| 1 - 12 |
Dynamic behaviour of direct spring loaded pressure relief valves in gas service: II reduced order modelling
Hos CJ, Champneys AR, Paul K, McNeely M |
| 13 - 19 |
Theoretical estimation of the lower flammability limit of fuel-air mixtures at elevated temperatures and pressures
Wan X, Zhang Q, Shen SL |
| 20 - 29 |
An improved model for heavy gas dispersion using time-varying wind data: Mathematical basis, physical assumptions, and case studies
Li Y, Chen DS, Cheng SY, Xu TT, Huang Q, Guo XR, Ma X, Yang N, Liu XX |
| 30 - 38 |
Probabilistic multiple model neural network based leak detection system: Experimental study
Abdulla MB, Herzallah R |
| 39 - 44 |
Experimental investigation on shock waves generated by pressurized gas release through a tube
Duan QL, Xiao HH, Gao W, Shen XB, Wang QS, Sun JH |
| 45 - 53 |
Experimental and simulation studies on the influence of carbon monoxide on explosion characteristics of methane
Deng J, Cheng FM, Song Y, Luo ZM, Zhang YT |
| 54 - 62 |
Root causes of hydrocarbon leaks on offshore petroleum installations
Vinnem JE, Roed W |
| 63 - 71 |
Evaluating the overall efficiency of a flameless venting device for dust explosions
Chao J, Dorofeev SB |
| 72 - 83 |
Development of generic bow-tie diagrams of accidental scenarios triggered by flooding of industrial facilities (Natech)
El Hajj C, Piatyszek E, Tardy A, Laforest V |
| 84 - 91 |
Major accident prevention and management of information systems security in technology-based work processes
Albrechtsen E |
| 92 - 97 |
Minimum ignition energy of mixtures of combustible dusts
Hosseinzadeh S, Norman F, Verplaetsen F, Berghmans J, Van den Bulck E |
| 98 - 107 |
Uncertainties in QRA: Analysis of losses of containment from piping and implications on risk prevention and mitigation
Milazzo MF, Vianello C, Maschio G |
| 108 - 119 |
PLS-based EWMA fault detection strategy for process monitoring
Harrou F, Nounou MN, Nounou HN, Madakyaru M |
| 120 - 124 |
A modified steady-state model for evaluation of ammonia concentrations behind a water curtain
Cheng C, Tan W, Du H, Liu LY |
| 125 - 133 |
Analysis of gas dispersion and ventilation within a comprehensive CAD model of an offshore platform via computational fluid dynamics
Kashi E, Mirzaei F, Mirzaei F |
| 134 - 145 |
A new approach to determine relieving temperature and thermodynamic behavior of trapped single and multi-phase fluid exposed to fire
Deilamani KS, Assar M |
| 146 - 157 |
Numerical study on dust movement and dust distribution for hybrid ventilation system in a laneway of coal mine
Wang YC, Luo G, Geng F, Li YB, Li YL |
| 158 - 166 |
Identification of managerial shaping factors in a petrochemical plant by resilience engineering and data envelopment analysis
Azadeh A, Haghighi SM, Salehi V |
| 167 - 170 |
On the mechanism of a BLEVE occurrence due to fire engulfment of tanks with overheated liquids
Shebeko YN, Shebeko AY |
| 171 - 182 |
Modeling of the venting of an untempered system under runaway conditions
Moreno VC, Kanes R, Wilday J, Vechot L |
| 183 - 184 |
Guest perspective on Bhopal - Dennis C. Hendershot Why can't we do better? Thoughts on the 30th anniversary of the Bhopal tragedy
[Anonymous] |
| 187 - 187 |
Tenth International Symposium on Hazards, Prevention, and Mitigation of Industrial Explosions
Skjold T |
| 188 - 196 |
Flame propagation mechanisms in dust explosions
Gao W, Mogi T, Yu JL, Yan XQ, Sun JH, Dobashi R |
| 197 - 204 |
Collecting representative dust samples: A comparison of various sampling methods in underground coal mines
Harris ML, Alexander D, Harteis SP, Sapko MJ |
| 205 - 215 |
Effect of shock strength on dust entrainment behind a moving shock wave
Chowdhury AY, Johnston HG, Marks B, Mannan MS, Petersen EL |
| 216 - 224 |
Structure and flame speed of dilute and dense layered coal-dust explosions
Houim RW, Oran ES |
| 225 - 231 |
Numerical simulation of dust dispersion using molecular-kinetic model for description of particle-to-particle collisions
Khmel T, Fedorov A |
| 232 - 238 |
Effect of scale on freely propagating flames in aluminum dust clouds
Julien P, Vickery J, Whiteley S, Wright A, Goroshin S, Bergthorson JM, Frost DL |
| 239 - 245 |
Explosion behaviour of metallic nano powders
Krietsch A, Scheid M, Schmidt M, Krause U |
| 246 - 253 |
Suppression of metal dust deflagrations
Taveau J, Vingerhoets J, Snoeys J, Going J, Farrell T |
| 254 - 259 |
Drying of combustible powders - Risk & mitigation
Febo HL |
| 260 - 267 |
Dust collector explosions: A quantitative hazard evaluation method
Zalosh R |
| 268 - 272 |
Correlation of p(max) and K-St to specific surface area and calorific value of a dust
Gerhold M, Stahmer KW |
| 273 - 282 |
Scaling of dust explosion violence from laboratory scale to full industrial scale - A challenging case history from the past
Eckhoff RK |
| 283 - 288 |
Flame propagation in lycopodium/air mixtures below atmospheric pressure
Kern H, Wieser GJ, Raupenstrauch H |
| 289 - 297 |
Explosion reactivity characterisation of pulverised torrefied spruce wood
Medina CH, Sattar H, Phylaktou HN, Andrews GE, Gibbs BM |
| 298 - 309 |
Application of CFD on the sensitivity analyses of some parameters of the modified Hartmann tube
Murillo C, Bardin-Monnier N, Munoz F, Dufaud O |
| 310 - 319 |
Agricultural waste pulverised biomass: MEC and flame speeds
Saeed MA, Medina CH, Andrews GE, Phylaktou HN, Slatter D, Gibbs BM |
| 320 - 327 |
Biomass explosion testing: Accounting for the post-test residue and implications on the results
Slatter DJF, Sattar H, Medina CH, Andrews GE, Phylaktou HN, Gibbs BM |
| 328 - 336 |
Minimum Ignition Temperature of layer and cloud dust mixtures
Danzi E, Marmo L, Riccio D |
| 337 - 344 |
Influence of inert materials on the self-ignition of flammable dusts
Binkau B, Wanke C, Krause U |
| 345 - 353 |
Detection of incipient self-ignition process in solid fuels through gas emissions methodology
Anez NF, Torrent JG, Pejic LM, Olmedo CG |
| 354 - 359 |
Determination of spontaneous combustion of thermally dried sewage sludge
Pejic LM, Anez NF, Torrent JG, Ramirez-Gomez A |
| 360 - 366 |
Detonations and vapor cloud explosions: Why it matters
Johnson DM, Tomlin GB, Walker DG |
| 367 - 372 |
Deflagration to detonation transition in a vapour cloud explosion in open but congested space: Large scale test
Pekalski A, Puttock J, Chynoweth S |
| 373 - 381 |
Numerical simulation of deflagration-to-detonation transition in large confined volumes
Hasslberger J, Boeck LR, Sattelmayer T |
| 382 - 388 |
DDT and detonation propagation limits in an obstacle filled tube
Cross M, Ciccarelli G |
| 389 - 395 |
Gas flame acceleration in long ducts
Proust C |
| 396 - 405 |
Numerical study of cellular detonation structures of methane mixtures
Trotsyuk AV, Fomin PA, Vasil'ev AA |
| 406 - 417 |
Influence of non-reactive particle cloud on heterogeneous detonation propagation
Fedorov AV, Kratova YV |
| 418 - 430 |
Medium-scale experiments on vented hydrogen deflagration
Kuznetsov M, Friedrich A, Stern G, Kotchourko N, Jallais S, L'Hostis B |
| 431 - 440 |
Vent burst pressure effects on vented gas explosion reduced pressure
Fakandu BM, Andrews GE, Phylaktou HN |
| 441 - 448 |
Un-ignited and ignited high pressure hydrogen releases: Concentration -turbulence mapping and overpressure effects
Daubech J, Hebrard J, Jallais S, Vyazmina E, Jamois D, Verbecke F |
| 449 - 461 |
Investigation of concentration effects on the flame acceleration in vented channels
Hisken H, Enstad GA, Middha P, van Wingerden K |
| 462 - 472 |
A compressible-LEM turbulent combustion subgrid model for assessing gaseous explosion hazards
Maxwell BM, Falle SAEG, Sharpe G, Radulescu MI |
| 473 - 479 |
Laminar burning velocities of various silanes
Chao J, Lee JHS, Bauwens CR, Dorofeev SB |
| 480 - 489 |
CGA G-13 large-scale silane release tests - Part I. Silane jet flame impingement tests and thermal radiation measurement
Ngai EY, Fuhrhop R, Chen JR, Chao J, Bauwens CR, Mjelde C, Miller G, Sameth J, Borzio J, Telgenhoff M, Wilson B |
| 490 - 498 |
CGA G-13 large-Scale silane release test - Part II. Unconfined silane-air explosions
Ngai EY, Fuhrhop R, Chen JR, Chao J, Bauwens CR, Mjelde C, Miller G, Sameth J, Borzio J, Telgenhoff M, Wilson B |
| 499 - 506 |
Lower explosion limit of hybrid mixtures of burnable gas and dust
Addai EK, Gabel D, Krause U |
| 507 - 510 |
Explosion of lycopodium-nicotinic acid-methane complex hybrid mixtures
Sanchirico R, Russo P, Saliva A, Doussot A, Di Sarli V, Di Benedetto A |
| 511 - 523 |
Hybrid H-2/Al dust explosions in Siwek sphere
Denkevits A, Hoess B |
| 524 - 533 |
Safety-related conclusions for the application of ultrasound in explosive atmospheres
Simon LH, Wilkens V, Beyer M |
| 534 - 540 |
Hot surfaces generated by sliding metal contacts and their effectiveness as an ignition source
Meyer L, Beyer M, Krause U |
| 541 - 545 |
A numerical approach to investigate the maximum permissible nozzle diameter in explosion by hot turbulent jets
Ghorbani A, Markus D, Steinhilber G, Maas U |
| 546 - 554 |
Fluorinated halon replacement agents in explosion inerting
Gatsonides JG, Andrews GE, Phylaktou HN, Chattaway A |
| 555 - 563 |
Ignition hazard evaluation on A2L refrigerants in situations of service and maintenance
Imamura T, Kamiya K, Sugawa O |
| 564 - U574 |
Determination of explosion limits - Criterion for ignition under non-atmospheric conditions
Tschirschwitz R, Schroder V, Brandes E, Krause U |
