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International Journal on Interactive Design and Manufacturing (IJIDeM)

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03-02-2022 | Original Paper

A preference-based multi-objective model for wind farm design layout optimization

Authors: Naima Charhouni, Mehdi El Amine, Mohammed Sallaou, Khalifa Mansouri

Published in: International Journal on Interactive Design and Manufacturing (IJIDeM) | Issue 1/2022

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Abstract

This paper is based on integrating the decision maker preferences in the wind farm design layout optimization problem through a multi-criteria decision making method. This integration allows obtaining the realistic and optimal wind farm layout that response appropriately to decision maker preferences. For that an overall desirability index is used and evaluated as the main fitness function to seek for the appropriate solution with the best trade-off between the wind farm design objectives. It combines the power production and wind farm cost that are normalized and weighted according to decision maker preferences using desirability function and aggregation operator. The optimization of overall desirability index under realistic conditions of Horns-rev1 wind farm is performed using genetic algorithm. The results obtained from computing and comparing several case studies reveals that designing wind farm layout with a specific size, number and different hub heights of wind turbines gives the best results compared with the traditional design layouts with an overall satisfaction of 0.67. It demonstrates also that a preference-based multi-objective interactive model proposed for wind farm design layout optimization provides a useful tool for wind farm designers to seek for the adequacy level of a wind farm design layout solution and therefore the trade-off ensured between the contradictory objectives expected to satisfy simultaneously.

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https://www.evwind.es/2019/09/03/330-gw-of-wind-energy-will-be-installed-from-2019-to-2023/70647. Accessed 25 January 2020

Porté-Agel, F., Wu, Y.T., Chen, C.H.: A numerical study of the effects of wind direction on turbine wakes and power losses in a large wind farm. Energies 6(10), 5297–5313 (2013)CrossRef

Herbert-Acero, J., Probst, O., Réthoré, P.E., Larsen, G., Castillo-Villar, K.: A review of methodological approaches for the design and optimization of wind farms. Energies 7(11), 6930–7016 (2014)CrossRef

González, J.S., Payán, M.B., Santos, J.M.R., González-Longatt, F.: A review and recent developments in the optimal wind-turbine micro-siting problem. Renew. Sustain. Energy Rev. 30, 133–144 (2014)CrossRef

Ulku, I., Alabas-Uslu, C.: A new mathematical programming approach to wind farm layout problem under multiple wake effects. Renew. Energy 136, 1190–1201 (2019)CrossRef

Mosetti, G.P.C.D.B., Poloni, C., Diviacco, B.: Optimization of wind turbine positioning in large windfarms by means of a genetic algorithm. J. Wind Eng. Ind. Aerodyn. 51(1), 105–116 (1994)CrossRef

Grady, S.A., Hussaini, M.Y., Abdullah, M.M.: Placement of wind turbines using genetic algorithms. Renew. Energy 30(2), 259–270 (2005)CrossRef

Chen, Y., Li, H., Jin, K., Song, Q.: Wind farm layout optimization using genetic algorithm with different hub height wind turbines. Energy Convers. Manag. 70, 56–65 (2013)CrossRef

MirHassani, S.A., Yarahmadi, A.: Wind farm layout optimization under uncertainty. Renew. Energy 107, 288–297 (2017)CrossRef

10.

Vasel-Be-Hagh, A., Archer, C.L.: Wind farm hub height optimization. Appl. Energy 195, 905–921 (2017)CrossRef

11.

Wang, L., Cholette, M.E., Zhou, Y., Yuan, J., Tan, A.C., Gu, Y.: Effectiveness of optimized control strategy and different hub height turbines on a real wind farm optimization. Renew. Energy 126, 819–829 (2018)CrossRef

12.

Mustakerov, I., Borissova, D.: Wind turbines type and number choice using combinatorial optimization. Renew. Energy 35(9), 1887–1894 (2010)CrossRef

13.

Chowdhury, S., Zhang, J., Messac, A., Castillo, L.: Optimizing the arrangement and the selection of turbines for wind farms subject to varying wind conditions. Renew. Energy 52, 273–282 (2013)CrossRef

14.

Rahbari, O., Vafaeipour, M., Fazelpour, F., Feidt, M., Rosen, M.A.: Towards realistic designs of wind farm layouts: application of a novel placement selector approach. Energy Convers. Manag. 81, 242–254 (2014)CrossRef

15.

Feng, J., Shen, W.Z.: Design optimization of offshore wind farms with multiple types of wind turbines. Appl. Energy 205, 1283–1297 (2017)CrossRef

16.

Carta, J.A., Ramirez, P., Velazquez, S.: A review of wind speed probability distributions used in wind energy analysis: case studies in the Canary Islands. Renew. Sustain Energy Rev 13(5), 933–955 (2009)CrossRef

17.

Wais, P.: Two and three-parameter Weibull distribution in available wind power analysis. Renew. Energy 103, 15–29 (2017)CrossRef

18.

Ceyhan, Ö., Grasso, F.: Investigation of wind turbine rotor concepts for offshore wind farms. In: Journal of Physics: Conference Series, Vol. 524, p. 012032. IOP Publishing (2014)

19.

Göçmen, T., Van der Laan, P., Réthoré, P.E., Diaz, A.P., Larsen, G.C., Ott, S.: Wind turbine wake models developed at the technical university of Denmark: A review. Renew. Sustain. Energy Rev. 60, 752–769 (2016)CrossRef

20.

Annoni, J., Seiler, P., Johnson, K., Fleming, P.: Evaluating wake models for wind farm control. In: 2014 American Control Conference. pp. 2517–2523, IEEE (2014)

21.

Archer, C.L., Vasel-Be-Hagh, A., Yan, C., Wu, S., Pan, Y., Brodie, J.F., Maguire, A.E.: Review and evaluation of wake loss models for wind energy applications. Appl. Energy 226, 1187–1207 (2018)CrossRef

22.

Wang, L., Tan, A.C., Cholette, M., Gu, Y.: Comparison of the effectiveness of analytical wake models for wind farm with constant and variable hub heights. Energy Convers. Manag. 124, 189–202 (2016)CrossRef

23.

Parada, L., Herrera, C., Flores, P., Parada, V.: Wind farm layout optimization using a Gaussian-based wake model. Renew. Energy 107, 531–541 (2017)CrossRef

24.

Jeon, S., Kim, B., Huh, J.: Comparison and verification of wake models in an onshore wind farm considering single wake condition of the 2 MW wind turbine. Energy 93, 1769–1777 (2015)CrossRef

25.

Katic, I., Højstrup, J., Jensen, N.O.: A simple model for cluster efficiency: In: European wind energy association conference and exhibition. A. Raguzzi (1987)

26.

Feng, J., Shen, W.Z.: Wind farm layout optimization in complex terrain: a preliminary study on a Gaussian hill. In: Journal of Physics: Conference Series, Vol. 524, p. 012146. IOP Publishing (2014)

27.

Charhouni, N., Sallaou, M., Mansouri, K.: Design analysis of critical concepts influence wind farm production and efficiency. In: International Journal of Engineering Research in Africa. Vol. 40, pp. 136–150. Trans Tech Publications. (2018)

28.

Chowdhury, S., Zhang, J., Messac, A., Castillo, L.: Unrestricted wind farm layout optimization (UWFLO): investigating key factors influencing the maximum power generation. Renew. Energy 38(1), 16–30 (2012)CrossRef

29.

Carrillo, C., Montaño, A.O., Cidrás, J., Díaz-Dorado, E.: Review of power curve modelling for wind turbines. Renew. Sustain. Energy Rev. 21, 572–581 (2013)CrossRef

30.

Bruck, M., Sandborn, P., Goudarzi, N.: A Levelized Cost of Energy (LCOE) model for wind farms that include power purchase agreements (PPAs). Renew. Energy 122, 131–139 (2018)CrossRef

31.

Junginger, M., Faaij, A., Turkenburg, W.C.: Cost reduction prospects for offshore wind farms. Wind Eng. 28(1), 97–118 (2004)CrossRef

32.

Sánchez-Lozano, J.M., Teruel-Solano, J., Soto-Elvira, P.L., García-Cascales, M.S.: Geographical Information Systems (GIS) and Multi-Criteria Decision Making (MCDM) methods for the evaluation of solar farms locations: case study in south-eastern Spain. Renew. Sustain. Energy Rev. 24, 544–556 (2013)CrossRef

33.

Harrington, E.C.: The desirability function. Ind. Qual. Control. 21(10), 494–498 (1965)

34.

Gaumond, M., Réthoré, P.E., Ott, S., Pena, A., Bechmann, A., Hansen, K.S.: Evaluation of the wind direction uncertainty and its impact on wake modeling at the Horns Rev offshore wind farm. Wind Energy 17(8), 1169–1178 (2014)CrossRef

35.

Méchali, M., Barthelmie, R., Frandsen, S., Jensen, L., Réthoré, P.E.: Wake effects at Horns Rev and their influence on energy production. In: European Wind Energy Conference and Exhibition. Citeseer. Vol. 1, pp. 10–20 (2006)

36.

Gonzalez-Rodriguez, A.G.: Review of offshore wind farm cost components. Energy Sustain. Dev. 37, 10–19 (2017)CrossRef

37.

Yager, R.R.: On ordered weighted averaging aggregation operators in multicriteria decisionmaking. IEEE Trans. Syst. Man Cybern. 18(1), 183–190 (1988)MathSciNetCrossRef

38.

Scott, M.J., Antonsson, E.K.: Using indifference points in engineering decisions. American Society of Mechanical Engineers. Vol 35142, pp. 161–171 (2000)

39.

El Amine, M., & Sallaou, M.: Integration of mechanical deformation and optical losses in the design of linear Fresnel solar collectors. Int. J. Interact. Des. Manuf. 13(3), 831–840 (2019)

40.

Jin, Y., Geslin, M., Lu, S.Y.: Impact of argumentative negotiation on collaborative engineering. CIRP Ann. 56(1), 181–184 (2007)CrossRef

41.

Charhouni, N., Sallaou, M., Mansouri, K.: Realistic wind farm design layout optimization with different wind turbines types. Int. J. Energy Environ. Eng. 10(3), 307–318 (2019)

42.

Bénabès, J., Bennis, F., Poirson, E., Ravaut, Y.: Interactive optimization strategies for layout problems. Int. J. Interact. Design Manuf. (IJIDeM) 4(3), 181–190 (2010)CrossRef

43.

Zafrane, M.A., Bachir, A., Boudechiche, Z., Fekhikher, O. . Interactive design and advanced manufacturing of double solar panel deployment mechanism for CubeSat, part 1: electronics design. International Journal on Interactive Design and Manufacturing (IJIDeM), 14, 503–518 (2020)

44.

Khodaygan, S.: An interactive method for computer-aided optimal process tolerance design based on automated decision making. Int. J. Interact. Design Manuf. (IJIDeM) 13(1), 349–364 (2019)CrossRef

45.

Vergnano, A., Berselli, G., Pellicciari, M.: Interactive simulation-based-training tools for manufacturing systems operators: an industrial case study. Int. J. Interact. Design Manuf. (IJIDeM) 11(4), 785–797 (2017)CrossRef

46.

Berrezzoug, S., Boudjemai, A., Bendimerad, F.T.: Interactive design and multidisciplinary optimization of geostationary communication satellite. Int. J. Interact. Design Manuf. (IJIDeM) 13(4), 1519–1540 (2019)CrossRef

47.

Landi, D., Vita, A., Germani, M.: Interactive optimization of the resin transfer molding using a general-purpose tool: a case study. Int. J. Interact. Design Manuf. (IJIDeM) 14(1), 295–308 (2020)CrossRef

48.

Azizi, A., Yazdi, P.G., Hashemipour, M.: Interactive design of storage unit utilizing virtual reality and ergonomic framework for production optimization in manufacturing industry. Int. J. Interact. Design Manufact. (IJIDeM) 13(1), 373–381 (2019)CrossRef

Title: A preference-based multi-objective model for wind farm design layout optimization
Authors: Naima Charhouni
Mehdi El Amine
Mohammed Sallaou
Khalifa Mansouri
Publication date: 03-02-2022
Publisher: Springer Paris
Published in: International Journal on Interactive Design and Manufacturing (IJIDeM) / Issue 1/2022
Print ISSN: 1955-2513
Electronic ISSN: 1955-2505
DOI: https://doi.org/10.1007/s12008-021-00828-3

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