Ocean Systems Engineering

Techno-Press (테크노프레스)
권호 표지
DOI QR코드

DOI QR Code

Assessment of the potential for the design of marine renewable energy systems

  • Received : 2018.02.23
  • Accepted : 2018.05.23
  • Published : 2018.06.25
⟨ Previous Next ⟩

Abstract

The assessment of the potential for the design of marine renewable energy systems is reviewed and the current situation for marine renewable energy is promising. The most studied forms of marine renewable energy are ocean wind energy, ocean wave energy and tidal energy. Wind turbine generators include mostly horizontal axis type and vertical axis type. But also more exotic ideas such as a kite design. Wave energy devices consist of designs converting wave oscillations in electric power via a power take off equipment. Such equipment can take multiple forms to be more efficient. Nevertheless, the technology alone cannot be the only step towards marine renewable energy. Many other steps must be overcome: policy, environment, manpower as well as consumption habits. After reviewing the current conditions of marine renewable energy development, the authors analyzed the key factors for developing a strong marine renewable energy industry and pointed out the huge potential of marine renewable energy.

Keywords

References

  1. 4COffshore (2018), https://www.4coffshore.com/offshorewind/.
  2. Anaconda (2012), http://www.bulgewave.com/.
  3. Babarit, A., Hals, J., Muliawan, M.J., Kurniawan, A., Moan, T. and Krokstad, J. (2012), "Numerical benchmarking study of a selection of wave energy converters", Renew. Energ., 41, 44-63. https://doi.org/10.1016/j.renene.2011.10.002
  4. Bombora mWave (2017), http://www.bomborawave.com/.
  5. Breitschopf, B., Nathani, C. and Resch, G. (2011), "Review of approaches for employment impact assessment of renewable energy deployment", Fraunhofer ISI, Rutter + Partner, Energy Economics Group.
  6. Carnegie Clean Energy (2017), https://www.carnegiece.com/wave/.
  7. Columbia Power Technologies, (2017), http://columbiapwr.com/why-wave-energy/.
  8. Drew, B.. Plummer, A.R. and Sahinkaya, M.N. (2009), "A review of wave energy converter technology", Proceedings of the Institution of Mechanical Engineers Part A Journal of Power and Energy, 223(8), 887-902. https://doi.org/10.1243/09576509JPE782
  9. Erickson, W.P., Johnson, G.D. and Young Jr., D.P. (2005), Summary and Comparison of Bird Mortality from Anthropogenic Causes with Emphasis on Collisions, USDA Forest Service Gen. Tech. Rep. PSW-GTR-191, 1029-1042.
  10. Gatzert, N. and Kosub, R. (2016), "Risks and risk management of renewable energy projects: The case of onshore and offshore wind parks", Renew. Sust. Energ. Rev., 60, 982-998. https://doi.org/10.1016/j.rser.2016.01.103
  11. Global Wind Atlas (2017), https://globalwindatlas.info/.
  12. Houghton, T., Bell, K.R.W. and Doquet, M. (2016), "Offshore transmission for wind: Comparing the economic benefits of different offshore network configurations", Renew. Energ., 94, 268-279. https://doi.org/10.1016/j.renene.2016.03.038
  13. ICF International for the European Commission (2014), Study on the competitiveness of the EU Renewable Energy Industry (both products and services), Policy Analysis and Sector Summaries (31 July 2014).
  14. Khrisanov, V.I. and Dmitriev, B.F. (2016), "Marine electrical power industry with renewable energy carriers. Part1. Wind and wave turbines of offshore power plants", Russian Elec. Eng., 87(7), 409-416.. https://doi.org/10.3103/S106837121607004X
  15. Kite Power Systems Limited (2017), http://www.kps.energy/.
  16. Lehmann, M., Elandt, R., Shakeri, M. and Alam, R. (2014), "The wave carpet: development of a submerged pressure differential wave energy converter", Proceedings of the 30th Symposium on Naval Hydrodynamics, Hobart, Tasmania, 1-9.
  17. Lopez, I., Andreu, J., Ceballos, S., Alegria, I.M. and Kortabarria, I. (2013), "Review of wave energy technologies and the necessary power-equipment", Renew Sust. Energ., 27, 413-434. https://doi.org/10.1016/j.rser.2013.07.009
  18. Lorenzo Saenz M., ETYMOL Ocean Power (2018), "Technology Overview - YEAR 2018"
  19. Lye, J.L., Brown, D.T., Johnson, F., Bromley, P., Bittencourt, C. (2008), Orecon - Design and model testing of a wave energy buoy. Marine Renewable Energy, The Royal Institution of Naval Architects.
  20. National Renewable Energy Laboratory (NREL) (2017), https://www.nrel.gov/.
  21. Nedwell, J.D., Langworthy, J. and Howell, D. (2003), Assessment of Subsea Acoustic Noise and Vibration from Offshore Wind Turbines and its Impact on Marine Life, Cowrie Rep.
  22. Ocean Energy Forum (2016), Ocean Energy Strategic Roadmap 2016, building ocean energy for Europe.
  23. Ocean Energy Limited (2017), http://www.oceanenergy.ie/.
  24. Ocean Power Technology (2017), http://www.oceanpowertechnologies.com/.
  25. Pelamis Wave Power (2007), https://www.pelamiswave.com/.
  26. Rodkin, R.B. and Reyff, J.A. (2004), "Underwater sound pressures from marine pile-driving", Acoust. Soc. Am., 16, 2648.
  27. Salter, S.H., Taylor, J.R.M. and Caldwell, N.J. (2002), "Power conversion mechanisms for wave energy", Proceedings of the Institution of Mechanical Engineers Part M Journal of Engineering for the Maritime Environment, 216.
  28. Salvatore, F. and Greco, L. (2008), INSEAN, Italian Ship Model Basin, Italy. Development and assessment of performance prediction tools for wind and tidal turbines. Marine Renew. Energ., The Royal Institution of Naval Architects.
  29. SBM Offshore (2017), https://www.sbmoffshore.com/.
  30. SI Ocean - Strategic Initiative for Ocean Energy (2014), Wave and Tidal Energy Market Development Strategy for Europe (June 2014).
  31. State of New South Wales, New South Wales Coastline Management Manual (1990).
  32. Syndicat des Energies Renouvelables (2015), GICAN. L'industrie maritime francaise s'engage pour les energies marines renouvelables.
  33. U.S. Department of Energy (2011), Energy Efficiency & Renewable Energy. A National Offshore Strategy: Creating an Offshore Wind Energy Industry in the United States. February 2011.
  34. U.S. Department of Energy (2016), U.S. Department on the Interior. National Offshore Wind Strategy: Facilitating the Development of the Offshore Wind Industry in the United States. September 2016.
  35. Wang, H. and Falzarano, J.F. (2013), "Energy extraction from the motion of an oscillating water column", Ocean Syst. Eng., 3(4), 327-348. https://doi.org/10.12989/ose.2013.3.4.327
  36. Wang, H. and Falzarano, J.F. (2017), "Energy balance analysis method in oscillating type wave converter", J. Ocean Eng. Mar. Energ., 3(3), 193-208. https://doi.org/10.1007/s40722-017-0081-y
  37. Wang, H., Sitanggang, K. and Falzarano, J.F. (2017), "Exploration of power take off in wave energy converters with two bodies interactions", Ocean Syst. Eng., 7(2), 89-106. https://doi.org/10.12989/OSE.2017.7.2.089
  38. Wave Dragon (2015), http://www.wavedragon.net/.
  39. Wello Penguin (2017), https://wello.eu/.
  40. Westerberg, H. and Lagenfelt, I. (2008), "Sub-sea power cables and the migration behaviour of the European eel", Fish. Manag. Ecol., 15(5-6), 369-375. https://doi.org/10.1111/j.1365-2400.2008.00630.x
  41. Whittaker, T. and Folley, M. (2012), "Nearshore oscillating wave surge converters and the development of Oyster", Philos. T. R. Soc. Ser. A, 370, 345-364. https://doi.org/10.1098/rsta.2011.0152
  42. Yaakob, O., Tawi K. and Suprayogi, D. (2008), University Teknologi Malaysia, Malaysia. Development of vertical axis marine current turbine rotor. Marine Renewable Energy, 2008 The Royal Institution of Naval Architects.
  43. Yasseri, S. (2008), KBR Engineering, UK. Real option approach to offshore wind energy valuation. Marine Renewable Energy, The Royal Institution of Naval Architects.
  44. Zupone, G.L., Amelio, M., Barbarelli, S., Florio, G., Scornaienchi, N.M. and Cutrupi, A. (2017), "Lcoe evaluation for tidal kinetic self-balancing turbine: Case study and comparison", Appl. Energ., 185(2), 1292-1302. https://doi.org/10.1016/j.apenergy.2016.01.015

Cited by

  1. Effects of demi-hull separation ratios on motion responses of tidal current turbines-loaded catamaran vol.10, pp.1, 2018, https://doi.org/10.12989/ose.2020.10.1.087
  2. Alternative steel lattice structures for wind energy converters vol.12, pp.1, 2021, https://doi.org/10.1108/ijsi-05-2019-0042