Volume 6, Issue 2, March 2017, Page: 19-27
Ocean Wave Energy Hydrogen System for Electrification
Abdul Majeed Muzathik, Department of Mechanical Engineering, Faculty of Engineering, South Eastern University of Sri Lanka, Oluvil, Sri Lanka
Received: Jun. 1, 2017;       Accepted: Jun. 15, 2017;       Published: Jul. 20, 2017
DOI: 10.11648/j.ijrse.20170602.12      View  2227      Downloads  119
Human population growth and development activities, growing at a rapid pace today, have increased the energy demands. Global concerns over above facts linked to fossil fuel consumption have increased the pressure to generate power from renewable sources. Owing to present day’s energy crisis, growing environmental concern and escalating cost of fossil fuels, we ought to take every effort to supplement our energy base with renewable sources. Without any doubt, renewable energy, especially solar, wind and wave energy will play an important role in 21st century. Main disadvantage of wave power is its largely random variability in several time-scales, from wave to wave, with sea state, and from season to season. Present situation shows a wide variety of wave energy systems, at several stages of development, competing against each other, without it being clear which types will be final winners. In last few years, interest in wave energy utilization has been growing rapidly in all over the world. High costs of constructing, deploying, maintaining and testing large prototypes under harsh environmental conditions, has hindered the development of wave energy systems. In this paper, some wave parameters have been discussed that are related to transport, generation and variability of wave energy in the sea. Wave Energy Converters (WECs) are classified into different groups. In order to develop a commercial WEC is not a straightforward task. Many inventions still have to be made, and many challenging problems need to be solved.
Population Growth, Energy Demand, Fossil Fuel, Environmental Concern, Wave Energy Systems
To cite this article
Abdul Majeed Muzathik, Ocean Wave Energy Hydrogen System for Electrification, International Journal of Sustainable and Green Energy. Vol. 6, No. 2, 2017, pp. 19-27. doi: 10.11648/j.ijrse.20170602.12
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Boyle, G. (2004). Renewable energy: power for a sustainable future (2nd ed.). Oxford University Press.
Muzathik, A. M., Ibrahim, M. Z., Samo, K. B. and Wan Nik, W. B. (2012). Assessment and Characterization of Renewable Energy Resources: A Case Study in Terengganu, Malaysia. Journal of Sustainability Science and Management, 7 (2), 220-229.
Lund, H. and Mathiesen, B. (2007). Energy system analysis of 100 percent renewable energy systems: the case of Denmark year 2030 and 2050. In HyFC Summer School Seminar. Svendborg, Denmark.
Renewable energy - Energy - European Commission (2017), https://ec.europa.eu/energy/en/topics/renewable-energy (30th May 2017).
Reichling, J. P. and Kulacki, F. A. (2008). Utility scale hybrid wind–solar thermal electrical generation: a case study for Minnesota. Energy, 33, 626-638.
Dahai, Z., Wei, L. and Yonggary, L. (2009). Wave energy in China: current status and perspectives. Renewable energy, 34 (11), 2089-2092.
Calderon, M., Calderon, A. J., Ramiro, A. and Gonzalez, J. F. (2010). Automatic management of energy flows of a stand-alone renewable energy supply with hydrogen support. International Journal of Hydrogen Energy, 35 (6), 2226-2235.
Muzathik, AM. (20130. Potential of Global Solar Radiation in Terengganu, Malaysia, International Journal of Energy Engineering 3 (4), 130-136.
Ajai, G., Saini, R. P. and Sharma, M. P. (2010). Steady-state modelling of hybrid energy system for off grid electrification of cluster of villages. Renewable Energy, 35 (2), 520-535.
Ghosh, P. C., Emonts, B., Janssen, H., Mergel, J. and Stolten, D. (2003). Ten years of operational experience with a hydrogen-based renewable energy supply system. Solar Energy, 75 (6), 469-478.
Isherwood, W., Smith, J. R., Aceves, S. M., Berry, G., Clark, W. and Johnson, R. (2000). Remote power systems with advanced storage technologies for Alaskan villages. Energy, 25 (10), 1005-1020.
Ibrahim, M. Z, Kamaruzzaman, S., Roziah, Z. and Muzathik, A. M. (2009). The potential of small scale environmental friendly renewable hybrid photovoltaic and wind energy generated system at Terengganu state coastal area. International Energy Journal, 10 (2). 81-91.
Babarit, A., Ben Ahmed, H., Clément, A. H., Debusschere, V., Duclos, G., Multon, B. and Robin G. (2006). Simulation of electricity supply of an Atlantic island by offshore wind turbines and wave energy converters associated with a medium scale local energy storage. Renewable Energy, 31 (2), 153-160.
Lund, H. (2006). Large-scale integration of optimal combinations of PV, wind and wave power into the electricity supply. Renewable Energy, 31 (4), 503-515.
Francesco, F., Gary, N. and Ringwood, J. V. (2010). Variability reduction through optimal combination of wind/wave resources - An Irish case study. Energy, 35 (1), 314-325.
Susan, B., Peter, W., Andrew, R. and Cornelis-van, K. G. (2010). Integration of wave power in Haida Gwaii. Renewable Energy, 35 (11), 2415-2421.
Langhamer O., Haikonen K., Sundberg J. Wave power—Sustainable energy or environmentally costly? A review with special emphasis on linear wave energy converters. Renewable and Sustainable Energy Reviews. 2010, 14 (4), 1329-1335.
Antonio F. de O. Falcao, Wave energy utilization: A review of the technologies. Renewable and Sustainable Energy Reviews. 2010, 14 (3), 899-918.
Al-Habaibeh A., Su D., McCague J., Knight A. An innovative approach for energy generation from waves. Energy Conversion and Management. 2010, 51 (8), 1664-1668.
Prado M.. Archimedes wave swing (AWS). In: Ocean wave energy (Ed. Cruz J), pp. 297-304, Springer, Berlin, 2008.
Ocean Power Technologies. 2006. Making Waves in Power. www.oceanpowertechnologies.com
McCormick M. E., Murthagh J., McCab P. Large-scale experimental study of a hinged-barge wave energy conversion system. 3rd European Wave Energy Conference Patras, Greece, 1998, 215-222.
McCabe A. P., Bradshaw A., Meadowcroft J. A. C., Aggidis G. Developments in the design of the PS Frog Mk 5 wave energy converter. Renewable Energy. 2006, 31, 141-151.
Kofoed J. P., Frigaard P., Friis-Madsen E., Sørensen H. C. Prototype testing of the wave energy converter wave dragon. Renewable Energy. 2006, 31, 181-189.
Goncalves F. V., Ramos H. M., Reis L. F. R. Hybrid energy system evaluation in water supply system production: neural network approach. International Journal of Energy and Environment 2010, 1 (1), 21-30.
Wan NikWB, Sulaiman OO, Rosliza R, Prawoto Y, Muzathik AM (2011). Wave energy resource assessment and review of the technologies. International Journal of Energy and Environment (IJEE), Volume 2, Issue 6, 2011, pp. 1101-1112.
Wan Nik, WB. Muzathik, AM. Samo, KB. Ibrahim, MZ. (2009). A review of ocean wave power extraction; the primary interface. International Journal of Fluid Machinery and Systems 2 (2), 156-164.
Milliken, J., Joseck, F. and Wang, M. (2007). The advanced energy initiative. Journal of Power Sources, 172, 121-131.
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