主 办:爆炸科学与技术国家重点实验室
安全与防护协同创新中心
报告题目:Explosion and Fire - QRA Methodology Using FLACS
报告人:Prof. Jan Roar Bakke
Chairman of Process Safety Subcommittee,
International Organization of Oil and Gas Producers
时间:2017年3月2日上午10:00
地点:北京理工大学9号教学楼617房间
个人简介:
Jan Roar Bakke acquired his Ph.D qualification in applied mathematics (mathematical modeling of gas explosions) in University of Bergen in 1986. He has extensive working experience in safety and risk management in companies such as Statoil (the Norwegian State Oil Company), Gexcon, CMR (Christian Michelsen Research) and CMI (Chr. Michelsen Institute). In October 2016 he returned to Gexcon, a world-leading company in the field of safety and risk management and advanced dispersion, explosion and fire modelling, as Director of Global Business Development. Bakke’s work centers on aspects of explosion and fire safety, process/technical safety and risk analysis. During his time in Statoil he was appointed chairman of the Process Safety Subcommittee in the International Organization of Oil and Gas Producers (IOGP). Examples of previous experience is guest lecturer on gas explosions at the Federal University of Rio de Janeiro (UFRJ), panel member for ISO 19901-3 “Petroleum and natural gas industries — Specific requirements for offshore structures — Part 3: Topsides structure”, chairman of Explosion Working Group and member of Fire Working Group in research programme 'Blast and Fire Engineering for Topside Structures‘(initiated as a consequence of Piper Alpha), and expert witness on gas explosions in the Piper Alpha Enquiry. He is also Adjunct Professor of Technical Safety at the University of Stavanger in Norway.
Abstract: The propagation and loading from explosions and fires in industrial environments are strongly dependent on interaction between explosion/fire-generated flow and local confinement and congestion. The presentation provides an overview of relevant parameters and their effects on explosion and fire characteristics. Particularly for the case of explosions, it is often impossible to design for worst case accidents. Hence analyses of potential explosion loads tend to be done as probabilistic analyses. A description of this methodology, that has been applied for almost 20 years by oil and gas industry, will be provided. In recent years probabilistic fire analyses have also been performed, albeit not to the same extent as for explosions.
