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Axial crack propagation and arrest in a pressurized cylinder: An experimental-numerical analysis |
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| Authors: | M Kosai A Shimamoto C T Yu A S Kobayashi P W Tan |
| Institution: | 1. Boeing Commercial Airplane Group, 98124-2207, Seattle, WA 2. Saitama Institute of Technology, 369-02, Saitama, Japan 3. Applied Precision, 98027-8929, Issaquah, WA 4. University of Washington, 98195-2600, Seattle, WA 5. Federal Aviation Administration, Technical Center, Atlantic City International Airport, 08405, NJ |
| Abstract: | The feasibility of using a previously developed crack-kinking criterion to predict crack arrest at a tear strap in a pressurized fuselage was studied with instrumented axial rupture tests of 21 models of an idealized fuselage. A rapidly propagating axial crack, which was initiated from a precrack, kinked immediately upon extension and propagated diagonally until it turned circumferentially and propagated along the tear straps. An elastodynamic finite element analysis of the rupturing model fuselage yielded the mixed-mode stress intensity factors,K I andK II , and the remote stress component, σ OX . This numerical procedure was also used to predict the crack trajectories in full-scale fuselage rupture tests. All numerical results agreed well with their measured counterparts regardless of size. |
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