Damage of Solid Phase due to Explosion Effect Using Uzawa’s Algorithm

The paper deals with the impact of explosion on the damage development in the structure that forms a boundary of closed or semi-closed space – tunnel - the explosion in which is initiated. In the previous publications of the author the penalty formulation of the problem was used; now Uzawa’s algorit...

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Bibliographic Details
Published in:Key engineering materials 2019-12, Vol.827, p.1-6
Main Author: Prochazka, Petr-Pavel
Format: Article
Language:English
Subjects:
Airspace
ALE (numerical method)
Algorithms
Conservation equations
Elasticity
Explosions
Impact damage
Linear equations
Mathematical analysis
Nonlinear equations
Shock wave propagation
Shock waves
Solid phases
Structural damage
Time dependence
Uzawa's algorithm
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Summary:The paper deals with the impact of explosion on the damage development in the structure that forms a boundary of closed or semi-closed space – tunnel - the explosion in which is initiated. In the previous publications of the author the penalty formulation of the problem was used; now Uzawa’s algorithm is applied, which appears to be more promising algorithm accelerating the iterative process of damage development in the structure. Shock waves propagating in the airspace can be described by non-linear conservation equations starting with Euler’s equations which are used to be solved by forward differences of the system of pseudo-linear equations, using Arbitrary Lagrangian-Euler Method (ALE). Conservation equations are formulated for two phases: air and solid. In the solid phase, concrete lining, the time-dependent elasticity of free rectangular elements undergoing the damage, is solved by uniformly distributed boundary elements. The paper is focused on damage to the concrete lining due to impact of the explosion in the tunnel.
ISSN:1013-9826
1662-9795
1662-9795
DOI:10.4028/www.scientific.net/KEM.827.1