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dc.contributor.authorHaugen, Stein
dc.contributor.authorEdwin, Nathaniel John
dc.contributor.authorVinnem, Jan Erik
dc.contributor.authorBrautaset, Olav
dc.contributor.authorNyheim, Ole Magnus
dc.contributor.authorZhu, Tiantian
dc.contributor.authorTuft, Vegard Larsen
dc.date.accessioned2017-11-23T12:39:48Z
dc.date.available2017-11-23T12:39:48Z
dc.date.created2016-08-16T13:10:40Z
dc.date.issued2016
dc.identifier.citationInstitution of Chemical Engineers Symposium Series. 2016, 2016-January (161), .nb_NO
dc.identifier.issn0307-0492
dc.identifier.urihttp://hdl.handle.net/11250/2467818
dc.description.abstractDesign of complex technical systems with potential for major accidents, such as nuclear power plants, offshore installations and high hazard process facilities, is often supported by quantitative risk analysis (QRA). This contributes to a safe design and optimized use of resources for controlling risk. QRA has been developed and improved over several decades for this purpose. In recent years, the offshore oil and gas industry in Norway has put significant effort into application of QRA also for supporting decisions in day-to-day operations of process plants. Several objectives have driven these attempts. One important objective is to ensure that major accident risk is taken into account in an adequate manner in daily operations. Another important aspect is to provide a basis for more consistent decision-making with respect to risk. However, success in meeting these objectives has been limited so far. The MIRMAP project (Modelling Instantaneous Risk for Major Accident Prevention) attempts to address this issue in a systematic manner. The starting point has been the types of decisions taken in daily operation, compared to the types of decisions in a design project. Based on this, risk models have been developed which are intended to give up-to-date risk information with limited effort and sufficiently quickly to be available when the decisions are being made. In traditional QRA, focus in the modelling is on technical systems and layout and how the systems may fail. This is relevant in design, when there is scope for making changes to these aspects. However, in operation, the design is fixed and changes in the risk level are driven primarily by the activities taking place and how they may interfere with the technical systems. The risk analysis should therefore also focus on activities. This is a different approach compared to traditional QRAs. The paper will describe the background to the project and an approach towards modelling the risk. Examples of representative activities are provided and how the risk associated with these are modelled. This includes how activities may influence the barriers in a plant and how activities may interact with each other to increase risk. Illustrative examples are provided and practical implications and feasibility are discussed.nb_NO
dc.language.isoengnb_NO
dc.publisherInstitution of Chemical Engineersnb_NO
dc.titleActivity-based risk analysis for process plant operationsnb_NO
dc.typeJournal articlenb_NO
dc.typePeer reviewednb_NO
dc.description.versionacceptedVersionnb_NO
dc.source.pagenumber12nb_NO
dc.source.volume2016-Januarynb_NO
dc.source.journalInstitution of Chemical Engineers Symposium Seriesnb_NO
dc.source.issue161nb_NO
dc.identifier.cristin1373186
dc.relation.projectNorges forskningsråd: 228237nb_NO
dc.description.localcode© 2016. This is the authors’ accepted and refereed manuscript to the article.nb_NO
cristin.unitcode194,64,20,0
cristin.unitnameInstitutt for marin teknikk
cristin.ispublishedtrue
cristin.fulltextoriginal
cristin.qualitycode1


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