Numerical study on the structural response of blast-loaded thin aluminium and steel plates

•The inelastic response of blast-loaded thin plates is studied numerically.•Numerical simulations are validated against experimental data.•The negative phase dominated the response at some loading and structural conditions.•The influence of the negative phase was found to depend on the timing and ma...

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Bibliographic Details
Published in:International journal of impact engineering 2017-01, Vol.99, p.131-144
Main Authors: Aune, V., Valsamos, G., Casadei, F., Larcher, M., Langseth, M., Børvik, T.
Format: Article
Language:English
Subjects:
Airblast loading
Aluminum
Blast resistance
Blasting (explosive)
Computer simulation
Detonation
Ductile failure
Dynamic response
Energy consumption
Erosion
EUROPLEXUS
Explosions
Explosives
Finite element method
Negative phase
Overpressure
Reversed snap buckling
Shock waves
Simulation
Steel plates
Structural response
Tearing
Thin plates
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Summary:•The inelastic response of blast-loaded thin plates is studied numerically.•Numerical simulations are validated against experimental data.•The negative phase dominated the response at some loading and structural conditions.•The influence of the negative phase was found to depend on the timing and magnitude of the peak negative pressure.•Ductile failure was also predicted by using an energy-based failure criterion. The inelastic response of thin aluminium and steel plates subjected to airblast loading is studied numerically and validated against experimental data. Special focus is placed on the influence of elastic effects and negative phase on the structural response. The blast loading was varied by detonating spherical charges of plastic explosives at various stand-off distances relative to the centre point of the plates. The numerical results obtained with the finite element code EUROPLEXUS were in good agreement with the experiments and predicted the entire range of structural response from complete tearing at the supports to a more counter-intuitive behaviour (CIB) where the final configuration of the plate was in the opposite direction to the incident blast wave due to reversed snap buckling (RSB). RSB attracted special attention since this is an unstable configuration sensitive to small changes in the loading and in structural characteristics. The negative phase of the blast pressure is usually neglected in blast-resistant design. However, the numerical simulations showed that the negative overpressure dominated the structural response and led to RSB at some loading and structural conditions. Two distinctive types of CIB were identified and both were found to depend on the timing and magnitude of the peak negative overpressure relative to the dynamic response of the plates. The study also revealed that CIB may occur in thin plates when the negative impulse is of the same order of magnitude as the positive impulse. The partial and complete failure along the boundaries observed in some of the tests was also successfully recreated in the simulations by using an energy-based failure criterion and element erosion.
ISSN:0734-743X
1879-3509
DOI:10.1016/j.ijimpeng.2016.08.010