The present work shows that weak blast waves that are considered as being harmless can turn to become fatal upon their reflections from walls and corners inside a building. In the experimental part, weak blast waves were generated by using an open-end shock tube. A three level building model was placed in vicinity to the open-end of the used shock tube. The evolved wave pattern inside the building rooms was recorded by a sequence of schlieren photographs; also pressure histories were recorded on the rooms' walls. In addition, numerical simulations of the evolved flow field inside the building were conducted. The good agreement obtained between numerical and experimental results shows the potential of the used code for identifying safe and dangerous places inside the building rooms penetrated by the weak blast wave.
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November 2017
Research-Article
Experimental and Numerical Investigation of Blast Wave Interaction With a Three Level Building
Jacques Massoni,
Jacques Massoni
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
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Laurent Biamino,
Laurent Biamino
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Search for other works by this author on:
Georges Jourdan,
Georges Jourdan
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Search for other works by this author on:
Ozer Igra,
Ozer Igra
Department of Mechanical Engineering,
Ben Gurion University,
Beer Sheva 84105, Israel;
Ben Gurion University,
Beer Sheva 84105, Israel;
Department of Mechanical Engineering,
Peter the Great St. Petersburg
Polytechnic University,
Saint Petersburg 195251, Russia
Peter the Great St. Petersburg
Polytechnic University,
Saint Petersburg 195251, Russia
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Lazhar Houas
Lazhar Houas
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Search for other works by this author on:
Jacques Massoni
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Laurent Biamino
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Georges Jourdan
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Ozer Igra
Department of Mechanical Engineering,
Ben Gurion University,
Beer Sheva 84105, Israel;
Ben Gurion University,
Beer Sheva 84105, Israel;
Department of Mechanical Engineering,
Peter the Great St. Petersburg
Polytechnic University,
Saint Petersburg 195251, Russia
Peter the Great St. Petersburg
Polytechnic University,
Saint Petersburg 195251, Russia
Lazhar Houas
Department of Mechanical Engineering,
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Aix Marseille University,
CNRS, IUSTI,
5 rue E. Fermi,
Marseille Cedex 13 13453, France
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received November 24, 2016; final manuscript received June 24, 2017; published online August 11, 2017. Assoc. Editor: John Abraham.
J. Fluids Eng. Nov 2017, 139(11): 111106 (9 pages)
Published Online: August 11, 2017
Article history
Received:
November 24, 2016
Revised:
June 24, 2017
Citation
Massoni, J., Biamino, L., Jourdan, G., Igra, O., and Houas, L. (August 11, 2017). "Experimental and Numerical Investigation of Blast Wave Interaction With a Three Level Building." ASME. J. Fluids Eng. November 2017; 139(11): 111106. https://doi.org/10.1115/1.4037172
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