, strain gauges and displacement gauges are installed on the structure to ensure the correct loading has been applied. Periodic inspections of the structure around critical stress concentrations such as holes and fittings are made to determine the time detectable cracks were found and to ensure any cracking that does occur, does not affect other areas of the test article. Because not all loads can be applied, any unbalanced structural loads are typically reacted out to the test floor through non-critical structure such as the undercarriage.

Airworthiness standards generally require a fatigue test to be carried out for large aircraft prior to certification to determine their safe life.[2] Small aircraft may demonstrate safety through calculations, although typically larger scatter or safety factors are used because of the additional uncertainty involved.

Coupon tests

Fatigue tests are used to obtain material data such as the rate of growth of a fatigue crack that can be used with crack growth equations to predict the fatigue life. These tests usually determine the rate of crack growth per cycle

da/dN

versus the stress intensity factor range

\DeltaK=Kmax-Kmin

, where the minimum stress intensity factor

Kmin

corresponds to the minimum load for

R>0

and is taken to be zero for

R\le0

, and

R

is the stress ratio

R=Kmin/Kmax

. Standardised tests have been developed to ensure repeatability and to allow the stress intensity factor to be easily determined but other shapes can be used providing the coupon is large enough to be mostly elastic.[3]

Coupon shape

A variety of coupons can be used but some of the common ones are:

Instrumentation

The following instrumentation is commonly used for monitoring coupon tests:

Full scale fatigue tests

Full-scale tests may be used to:

  1. Validate the proposed aircraft maintenance schedule.
  2. Demonstrate the safety of a structure that may be susceptible to widespread fatigue damage.
  3. Generate fatigue data
  4. Validate expectations for crack initiation and growth pattern.
  5. Identify critical locations
  6. Validate software used to design and manufacture the aircraft.

Fatigue tests can also be used to determine the extent that widespread fatigue damage may be a problem.

Test article

Certification requires knowing and accounting for the complete load history that has been experienced by a test article. Using test articles that have previously been used for static proof testing have caused problems where overloads have been applied and that can retard the rate of fatigue crack growth.

The test loads are typically recorded using a data acquisition system acquiring data from possibly thousands of inputs from instrumentation installed on the test article, including: strain gages, pressure gauges, load cells, LVDTs, etc.

Fatigue cracks typically initiate from high stress regions such as stress concentrations or material and manufacturing defects. It is important that the test article is representative of all of these features.

Cracks may initiate from the following sources:

Loading sequence

A representative block of loading is applied repeatedly until the safe life of the structure has been demonstrated or failures occur which need to be repaired.The size of the sequence is chosen so that the maximum loads which may cause retardation effects are applied sufficiently often, typically at least ten times throughout the test, so that there are no sequence effects.[8]

The loading sequence is generally filtered to eliminate applying small non-fatigue damaging cycles that would take too long to apply. Two types of filtering are typically used:

  1. deadband filtering eliminates small cycles that completely fall within a certain range such as +/-3g.
  2. rise-fall filtering eliminates small cycles that are less than a certain range such as 1g.

The testing rate of large structures is typically limited to a few Hz and needs to avoid the resonance frequency of the structure.

Test rig

All components that are not part of the test article or instrumentation are termed the test rig. The following components are typically found in full scale fatigue tests:

Instrumentation

The following instrumentation is typically used on a fatigue test:

It is important to install any strain gauges on the test article that are also used for monitoring fleet aircraft. This allows the same damage calculations to be performed on the test article that are used to track the fatigue life of fleet aircraft. This is the primary way of ensuring fleet aircraft do not exceed the safe-life determined from the fatigue test.

Inspections

Inspections form a component of a fatigue test. It is important to know when a detectable crack occurs in order to determine the certified life of each component in addition to minimising the damage to surrounding structure and to develop repairs that have minimal impact on the certification of the adjacent structure. Non-destructive inspections may be carried out during testing and destructive tests may be used at the end of testing to ensure the structure retains its load carrying capacity.

Certification

Test interpretation and certification involves using the results from the fatigue test to justify the safe life and operation of an item.[9] The purpose of certification is to ensure the probability of failure in service is acceptably small. The following factors may need to be considered:

Airworthy standards typically require that an aircraft remains safe even with the structure in a degraded state due to the presence of fatigue cracking.[10]

Notable fatigue tests

Further reading

External links

Web site: Boeing 787 conducts fatigue testing . . 18 July 2019.

Notes and References

  1. Web site: High-Rate Test Systems. MTS . 26 June 2019.
  2. Web site: FAA PART 23—Airworthiness Standards: Normal Category Airplanes . 26 June 2019.
  3. Book: ASTM Committee E08.06 . E647 Standard Test Method for Measurement of Fatigue Crack Growth Rates . . E647-13 . 2013.
  4. Web site: Single Edge Notch Tension Testing. 26 June 2019 . NIST .
  5. J. C. . Newman . Y. . Yamada . M. A. . James . Back-face strain compliance relation for compact specimens for wide range in crack lengths . Engineering Fracture Mechanics . 2011 . 78 . 15 . 2707–2711. 10.1016/j.engfracmech.2011.07.001 .
  6. Recovery of the RAAF MB326H Fleet; the Tale of an Aging Trainer Fleet . G. . Clark . G. S. . Yost . G. D. . Young . Fatigue in New and Ageing Aircraft . 26 June 2019.
  7. Web site: From 'Safe Life' to Fracture Mechanics - F111 Aircraft Cold Temperature Proof Testing at RAAF Amberley . Redmond . Gerard . 17 April 2019 . 27 April 2019 . https://web.archive.org/web/20190427131335/https://www.ndt.net/apcndt2001/papers/912/912.htm . dead .
  8. Design and Airworthiness Requirements for Service Aircraft . United Kingdom, Ministry of Defence . 1982 . Defence Standard 00-970.
  9. Book: Design and Airworthiness Requirements for Service Aircraft . United Kingdom, Ministry of Defence . 1982 . Defence Standard 00-970.
  10. Web site: FAA Airworthiness standards transport category airplanes, Damage - tolerance and fatigue evaluation of structure. . 2021-02-02.
  11. Web site: Vibration fatigue test of the F/A-18 empennage . . 26 June 2019.
  12. Web site: The Canadian and Australian F/A-18 International Follow-On Structural Test Project . D.L. . Simpson . N. . Landry . J. . Roussel . L. . Molent . N. . Schmidt . 26 June 2019.
  13. Book: Molent, L. . The History of Structural Fatigue Testing at Fishermans Bend Australia. https://web.archive.org/web/20190626133127/https://apps.dtic.mil/dtic/tr/fulltext/u2/a441814.pdf . live . June 26, 2019 . 26 June 2019 . DSTO-TR-1773 . 2005 .
  14. Enhanced Teardown of Ex-Service F/A-18A/B/C/D Centre Fuselages . L. . Molent . B. . Dixon . S. . Barter . P. . White . T. . Mills . K. . Maxfield . G. . Swanton . B. . Main . 25th ICAF Symposium – Rotterdam, 27–29 May 2009 . 2009.