NUMERICAL SIMULATION FOR LARGE UNCONTAINED ENGINE DEBRIS IMPACT AND PROTECTION METHODS

In order to evaluate the impact process induced by uncontained failure,numerical simulation for one-third HPT( High Pressure Turbine) disk impact was carried out under different obliquity angles and residual fuel volumes in the wing structure. The study,which resulted in continuous dynamic response,...

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Bibliographic Details
Published inJi xie qiang du Vol. 38; pp. 1035 - 1040
Main Authors LI KeJun, PEI Yang, SONG BiFeng, YI HuaHui
Format Journal Article
LanguageChinese
Published Editorial Office of Journal of Mechanical Strength 15.10.2016
Subjects
Uncontained failure;Large engine debris;Turbine cowl;Integral fuel tank;Numerical simulation
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Summary:In order to evaluate the impact process induced by uncontained failure,numerical simulation for one-third HPT( High Pressure Turbine) disk impact was carried out under different obliquity angles and residual fuel volumes in the wing structure. The study,which resulted in continuous dynamic response,focused on the interaction among debris,turbine cowl and integral fuel tank. The constitutive material mode and failure criteria proposed by Johnson-Cook were applied in solid element definition,while SPH( Smooth Particle Hydrodynamics) model was used for fuel particles. The analysis involved the debris velocity history,fuel tank deformation along with the stress distribution changes during the whole process. It is shown from the results that with the increase of obliquity angle and residual fuel volume, the velocity loss and energy reduction rise correspondingly. The turbine cowl absorbs most of the debris energy while fuel also contributes to the absorption due to its viscidity. Hydrodynamic ram fails to cause le
ISSN:1001-9669
DOI:10.16579/j.issn.1001.9669.2016.05.023