Survey on Experimental and Numerical Approaches to Model Underwater Explosions

Camargo, Felipe Vannucchi de

doi:10.3390/jmse7010015

Cited by 21 publications

(13 citation statements)

References 62 publications

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“…The article attempts to collect most of the descriptions of various researchers and implement them for CAE (Computer Aided Engineering) purposes. A similar approach has been proposed in [30]. Table 1 presents formulas necessary to calculate shock waves caused by underwater TNT explosion pressure values and their waveforms.…”

Section: Pressure Wavementioning

confidence: 99%

Pressure Wave Caused by Trinitrotoluene (TNT) Underwater Explosion—Short Review

Kiciński

Szturomski

2020

Applied Sciences

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The development of computational techniques and computer hardware has an impact the analysis of short-term (fast-changing) processes, such as the impact of a non-contact underwater explosion pressure waves. A theory of underwater explosions, gas bubble formation and pressure waves are presented. The course of the pressure wave in time, and its propagation in the acoustic medium are presented. The study presents empirical descriptions of non-contact pressure explosion waves. We propose to use them in simulations of ship hull strength and other objects immersed in liquids that are exposed to the effects of non-contact trinitrotoluene (TNT)-charge explosions. Pressure distributions and their time courses given by authors such as R.H. Cole, J.S. Nawagin, W. Stiepanow, T.E. Farley and H.G. Snay, T.L. Geers and K.S. Hunter are compared. A method of pressure wave modeling using acoustic media implemented in Computer Aided Engineering (CAE) programs is presented. The results of the values and the time course of the pressure acting on the underwater object are given. The influence of FEM (Finite Element Method) mesh density on the obtained results is examined and presented. The aim of the article is to expand our knowledge of underwater explosions, compare mathematical descriptions of the pressure waves developed by different authors and show the differences between them. In addition, we present the distinction between contact and non-contact explosions and analyze how changes in the mesh density of acoustic elements affects the reflection of the incident wave caused by an underwater explosion.

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Section: Pressure Wavementioning

confidence: 99%

Pressure Wave Caused by Trinitrotoluene (TNT) Underwater Explosion—Short Review

Kiciński

Szturomski

2020

Applied Sciences

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“…There are several approaches to analyze explosion such as the Smoothed Partial Hydrodynamic (SPH) Method, Boundary Element Method (BEM) and Finite Volume Method (FVM). These methodologies are reviewed, and a validity check has been carried out [20]. This study utilizes FLACS which adopts FVM, since it is widely used and accepted for explosion analysis in offshore projects and petroleum industries.…”

Section: Flacs Programmentioning

confidence: 99%

Dynamic Response of Drill Floor Considering Propagation of Blast Pressure Subsequent to Blowout

Kim

Lee

2020

Applied Sciences

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Explosions and fire have very critical safety hazard impacts on offshore oil and gas facilities since they are mostly located in remote areas and could induce serious environmental issues. Explosion risk assessment and structure blast analysis are essential for these production facilities, and research studies have been carried out. Explosion due to blowout during drilling operation is also a critical risk for drilling units, and this has not been researched much until the accident of the drilling unit in the Gulf of Mexico in 2010. This paper provides the risk and evaluation of explosion and structure under blast pressure during the drilling operation, whereas previous research studies have mainly been interested in process plants. This study suggests weight saving in drilling units through the consideration of the actual behavior of gas explosion. Weight saving is the priority of offshore unit design due to payload. This research also gives guidelines to select the material-grade-appropriate anti-explosion system through the comparison of several materials by design and result.

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“…The numerical model of the bottom structure defined in ANSYS LS-DYNA [26] with reference to the shell elements was used in this study. The element formulation utilized the fully integrated version of the Belytschko-Tsay [27,28] to suppress hourglass energy during the application of accidental loading to the ship structures. In the analysis, steel was defined while using a plastic-kinematic model (see Table 6) with kinematic hardening being applied to the structure.…”

Section: Geometry and Materialsmentioning

confidence: 99%

Simulation of the Behavior of a Ship Hull under Grounding: Effect of Applied Element Size on Structural Crashworthiness

Prabowo

Putranto

Sohn

2019

JMSE

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This work models the effect of an impact phenomenon-namely the interaction between seabed rock and a ship during its operations-on the ship structure. The collision between a tanker vessel with a conical rock is simulated, a scenario that is similar to the famous grounding of the Exxon Valdez oil tanker. The study uses finite element analysis to simulate numerical parameters that are related to structural response and the contours of the ship hull under impact loading. The traditional element-length-to-thickness (ELT) ratio of 10 is recommended in this work. ELT ratios in the range of 11 to 13 are shown to produce similar results in terms of internal energy, contact force, and structural acceleration. Additionally, the analysis time is reduced by approximately 20% for the recommended ELT ratio. This result is very helpful for researchers using finite element analysis to simulate ship accidents, since the mesh size or length of complex structures is used to maintain the efficiency and accuracy of the simulation results.

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Survey on Experimental and Numerical Approaches to Model Underwater Explosions

Cited by 21 publications

References 62 publications

Pressure Wave Caused by Trinitrotoluene (TNT) Underwater Explosion—Short Review

Pressure Wave Caused by Trinitrotoluene (TNT) Underwater Explosion—Short Review

Dynamic Response of Drill Floor Considering Propagation of Blast Pressure Subsequent to Blowout

Simulation of the Behavior of a Ship Hull under Grounding: Effect of Applied Element Size on Structural Crashworthiness

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