Fatigue analysis optimization.
Lozici-Brinzei, Dorin ; Baran, Daniela ; Tataru, Simion 等
1. INTRODUCTION
The elementary steps in the fatigue analysis and damage tolerance
evaluation are:
* Define the Aircraft Missions
* Develop the global load spectra
* Select critical locations for each Principal Structural Elements
(PSE)
* Calculate nominal stress levels for PSEs and local stress levels
at critical locations
* Calculate fatigue life and Margin of Safety
One of the most relevant questions arising now is about how well we
are now endowed with the tools and knowledge to deal with the above
steps.
If S-N data are available the Miner rule may be adopted to
calculate the fatigue life under spectrum loading.
Figure 1 show the mission profile and stress distribution for
IAR-99.
[FIGURE 1 OMITTED]
Figure 2 shows the mission profile and stress distribution for
civil aircrafts.
[FIGURE 2 OMITTED]
2. GLOBAL LOAD SPECTRUM
Figure 3 shows several associated load spectrum examples
[***CS-32,2003].
[FIGURE 3 OMITTED]
3. FEM ANALYSIS
The stress analysis is performed to determine the stress
distribution within a component, and usually involves relatively
detailed models of airframe sub-components.
The principal normal stresses and maximum shear stress together
with the angle of the principal axis can be determined from the applied
stresses (fx, fy and fs) using the following equations [Bruhn, 1973],
[Niu, 2005]:
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII]
The effective stress for von Mises is expressed as [Petre, 1984]:
[??] = [square root of 1/2 [[([[sigma].sub.x] -
[[sigma].sub.y]).sup.2] + [([[sigma].sub.y] + [[sigma].sub.z]).sup.2] +
[([[sigma].sub.z] - [[sigma].sub.x]).sup.2]] + 3([[tau].sup.2.sub.xy] +
[[tau].sup.2.sub.yz] + [[tau].sup.2.sub.zx])]
[FIGURE 4 OMITTED]
[FIGURE 5 OMITTED]
[FIGURE 6 OMITTED]
4. FATIGUE LIFE CALCULATION
Constant and variable amplitude loading may be considered in
calculating fatigue life. By using an SN curve, designers can calculate
the number of such cycles rapidly leading to the component failure.
This theory also assumes that the damage caused by a stress cycle
is independent of where it occurs in the load history, and that the rate
of the damage accumulation is independent of the stress level.
[FIGURE 7 OMITTED]
The result, or Damage (D), is expressed as a fraction of the
failure. The component failure occurs when D = 1.0, so, if D = 0.85 then
85% of the component's life has been consumed.
[FIGURE 8 OMITTED]
[FIGURE 9 OMITTED]
5. CONCLUSIONS
The tools and approaches discussed in this review can help
designers to improve the component safety while reducing
over-engineered, heavy, and costly designs.
FEA provides excellent tools for studying fatigue by the SN
approach, because the input consists of a linear elastic stress field,
and FEA allows consideration of the possible interactions of multiple
load cases. Because of its ease of implementation and the large amounts
of available material data, the most commonly used method is SN. By
making use of today's technology to avoid fatigue, catastrophes can
often be prevented.
6. REFERENCES
*** (2003).CS-23 Certification Specifications for Normal, Utility,
Aerobatic, and Commuter Category Aero planes, 14 Nov.
*** (2008), MIL HDBK 5J, Metallic Materials and Elements for
Aerospace Vehicle Structures
Bruhn, E. F. (1973), Analysis and Design of Flight Vehicle
Structures, Tri-State Offset Co, Cincinaty, ISBN-13: 978-0961523404
Niu, M. (2005), Airframe Stress Analysis and Sizing, Conmilet Press
Ltd, 2nd Edition, New York, ISBN-13: 978-9627128083
Roark, R.J., Young, W.C. (2001), Formulas for Stress & Strains,
MCGRAW-HILL International, 7th Edition, New York, ISBN:
978-0-07-072542-3
Petre A (1984), Calculul structurilor de aviatie, Editura Tehnica,
Bucuresti.
Peterson, R.E., (2008), Stress Concentration Factors, John Wiley
& Sons, 3rd Edition, San Francisco, ISBN 978-0-0470-04824-5
