Improving the Installation of Offshore Wind Farms by the use of Discrete Event Simulation

Muhabie, Yohannes Tekle; Caprace, Jean-David; Petcu, Cristian; Rigo, Philippe

Download

Paper published in a book (Scientific congresses and symposiums)

Improving the Installation of Offshore Wind Farms by the use of Discrete Event Simulation

Muhabie, Yohannes Tekle; Caprace, Jean-David; Petcu, Cristian et al.

2015 • In Improving the Installation of Offshore Wind Farms by the use of Discrete Event Simulation

Peer reviewed

Permalink
https://hdl.handle.net/2268/188269

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

183.pdf

Author postprint (959.58 kB)

Download

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Discrete Event Simulation (DES); Weather Time Window; Workability;; Offshore Wind Farm; Lead Time; Probability; Conditional Probability; Risks

Abstract :

[en] The offshore wind energy development is highly affected by the condition of the weather at sea. Hence, it demands a well-organized planning of the overall process starting from the producers’ sites until the offshore site where the turbines will finally be installed. The planning phase can be supported with the help of Discrete Event Simulation (DES) where weather restrictions, distance matrix, vessel characteristics and assembly scenarios are taken into account. The purpose of this paper is to simulate the overall transport, assembly and installation of the wind turbine components at sea. The analysis is carried out through DES considering both the real historical weather data (wind speed and wave height) and probabilistic approach. Results of the study, applied to the real Offshore Wind Farm (OWF) configuration, are showing a good agreement between the two proposed models. The results point out that the probabilistic approach is highly affected by the semi-random numbers used to model the stochastic behavior of the input variable so that several iterations (200 to 400) are required to reach the convergence of the simulation outputs. We suggest that seasonality of the outputs of both models are preserved, i.e. the variation of the results depending on the variation of the weather along the year. These findings provide a new framework to address risks and uncertainties in OWF installations.

Disciplines :

Energy

Author, co-author :

Muhabie, Yohannes Tekle ; Université de Liège > Département ArGEnCo > Constructions hydrauliques et navales

Caprace, Jean-David ; Université de Liège > Département ArGEnCo > Constructions hydrauliques et navales

Petcu, Cristian ; Université de Liège > Département ArGEnCo > Constructions hydrauliques et navales

Rigo, Philippe ; Université de Liège > Département ArGEnCo > Constructions hydrauliques et navales

Language :

English

Title :

Improving the Installation of Offshore Wind Farms by the use of Discrete Event Simulation

Publication date :

November 2015

Event name :

5th World Maritime Technology Conference

Event organizer :

SNAME

Event place :

Providence, United States

Event date :

from 311-2015 to 7-11-2015

Audience :

International

Main work title :

Improving the Installation of Offshore Wind Farms by the use of Discrete Event Simulation

Peer reviewed :

Peer reviewed

Available on ORBi :

since 19 November 2015

Statistics

Number of views

258 (25 by ULiège)

Number of downloads

950 (13 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

Bibliography

A. AIT-ALLA, M.QUANDT, M.LUTJEN, Simulation-based aggregate installation planning of offshore wind farms, International Journal of Energy 7 (2013) 23-30.
A. Kovacs, G. Erdos, Z. J. Viharos, L. Monostori, A system for the detailed scheduling of wind farm maintenance, CIRP Annals – Manufacturing Technology 60 (1) (2011) 497-501.
E. Davey, a. Nimmo, Offshore wind cost reduction: Pathways study, Tech. Rep, The crow state, 16 New Burlington Place, London (May 2012).
El-Thalji, J. Liyanage, Managing offshore wind energy assets: On the systematic development of an integrated architecture, in: J. Mathew, L. Ma, A. Tan, M. Weijnen, J. Lee (Eds.), Engineering Asset Management and Infrastructure Sustainability, Springer London, 2012, pp. 181-193.
EWEA (2015), The European offshore wind industry- key trends and statistics 2014, European Wind energy Associations.
F. Thalemann, J. Bard, Offshore supply chain requirements for ocean energy in Europe-results from the orecca project, in: proceedings of the 4th International Conference on Ocean Energy, Dublin, 2012, pp. 1-6.
Hinnenthal, Robust pareto-optimum routing of ships utilizing deterministic and ensemble weather forecasts, PhD thesis, Universitätsbibliothek (2007).
IRENA, Renewable Energy Technologies: Cost analysis series-wind power, Tech. Rep., International Renewable Energy agency (IRENA) (June 2012).
J. Caprace, C.Petcu, M. Velarde, P. Rigo, Towards a Risk Based Simulations for the Erection of an Offshore Windmill Park, COMPIT’12-Proceeding of the 11th International Conference on Computer applications and Information technology in the Maritime Industries, Vol. 1, 2012, pp. 312-322.
J. Kaldellis, M. Kapasali, Shifting towards offshore wind energy-recent activity and future development, Energy Policy 53 (0) (2013) 136-148.
J. Moccia, A. Arapogianni, D. Williams, J. Philips, G. Hassan, Wind in our sails-the coming of Europe’s offshore wind energy industry, Tech. Rep., The European Wind Energy Association –EWEA (2011).
J. S. Gonzlez, M. B. payn, J. M. R. santos, F. Gonzlez-Longatt, A review and recent developments in the optimal wind-turbine micro-sitting problems, Renewable and Sustainable Energy Reviews 30 (0) (2014) 133-144.
K. Lange, A. Rinne, H. D. Haasis, Planning maritime logistics concepts for offshore wind farms: A newly developed decision support system, in: H. Hu, X. Shi, R. Stahlbock, S. VoB (Eds.), Berlin, Springer, 2012, 142-158.
L. K. Chien, S. Y. Chiu, W. C. Tseng, K. H. Chen, Risk assessment of offshore wind farm construction, in: Proceedings of the 23rd International Offshore and Polar engineering Congress (ISOPE 13), International Society of Offshore and Polar Engineering (ISPOPE), 2013, pp. 414-420.
M. Junginger, A. Faaij, W. C. Turkenburg, Cost reduction prospects for offshore wind farms, Wind Engineering 28 (2004) 97-118.
M. Ltjen, H. Karimi, Approach of a port inventory control system for the offshore installation of wind turbines, in: The 22th International Offshore and Polar Engineering Conference (ISOPE), Rhodes, Greece, 2012, pp. 502-508.
Miller, B. Chang, R. Issa, G. Chen, Review of computer-aided numerical simulation in wind energy, Renewable and sustainable energy Reviews 25 (0) (2013) 122-134.
R. Green, N. Vasilakos, 2011, the economics of offshore wind, Energy Policy 39(2), pp. 496-502.
R. Henderson, C.Morgan, B. smith, H. C. Srensen, R.J. Barthelmi, Boesmans, Offshore Wind Energy in Europe: A review of the state-of-the-art, Wind Energy 6 (1) (2003) 35-52.
R. Perveen, N. Kishor, s. R. Mohanty, Offshore wind farm development: Present status and challenges, Renewable and Sustainable Energy reviews 29 (0) (2014) 780-792.
Scholz-Reiter, M. Lütyen, J. Heger, a. Schweizer, Planning and control of logistic for offshore wind farms, in: Proceedings of the 12th WSEAS international conference on Mathematical and computational methods in science and engineering, MACMESE’10, World Scientific and Engineering Academy and Society (WSEAS), Stevens point, Wisconsin, USA, 2010, pp. 242-247.
Steinhauer, The simulation toolkit shipbuilding (STS)-10 years of cooperative development and inter branch application, in: V. Bertram (Ed.), proceeding of the 10th International Conference on Computer and IT Applications in the Maritime Industries (COMPIT), Vol. 1, 2011, pp. 453-465.
T. Smit, M. Junginger, R. Smits, Technological learning in offshore wind energy: Different roles of the government, Energy Policy 35 (2007) 6431-6444
Tyapin, G. Hovland, J. Jorde, Comparison of Markov Theory and Monte Carlo Simulations for analysis of Marine Operations Related to Installation of an Offshore Wind Turbine, in: 24th International Congress on Condition Monitoring (COMADEM), Stavanger, Norway, 2011, pp. 1071-1081.
UK, Value breakdown for the offshore wind sector, Tech. Rep. RAB (2010)0365, United Kingdom Government (February 2010)
X. Sun, D.Huang, G. Wu, The current state of Offshore wind technology development, Energy 41(1) (2012) 298 312, 23rd International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, (ECOS).