IMIS - Marine Research Groups | Compendium Coast and Sea

IMIS - Marine Research Groups

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Naval architecture, Maritime engineering, Inland and Sea shipping and Transport System Analysis (ULG-ANAST)
seadatanet.maris2.nl/v_edmo/print.asp?n_code=2058
www.ulg.ac.be/anast
The research group Naval Architecture, Maritime Engineering, Inland and Sea Shipping and Transport System Analysis (ANAST) studies multiple aspects of shipping. The research activities of this group concentrate on shipbuilding, naval and offshore engineering (wind energy); maritime transport; modelling of river/maritime and intermodal transport; telematics applied to the management of navigation material; the development of an integrated application software (CAD-CAE) for shipbuilding; optimisation of naval and floating structures; technical-economic comparative analyses on transport modes (incl. intermodality); the development of a transport plan, mathematical modelling of future traffic flow; testing techniques after optimisation in the towing tank; naval hydrodynamics and production simulation (space, flow).

The marine topics studied by this research unit are:
  • shipbuilding and the development of an integrated application software (CAD-CAE) for ship building;

  • development and optimisation of offshore wind turbines (WindSteel, EOL-OS, etc.);

  • development of a real-time and powerful asset integrity management system for offshore wind farms and an adaptive maintenance strategy (HLC-AIMS).


The research group collaborates with many institutes and universities worldwide and participates in several European and international research projects.

Standard name: Architecture Navale, Génie Maritime, Navigation Intérieure et Maritime, Analyse des Systèmes de Transport
Parent institute: Université de Liège; Faculty of Applied Sciences; Urban and Environmental Engineering (ULG-UEE), more


Child institute
  • Université de Liège; Faculty of Applied Sciences; Urban and Environmental Engineering; Naval architecture, Maritime engineering, Inland and Sea shipping and Transport System Analysis; Naval and Offshore Engineering (ULG), more

Address:
Quartier Polytech 1
Allée de la Découverte 9
4000 Liège
Belgium

Tel.: +32-(0)4-366 96 29
 
Type: Scientific
    ( 32 peer reviewed ) split up filter
  • Peer reviewed article Hlaing, N.; Morato, P.G.; de Nolasco Santos, F.; Weijtjens, W.; Devriendt, C.; Rigo, P. (2024). Farm-wide virtual load monitoring for offshore wind structures via Bayesian neural networks. Structural Health Monitoring 23(3): 1641-1663. https://dx.doi.org/10.1177/14759217231186048, more
  • Peer reviewed article Ladeira, I.; Márquez, L.; Echeverry, S.; Le Sourne, H.; Rigo, P. (2023). Review of methods to assess the structural response of offshore wind turbines subjected to ship impacts. Ships Offshore Struct. 18(6): 755-774. https://dx.doi.org/10.1080/17445302.2022.2072583, more
  • Peer reviewed article Ladeira, I.; Echeverry Jaramillo, S.; Le Sourne, H. (2023). A simplified method to assess the elasto-plastic response of standalone tubular Offshore Wind Turbine supports subjected to ship impact. Ocean Eng. 279: 114313. https://dx.doi.org/10.1016/j.oceaneng.2023.114313, more
  • Peer reviewed article Mishael, J.; Morato, P.G.; Rigo, P. (2023). Numerical fatigue modeling and simulation of interacting surface cracks in offshore wind structural connections. Mar. Struct. 92: 103472. https://dx.doi.org/10.1016/j.marstruc.2023.103472, more
  • Peer reviewed article Marquez, L.; Le Sourne, H.; Rigo, P. (2022). Mechanical model for the analysis of ship collisions against reinforced concrete floaters of offshore wind turbines. Ocean Eng. 261: 111987. https://dx.doi.org/10.1016/j.oceaneng.2022.111987, more
  • Peer reviewed article Morato, P.G.; Papakonstantinou, K.G.; Andriotis, C.P.; Nielsen, J.S.; Rigo, P. (2022). Optimal inspection and maintenance planning for deteriorating structural components through dynamic Bayesian networks and Markov decision processes. Structural Safety 94: 102140. https://dx.doi.org/10.1016/j.strusafe.2021.102140, more
  • Peer reviewed article Long, L.; Mai, Q.A.; Morato, P.G.; Sørensen, J.D.; Thöns, S. (2020). Information value-based optimization of structural and environmental monitoring for offshore wind turbines support structures. Renew. Energy 159: 1036-1046. https://hdl.handle.net/10.1016/j.renene.2020.06.038, more
  • Peer reviewed article Pire, T.; Le Sourne, H.; Echeverry, S.; Rigo, P. (2018). Analytical formulations to assess the energy dissipated at the base of an offshore wind turbine jacket impacted by a ship. Mar. Struct. 59: 192-218. https://dx.doi.org/10.1016/j.marstruc.2018.02.002, more
  • Peer reviewed article Bela, A.; Le Sourne, H.; Buldgen, L.; Rigo, P. (2017). Ship collision analysis on offshore wind turbine monopile foundations. Mar. Struct. 51: 220-241. https://dx.doi.org/10.1016/j.marstruc.2016.10.009, more
  • Peer reviewed article Lee, S.E.; Sahin, S.; Rigo, P.; Park, M.; Paik, J.K. (2017). Ultimate strength of cylindrical shells with cutouts. Ships Offshore Struct. 12: S153-S173. https://dx.doi.org/10.1080/17445302.2016.1271592, more
  • Peer reviewed article Buldgen, L.; Le Sourne, H.; Rigo, P. (2015). A simplified analytical method to estimate the resistance of plane lock gates impacted by river barges. Mar. Struct. 43: 61-86. https://dx.doi.org/10.1016/j.marstruc.2015.06.001, more
  • Peer reviewed article Ehlers, S.; Le Sourne, H.; Buldgen, L.; Ollero, J.; Robertson, C.; Rigo, P. (2015). A review of technical solutions and simulation approaches for ship collisions with lock gates. Ship Technology Research 62(1): 14-25. https://dx.doi.org/10.1179/0937725515Z.0000000002, more
  • Peer reviewed article Buldgen, L.; Le Sourne, H; Pire, T. (2014). Extension of the super-elements method to the analysis of a jacket impacted by a ship. Mar. Struct. 38: 44-71. dx.doi.org/10.1016/j.marstruc.2014.05.002, more
  • Peer reviewed article Khedmati, R; Pedram, M; Rigo, P. (2014). The effects of geometrical imperfections on the ultimate strength of aluminium stiffened plates subject to combined uniaxial compression and lateral pressure. Ships Offshore Struct. 9(1): 88-109. https://dx.doi.org/10.1080/17445302.2012.726761, more
  • Peer reviewed article Buldgen, L.; Le Sourne, H.; Rigo, P. (2013). A simplified analytical method for estimating the crushing resistance of an inclined ship side. Mar. Struct. 33: 265-296. dx.doi.org/10.1016/j.marstruc.2013.06.005, more
  • Peer reviewed article Caprace, J.-D.; Petcu, C.; Velarde, M.G.; Rigo, P. (2013). Optimization of shipyard space allocation and scheduling using a heuristic algorithm. J. Mar. Sci. Technol. 18(3): 404-417. dx.doi.org/10.1007/s00773-013-0217-2, more
  • Peer reviewed article De Baere, K.; Verstraelen, H.; Rigo, P.; Van Passel, S.; Lenaerts, S.; Potters, G. (2013). Study on alternative approaches to corrosion protection of ballast tanks using an economic model. Mar. Struct. 32: 1-17. https://dx.doi.org/10.1016/j.marstruc.2013.02.003, more
  • Peer reviewed article De Baere, K.; Verstraelen, H.; Rigo, P.; Van Passel, S.; Lenaerts, S.; Potters, G. (2013). Reducing the cost of ballast tank corrosion: an economic modeling approach. Mar. Struct. 32: 136-152. https://dx.doi.org/10.1016/j.marstruc.2012.10.009, more
  • Peer reviewed article Buldgen, L.; Le Sourne, H.; Rigo, P. (2012). Simplified analytical method for estimating the resistance of lock gates to ship impacts. Journal of Applied Mathematics 2012(ID 763849): 39 pp. dx.doi.org/10.1155/2012/763849, more
  • Peer reviewed article Buldgen, L.; Le Sourne, H.; Besnard, N.; Rigo, P. (2012). Extension of the super-elements method to the analysis of oblique collision between two ships. Mar. Struct. 29(1): 22-57. http://dx.doi.org/10.1016/j.marstruc.2012.08.002, more
  • Peer reviewed article Caprace, J.-D.; Rigo, P. (2012). Towards a short time “feature-based costing” for ship design. J. Mar. Sci. Technol. 17(2): 216-230. http://dx.doi.org/10.1007/s00773-012-0163-4, more
  • Peer reviewed article Caprace, J.-D.; Rigo, P. (2012). A real-time assessment of the ship design complexity. Comput. Aided Des. 44(3): 203-208. http://dx.doi.org/10.1016/j.cad.2010.12.005, more
  • Peer reviewed article Caprace, J.D.; Rigo, P. (2011). Ship complexity assessment at the concept design stage. Journal of Marine Science and Technology 16(1): 68-75. dx.doi.org/10.1007/s00773-010-0107-9, more
  • Peer reviewed article Constantinescu, A.; El Malki Alaoui, A.; Nême, A.; Jacques, N.; Rigo, P. (2011). Numerical and experimental studies of simple geometries in slamming. IJOPE 21(3): 216-224, more
  • Peer reviewed article Besnard, N.; Pécot, F.; Rigo, P. (2010). Ship design goes multidisciplinary. Nav. Archit. 2010: 16-19, more
  • Peer reviewed article Caprace, J.-D.; Bair, F.; Rigo, P. (2010). Scantling multi-objective optimisation of a LNG carrier. Mar. Struct. 23(3): 288-302. http://dx.doi.org/10.1016/j.marstruc.2010.07.003, more
  • Peer reviewed article Reza Khedmati, M.; Reza Zareei, M.; Rigo, P. (2010). Empirical formulations for estimation of ultimate strength of continuous stiffened aluminium plates under combined in-plane compression and lateral pressure. Thin-Walled Struct. 48(3): 274-289. http://dx.doi.org/10.1016/j.tws.2009.10.001, more
  • Peer reviewed article Reza Khedmati, M.; Bayatfar, A.; Rigo, P. (2010). Post-buckling behaviour and strength of multi-stiffened aluminium panels under combined axial compression and lateral pressure. Mar. Struct. 23(1): 39-66. http://dx.doi.org/10.1016/j.marstruc.2009.10.003, more
  • Peer reviewed article Rigo, P.; Zanic, V.; Ehlers, S.; Andric, J. (2010). Design of innovative ship concepts using an integrated decision support system for ship production and operation. Brodogradnja 61(4): 367-380, more
  • Peer reviewed article Reza Khedmati, M.; Reza Zareei, M.; Rigo, P. (2009). Sensitivity analysis on the elastic buckling and ultimate strength of continuous stiffened aluminium plates under combined in-plane compression and lateral pressure. Thin-Walled Struct. 47(11): 1232-1245. http://dx.doi.org/10.1016/j.tws.2009.04.010, more
  • Peer reviewed article Turan, O.; Olcer, A.; Lazakis, I.; Rigo, P.; Caprace, J. (2009). Maintenance/repair and production-oriented life cycle cost/earning model for ship structural optimisation during conceptual design stage. Ships Offshore Struct. 4(2): 107-125. dx.doi.org/10.1080/17445300802564220, more
  • Peer reviewed article Richir, T.; Losseau, N.; Pircalabu, E.; Toderan, C.; Rigo, P. (2007). Least cost optimization of a large passenger vessel, in: Soares, C.G. et al. (Ed.) Advancements in Marine Structures: Proceedings of MARSTRUCT 2007, the 1st International Conference on Marine Structures, Glasgow, United Kingdom, 12-14 March 2007. Proceedings and Monographs in Engineering, Water and Earth Sciences, : pp. 483-488. hdl.handle.net/2268/29753, more
  • Bayatfar, A.; Warnotte, R.; Rigo, P. (2019). Automated structural optimisation of ships' midship section in concept design phase, in: Parunov, J. et al. Trends in the analysis and design of marine structures. pp. 510-514, more
  • Dang, T.V.; Mai, Q.A.; Morato, P.G.; Rigo, P. (2019). Updating the failure probability of miter gates based on observation of water levels, in: Correia, J.A.F.O. et al. Mechanical fatigue of metals. pp. 221-228. https://dx.doi.org/10.1007/978-3-030-13980-3_29, more
  • Bela, A.; Pire, T.; Buldgen, L.; Rigo, P. (2016). Ship collision on offshore wind turbines, in: PIANC Yearbook 2015. pp. 57, more
  • Mai, Q.A.; Sørensen, J.D.; Rigo, P. (2016). Updating failure probability of a welded joint in offshore wind turbine substructures, in: Proceedings of the 35th International Conference on Ocean, Offshore and Arctic Engineering, OMAE2016, June 19-24, 2016, Busan, South Korea. pp. 10 pp, more
  • Tekle Muhabie, Y.; Petcu, C.; Rigo, P.; Caprace, J.D. (2016). Weather down time analysis for offshore wind farm installations, in: PIANC Yearbook 2015. pp. 52-53, more
  • Khedmati, M.; Rigo, P.; Amrane, A.; Nazari, M. (2013). Assessment of fatigue reliability for jacket-type offshore platforms considering dynamic behavior, in: ASME (Ed.) ASME 2013: Proceedings of the 32nd International Conference on Ocean, Offshore and Arctic Engineering. Volume 2B: Structures, Safety and Reliability. pp. V02BT02A050. http://dx.doi.org/10.1115/OMAE2013-11568, more
  • Amrane, A.; Rigo, P. (2011). Scantling optimization of ship structures considering fatigue at the early design stage, in: Soares, C.G. et al. (Ed.) Advances in Marine Structures. pp. 569-579, more
  • Rigo, P.; Caprace, J.-D. (2011). Optimization of ship structures, in: Soares, C.G. et al. (Ed.) Marine technology and engineering, vol. 2. pp. 925-944, more
  • Thiry, A.; Bair, F.; Buldgen, L.; Raboni, G.; Rigo, P. (2011). Optimization of monopile offshore wind structures, in: Soares, C.G. et al. (Ed.) Advances in Marine Structures. pp. 633-642, more
  • Caprace, J.-D.; Bair, F.; Rigo, P. (2010). Least weight and least cost optimisation of a passenger vessel. Sci.J. Ser. Math. Modelling Civ. Eng. (Tech. Univ. Civ. Eng. Buchar., Print) 2: 17-26, more
  • Rigo, P.; Herbillon, V. (2010-2011). Voies navigables et constructions hydrauliques: notes de cours destinées aux étudiants de la 2ème année du Master en Ingénieur Civil des Constructions [COURS]. Université de Liège. Faculté des Sciences Appliquées: Liège. different pagination pp., more
  • Losseau, N.; Caprace, J.-D.; Rigo, P.; Aracil, F.F. (2009). A data mining analysis to evaluate the additional workloads caused by welding distortions, in: Soares, C.G. et al. Analysis and Design of Marine Structures. , more
  • Graille, P.; Maillet, J.-N.; Daly, F.; Rigo, P. (2008). Seine-Nord Europe Canal: comparison of two lock concepts with water-saving basins and optimisation of chamber structure. On Course 132: 35-48, more
  • Graille, P.; Maillet, J.-N.; Cazaillet, O.; Rigo, P. (2008). Seine-Nord Europe Canal: hydraulic design of locks. On Course 132: 49-66, more
  • BENCORE: Belgian Network for Coastal Reseach, more
  • BESST: Breakthrough in European Ship and Shipbuilding Technologies, more
  • CREATING: Concepts to reduce environmental impact and attain optimal transport performance by inland navigation, more
  • IMPROVE: Design of Improved and Competitive Products Using an Interated Decision Support Systems for Ship Production and Operation, more
  • MarNIS: Maritime Navigation and Information Services, more
  • MARSTRUCT: Network of excellence in marine structures, more