Integrated design and analysis for virtual arctic simulation environment

Matthew Hamilton, Aaron Maynard, Muhammad Jujuly, Ibraheem Adeoti, Azizur Rahaman, Matthew Adey

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

We present an integration of new capabilities of simulation and visualization for subsea analysis and design into an existing virtual arctic simulation environment (VASE). The existing system (previously presented) provides interactive, high-fidelity simulation capabilities for remotely-operated vehicles (ROV) in arctic environments for subsea trenching along with support for visualization of integrated data from sub-bottom and multibeam sonar imaging devices. This paper describes integration of the existing VASE with computation fluid dynamics (CFD) simulation capability for simulation of flow assurance and fluidstructure interaction design issues relevant to arctic subsea oil and gas field design. The presented integrated simulation system allows for rapid, streamlined evaluation of pipeline designs in an integrated data, whole-field context. In particular, detailed analysis of pipeline fatigue risk factors due to slugging and effects of hydrate formation can be performed through integrated CFD analysis capabilities. The system's intuitive pipeline design allows for rapid alteration of pipe and flow lines in response to feedback from bathymetry and soil data, ROV accessibility requirements and structural analysis through flow induced vibration and fluid structure-interaction simulations. It is demonstrated how various pipeline and jumper designs can be rapidly created in the VASE with design strategies motivated by the integrated whole field data visualization environment. Once pipe and jumper designs are specified, they can be exported for external analysis. We demonstrate this analysis through two fluid-structure interaction models (slugging and hydrate formation model). This allows for effective design in arctic environments, including design of pipeline routes in context of trenching and general management of cold water conditions. Overall, the system can also serve to function as a planning and data management system for subsequent training of pilots for inspection as part of asset integrity management.

Original languageEnglish
Title of host publicationArctic Technology Conference 2016
PublisherOffshore Technology Conference
ISBN (Print)9781510835801
Publication statusPublished - 1 Jan 2016
EventArctic Technology Conference 2016 - St. John's, Canada
Duration: 24 Oct 201626 Oct 2016

Other

OtherArctic Technology Conference 2016
CountryCanada
CitySt. John's
Period24/10/1626/10/16

Fingerprint

simulation
Pipelines
Trenching
fluid-structure interaction
visualization
arctic environment
Remotely operated vehicles
remotely operated vehicle
Fluid structure interaction
fluid dynamics
Fluid dynamics
Hydrates
Visualization
pipe
Offshore oil fields
Pipe
analysis
multibeam sonar
Bathymetry
Data visualization

ASJC Scopus subject areas

  • Geotechnical Engineering and Engineering Geology
  • Geochemistry and Petrology

Cite this

Hamilton, M., Maynard, A., Jujuly, M., Adeoti, I., Rahaman, A., & Adey, M. (2016). Integrated design and analysis for virtual arctic simulation environment. In Arctic Technology Conference 2016 Offshore Technology Conference.

Integrated design and analysis for virtual arctic simulation environment. / Hamilton, Matthew; Maynard, Aaron; Jujuly, Muhammad; Adeoti, Ibraheem; Rahaman, Azizur; Adey, Matthew.

Arctic Technology Conference 2016. Offshore Technology Conference, 2016.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Hamilton, M, Maynard, A, Jujuly, M, Adeoti, I, Rahaman, A & Adey, M 2016, Integrated design and analysis for virtual arctic simulation environment. in Arctic Technology Conference 2016. Offshore Technology Conference, Arctic Technology Conference 2016, St. John's, Canada, 24/10/16.
Hamilton M, Maynard A, Jujuly M, Adeoti I, Rahaman A, Adey M. Integrated design and analysis for virtual arctic simulation environment. In Arctic Technology Conference 2016. Offshore Technology Conference. 2016
Hamilton, Matthew ; Maynard, Aaron ; Jujuly, Muhammad ; Adeoti, Ibraheem ; Rahaman, Azizur ; Adey, Matthew. / Integrated design and analysis for virtual arctic simulation environment. Arctic Technology Conference 2016. Offshore Technology Conference, 2016.
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