| 289 - 290 |
Sixth international symposium on hazards, prevention, and mitigation of industrial explosions: Twelfth international colloquium on dust explosions and seventh colloquium on gas, vapor, liquid and hybrid explosions
Amyotte PR |
| 291 - 302 |
Review of the DESC project
Skjold T |
| 303 - 309 |
Thermo-kinetic modelling of dust explosions
Di Benedetto A, Russo P |
| 310 - 316 |
Effect of transient heat transfer on ignition of solid particles
Frolov SM, Avdeev KA, Frolov FS |
| 317 - 321 |
About stability of the ignition process of small solid particle
Fedorov AV, Shulgin AV |
| 322 - 329 |
Ignitability characteristics of aluminium and magnesium dusts that are generated during the shredding of post-consumer wastes
Nifuku M, Koyanaka S, Ohya H, Barre C, Hatori M, Fujiwara S, Horiguchi S, Sochet I |
| 330 - 336 |
Influence of the oxide content on the ignition energies of aluminium powders
Baudry G, Bernard S, Gillard P |
| 337 - 348 |
Explosion temperatures and pressures of metals and other elemental dust clouds
Cashdollar KL, Zlochower IA |
| 349 - 365 |
Development of a method for predicting the ignition of explosive atmospheres by mechanical friction and impacts (MECHEX)
Proust C, Hawksworth S, Rogers R, Beyer M, Lakic D, Raveau D, Herve P, Pina N, Petitfrere C, Lefebvre X |
| 366 - 374 |
Shock-induced dust ignition in curved pipeline with steady flow
Semenov I, Frolov S, Markov V, Utkin P |
| 375 - 386 |
A quantitative risk assessment tool for the external safety of industrial plants with a dust explosion hazard
van der Voort MM, Klein AJJ, de Maaijer M, van den Berg AC, van Deursen JR, Versloot NHA |
| 387 - 395 |
Modeling of BP texas city refinery incident
Khan FI, Amyotte PR |
| 396 - 401 |
Electrostatic spark ignition of sensitive dust clouds of MIE < 1 mJ
Eckhoff RK, Randeberg E |
| 402 - 408 |
Test methodology for determining the incendiary nature and electrostatic discharge characteristics of plastic surfaces
Dastidar AG, Dahn CJ |
| 409 - 416 |
Computation of particles' ascent from a cavity behind passing shock wave
Bedarev IA, Gosteev YA, Fedorov AV |
| 417 - 426 |
Modelling of dust lifting process behind propagating shock wave
Zydak P, Klemens R |
| 427 - 432 |
Hazard evaluation of hydrogen-air deflagration with flame propagation velocity measurement by image velocimetry using brightness subtraction
Otsuka T, Saitoh H, Mizutani T, Morimoto K, Yoshikawa N |
| 433 - 438 |
Numerical analysis of hydrogen deflagration mitigation by venting through a duct
Makarov D, Verbecke F, Molkov V |
| 439 - 446 |
Shock-induced ignition of hydrogen gas during accidental or technical opening of high-pressure tanks
Golub VV, Baklanov DI, Bazhenova TV, Bragin MV, Golovastov SV, Ivanov MF, Volodin VV |
| 447 - 454 |
An application of 3D gasdynamic modeling for the prediction of overpressures in vented enclosures
Karnesky J, Chatterjee P, Tamanini F, Dorofeev S |
| 455 - 461 |
Numerical analysis of gas explosion inside two rooms connected by ducts
Hashimoto A, Matsuo A |
| 462 - 469 |
Determination of the maximum effective burning velocity of dust-air mixtures in constant volume combustion
Pu YK, Jia F, Wang SF, Skjold T |
| 470 - 476 |
Determination of turbulent burning velocities of dust air mixtures with the open tube method
Schneider H, Proust C |
| 477 - 485 |
Vapor flammability above aqueous solutions of flammable liquids
Brooks MR, Crowl DA |
| 486 - 493 |
Effect of self-inhibition at a flame propagation in rich gaseous mixtures of combustible-air-diluent
Azatyan VV, Shebeko YN, Shebeko AY, Navzenya VY |
| 494 - 500 |
An influence of oxygen content in an oxidizing atmosphere on inhibitive action of fluorinated agents on a hydrogen flame
Azatyan VV, Shebeko YN, Shebeko AY, Navzenya VY, Tomilin AV |
| 501 - 508 |
Reactive shock and detonation propagation in U-bend tubes
Frolov SM, Aksenov VS, Shamshin IO |
| 509 - 516 |
Impact of a shock wave on a structure on explosion at altitude
Trelat S, Sochet I, Autrusson B, Cheval K, Loiseau O |
| 517 - 522 |
"Vybuchovy trojuhelnik": A software tool for evaluation of explosibility of coal mine atmosphere
Janovsky B, Zigmund J |
| 523 - 529 |
Dust explosion incidents and regulations in the United States
Blair AS |
| 530 - 535 |
New dust explosion venting design requirements for turbulent operating conditions
Zalosh R |
| 536 - 540 |
The lower explosion point - A good measure for explosion prevention: Experiment and calculation for pure compounds and some mixtures
Brandes E, Mitu M, Pawel D |
| 541 - 550 |
Numerical simulation of wind-aided flame propagation over horizontal surface of liquid fuel in a model tunnel
Wang HY, Joulain P |
| 551 - 561 |
Influence of ignition position and obstacles on explosion development in methane-air mixture in closed vessels
Kindracki J, Kobiera A, Rarata G, Wolanski P |
| 562 - 569 |
Modeling of n-butane ignition, combustion, and preflame oxidation in the 20-1 vessel
Frolov SM, Basevich VY, Smetanyuk VA, Belyaev AA, Pasman HJ |
| 570 - 577 |
Planar detonation structure for chain-branching kinetics with large activation energy and small initiation rate
Liang Z, Bedard-Tremblay L, Bauwens L |
| 578 - 583 |
Minimum propagation diameter and thickness of high explosives
Petel OE, Mack D, Higgins AJ, Turcotte R, Chan SK |
| 584 - 588 |
Detonation characteristics of ammonium nitrate and activated carbon mixtures
Miyake A, Kobayashi H, Echigoya H, Kubota S, Wada Y, Ogata Y, Arai H, Ogawa T |
| 589 - 598 |
Airbag for the closing of pipelines on explosions and leakages
Eisenreich N, Neutz J, Seiler F, Hensel D, Stancl M, Tesitel J, Price R, Rushworth S, Markert F, Marcelles I, Schwengler P, Dyduch Z, Lebecki K |
| 599 - 606 |
Measuring the violence of dust explosions with the "201 sphere" and with the standard "ISO 1 m(3) vessel" - Systematic comparison and analysis of the discrepancies
Proust C, Accorsi A, Dupont L |
| 607 - 615 |
Post-explosion observations of experimental mine and laboratory coal dust
Cashdollar KL, Weiss ES, Montgomery TG, Going JE |
| 616 - 620 |
Coal dust particle size survey of US mines
Sapko MJ, Cashdollar KL, Green GM |
| 621 - 643 |
Flixborough: A final footnote
Venart JES |
| 644 - 650 |
Lessons learned from recent incidents: Facility siting, atmospheric venting, and operator information systems
Mannan MS, West HH, Berwanger PC |
| 651 - 658 |
Fire and explosion risk assessment for large-scale oil export terminal
Shebeko YN, Bolodian IA, Molchanov VP, Deshevih YI, Gordlenko DM, Smolin IM, Kirillov DS |
| 659 - 663 |
Deflagration suppression using expanded metal mesh and polymer foams
Zalosh R |
| 664 - 674 |
Dynamics of dust explosions suppression by means of extinguishing powder in various industrial conditions
Klemens R, Gieras M, Kaluzny M |
| 675 - 687 |
Moderation of dust explosions
Amyotte PR, Pegg MJ, Khan FI, Nifuku M, Tan YX |
| 688 - 690 |
Decomposing deflagration properties of acetylene under low temperatures
Mizutani T, Miyake A, Matsui H |
| 691 - 697 |
Flame propagation in hybrid mixture of coal dust and methane
Liu Y, Sun JH, Chen DL |
| 698 - 707 |
Explosibility of hydrogen-graphite dust hybrid mixtures
Denkevits A |
