A Monte-Carlo method used to study the fragment impact effect on the industrial facilities
Abstract: -The generated fragments due to the explosion of vessel under pressure may be threats to the surrounding equipments at the impact. The fragment characteristics are number, shape, mass, departure angles, departure velocity. These characteristics are considered as uncertain variables. The authors propose the probability distribution for each variable. A fragment trajectory model concerning its shape is then presented in order to study the impact problem. The numerical simulations using the Monte-Carlo method all… Show more
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Cited by 3 publications
References 7 publications
The article contains sections titled: 1. Process and Plant Safety Analysis 1.1. Qualitative Methods 1.1.1. What If? Analysis 1.1.2. Checklists 1.1.3. Failure Mode and Effects Analysis (FMEA) 1.1.4. Hazard and Operability (HAZOP) Studies 1.2. Qualitative Methods Appropriate for Quantification 1.2.1. Event Tree Analysis 1.2.2. Fault Tree Analysis 1.3. Quantitative Analysis 1.3.1. Failure Rates 1.3.2. Constant Failure Probabilities 1.4. Methods for Increasing Reliability 1.4.1. Maintenance Models 1.4.2. Recurrent Functional Tests 1.5. Reliability Data 1.6. Human Error 1.7. Semiquantitative Methods 1.7.1. LOPA (Layer of Protection Analysis) 1.7.2. SQUAFTA (Semiquantitative Fault Tree Analysis) 1.8. Numerical Evaluation of a Fault Tree Including Reliability Data Comparisons 2. Consequence Analysis 2.1. Pool Formation and Vaporization from Pools 2.2. Vapor Cloud Dispersion 2.2.1. Formulation of the Problem 2.2.2. German Practice 2.3. Pool Fires and Spill Fires 2.3.1. Zones and Measurable Quantities 2.3.2. Physical Characteristics 2.3.3. Spill Fires and Fuel Layer Thickness Effects 2.3.4. Soot Production 2.3.5. Heat Transfer 2.3.6. Large Pool Fires 2.3.7. Modeling of Pool Fires 2.3.8. Conclusions and Outlook 2.4. Flash Fires, Fireballs, and Jet Fires 2.4.1. Flash Fires 2.4.2. Fireballs 2.4.3. Jet Fires 2.4.4. Thermal Radiation Impacts at a Distance from the Source 2.5. Explosions 2.5.1. TNT Equivalency Method 2.5.2. Vapor Cloud Explosions (VCE) 2.5.3. Boiling‐Liquid Expanding‐Vapor Explosion (BLEVE) 2.5.4. Dust Explosions 2.6. Vessel Fragmentation and Missile Flight 2.7. Threshold Values, Probits, Damage 3. Appendix A
The article contains sections titled: 1. Process and Plant Safety Analysis 1.1. Qualitative Methods 1.1.1. What If? Analysis 1.1.2. Checklists 1.1.3. Failure Mode and Effects Analysis (FMEA) 1.1.4. Hazard and Operability (HAZOP) Studies 1.2. Qualitative Methods Appropriate for Quantification 1.2.1. Event Tree Analysis 1.2.2. Fault Tree Analysis 1.3. Quantitative Analysis 1.3.1. Failure Rates 1.3.2. Constant Failure Probabilities 1.4. Methods for Increasing Reliability 1.4.1. Maintenance Models 1.4.2. Recurrent Functional Tests 1.5. Reliability Data 1.6. Human Error 1.7. Semiquantitative Methods 1.7.1. LOPA (Layer of Protection Analysis) 1.7.2. SQUAFTA (Semiquantitative Fault Tree Analysis) 1.8. Numerical Evaluation of a Fault Tree Including Reliability Data Comparisons 2. Consequence Analysis 2.1. Pool Formation and Vaporization from Pools 2.2. Vapor Cloud Dispersion 2.2.1. Formulation of the Problem 2.2.2. German Practice 2.3. Pool Fires and Spill Fires 2.3.1. Zones and Measurable Quantities 2.3.2. Physical Characteristics 2.3.3. Spill Fires and Fuel Layer Thickness Effects 2.3.4. Soot Production 2.3.5. Heat Transfer 2.3.6. Large Pool Fires 2.3.7. Modeling of Pool Fires 2.3.8. Conclusions and Outlook 2.4. Flash Fires, Fireballs, and Jet Fires 2.4.1. Flash Fires 2.4.2. Fireballs 2.4.3. Jet Fires 2.4.4. Thermal Radiation Impacts at a Distance from the Source 2.5. Explosions 2.5.1. TNT Equivalency Method 2.5.2. Vapor Cloud Explosions (VCE) 2.5.3. Boiling‐Liquid Expanding‐Vapor Explosion (BLEVE) 2.5.4. Dust Explosions 2.6. Vessel Fragmentation and Missile Flight 2.7. Threshold Values, Probits, Damage 3. Appendix A
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