| 195 - 196 |
Bhopal Gas Tragedy and its effects on process safety
Gupta JP |
| 197 - 199 |
Bhopal Gas Tragedy and its effects on process safety
Gupta JP |
| 200 - 204 |
Commentary on keynote lectures and papers presented at the conference
Gupta JP |
| 205 - 208 |
The unfolding of Bhopal disaster
Chouhan TR |
| 209 - 212 |
The Bhopal gas tragedy - A perspective
Bisarya RK, Puri S |
| 213 - 217 |
The Bhopal gas leak: Analyses of causes and consequences by three different models
Eckerman I |
| 218 - 224 |
The legacy of Bhopal: The impact over the last 20 years and future direction
Mannan AS, West HH, Krishna K, Aldeeb AA, Keren N, Saraf SR, Liu YS, Gentile M |
| 225 - 237 |
Current status and expected future trends in dust explosion research
Eckhoff RK |
| 238 - 244 |
Implementing inherent safety throughout process lifecycle
Hurme M, Rahman M |
| 245 - 253 |
A simple model for calculating chlorine concentrations behind a water spray in case of small releases
Dandrieux-Bony A, Dimbour JP, Dusserre G |
| 254 - 260 |
Export inherent safety NOT risk
Edwards DW |
| 261 - 263 |
Bhopal disaster - a personal experience
Gehlawat JK |
| 264 - 267 |
Bhopal gas tragedy: scientific challenges and lessons for future
Sriramachari S |
| 268 - 273 |
Aftermath of the world's worst chemical disaster Bhopal, December 1984
Acquilla S, Bertell R, Dhara VR, Tognoni G |
| 274 - 282 |
Literary and economic impact of the Bhopal gas tragedy
Saraf S, Karanjikar M |
| 283 - 292 |
Steady-state analyses for reactive distillation control: An MTBE case study
Singh BP, Singh R, Kumar MVP, Kaistha N |
| 293 - 300 |
Combating interference by unauthorised persons
Uth HJ |
| 301 - 309 |
Site security for chemical process industries
Bajpai S, Gupta JP |
| 310 - 326 |
I2SI: A comprehensive quantitative tool for inherent safety and cost evaluation
Khan FI, Amyotte PR |
| 327 - 334 |
Comparison of inherent safety indices in process concept evaluation
Rahman M, Heikkila AM, Hurme M |
| 335 - 352 |
Assessment of chemical process hazards in early design stages
Shah S, Fischer U, Hungerbuhler K |
| 353 - 359 |
Bhopal and its effects on the Canadian regulatory framework
Lacoursiere PEJP |
| 360 - 364 |
The implementation of the SEVESO II legislation in the Polish major hazard industry
Markowski AS |
| 365 - 374 |
The Bhopal tragedy: its influence on process and community safety as practiced in the United States
Willey RJ, Crowl DA, Lepkowski W |
| 375 - 379 |
The post-Bhopal and post-9/11 transformations in chemical emergency prevention and response policy in the United States
Belke JC, Dietrich DY |
| 380 - 383 |
Mixing hazard evaluation of organic peroxides with other chemicals
Miyake A, Yamada N, Ogawa T |
| 384 - 391 |
Catalytic decomposition of hydrogen peroxide in the presence of alkylpyridines: Runaway scenarios studies
Papadaki M, Marques-Domingo E, Gao J, Mahmud T |
| 392 - 396 |
Solubility and calorimetric study of the effects of gas environment on the decomposition of o-nitrobenzoyl chloride
Lever SD, Papadaki M |
| 397 - 402 |
Application of risk based inspection in refinery and processing piping
Chang MK, Chang RR, Shu CM, Lin KN |
| 403 - 413 |
Dangerous good transportation by road: from risk analysis to emergency planning
Fabiano B, Curro F, Reverberi AP, Pastorino R |
| 414 - 422 |
Toward an integrative approach of the industrial risk management process in France
Salvi O, Merad M, Rodrigues N |
| 423 - 432 |
Thermal shielding by water spray curtain
Buchlin JM |
| 433 - 442 |
Rain-out investigation: Initial droplet size measurement
Bigot JP, Touil A, Bonnet P, Lacome JM |
| 443 - 454 |
Revised fire consequence models for offshore quantitative risk assessment
Pula R, Khan FI, Veitch B, Amyotte PR |
| 455 - 459 |
Study on the early stage of runaway reaction using Dewar vessels
Li XR, Koseki H |
| 460 - 464 |
Thermal decomposition kinetic of liquid organic peroxides
Li XR, Koseki H |
| 465 - 468 |
Explosion properties of highly concentrated ozone gas
Koike K, Nifuku M, Izumi K, Nakamura S, Fujiwara S, Horiguchi S |
| 469 - 473 |
A comparative study on the autoxidation of dimethyl ether (DME) comparison with diethyl ether (DEE) and diisopropyl ether (DIPE)
Naito M, Radcliffe C, Wada Y, Hoshino T, Liu XM, Arai M, Tamura M |
| 474 - 480 |
Using consequence analysis on some chlorine operation hazards and their possible effects on neighborhoods in central Taiwan
Horng JJ, Lin YS, Shu CM, Tsai E |
| 481 - 487 |
City hazardous gas monitoring network
Abbaspour M, Mansouri N |
| 488 - 501 |
Determination of human error probabilities for offshore platform musters
DiMattia DG, Khan FI, Amyotte PR |
| 502 - 505 |
Dilution with air to minimise consequences of toxic/flammable gas releases
Gupta JP |
| 506 - 511 |
Heavy gas dispersion by water spray curtains: A research methodology
Hald K, Buchlin JM, Dandrieux A, Dusserre G |
| 512 - 519 |
Ammonia large scale atmospheric dispersion experiments in industrial configurations
Bouet R, Duplantier S, Salvi O |
| 520 - 525 |
Real-time response system for the prediction of the atmospheric transport of hazardous materials
Alhajraf S, Al-Awadhi L, Al-Fadala S, Al-Khubaizi A, Khan AR, Baby S |
| 526 - 530 |
Chlorine leakage from bonnet of a valve in a bullet - a case study
Gangopadhyay RK, Das SK, Mukherjee M |
| 531 - 536 |
Incident investigation of mono-nitro toluene still explosion
Sachdev A, Todd J |
| 537 - 548 |
Lessons after Bhopal: CSB a catalyst for change
Joseph G, Kaszniak M, Long L |
| 549 - 552 |
The role of local communities in chemical accident prevention and preparedness
Gablehouse TR |
| 553 - 557 |
Effectiveness of the designed safety education programme modules by their implementation in selected industries
Elangovan RK, Mohammed KP, Mohan S |
