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Journal articles on the topic 'Tidal energy'

Author: Grafiati
Published: 4 June 2021
Last updated: 21 February 2023

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1

Neill, Simon P., M. Reza Hashemi, and Matt J. Lewis. "Tidal energy leasing and tidal phasing." Renewable Energy 85 (January 2016): 580–87. http://dx.doi.org/10.1016/j.renene.2015.07.016.

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2

Khalid, Syed Shah, Zhang Liang, and Nazia Shah. "Harnessing Tidal Energy Using Vertical Axis Tidal Turbine." Research Journal of Applied Sciences, Engineering and Technology 5, no. 1 (January 1, 2013): 239–52. http://dx.doi.org/10.19026/rjaset.5.5112.

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3

Blunden, L. S., and A. S. Bahaj. "Tidal energy resource assessment for tidal stream generators." Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy 221, no. 2 (March 2007): 137–46. http://dx.doi.org/10.1243/09576509jpe332.

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4

FRAENKEL, PETER L. "Tidal Current Energy Technologies." Ibis 148 (March 27, 2006): 145–51. http://dx.doi.org/10.1111/j.1474-919x.2006.00518.x.

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5

Ferro, Benoit Dal. "Wave and tidal energy." Refocus 7, no. 3 (May 2006): 46–48. http://dx.doi.org/10.1016/s1471-0846(06)70574-1.

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6

Koruthu, Joh. "4598211 Tidal energy system." Ocean Engineering 14, no. 1 (January 1987): ii. http://dx.doi.org/10.1016/0029-8018(87)90018-7.

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7

O Rourke, Fergal, Fergal Boyle, and Anthony Reynolds. "Tidal energy update 2009." Applied Energy 87, no. 2 (February 2010): 398–409. http://dx.doi.org/10.1016/j.apenergy.2009.08.014.

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8

Majdi Nasab, Navid, Jeff Kilby, and Leila Bakhtiaryfard. "Integration of wind and tidal turbines using spar buoy floating foundations." AIMS Energy 10, no. 6 (2022): 1165–89. http://dx.doi.org/10.3934/energy.2022055.

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<abstract> <p>Floating platforms are complex structures used in deep water and high wind speeds. However, a methodology should be defined to have a stable offshore structure and not fail dynamically in severe environmental conditions. This paper aims to provide a method for estimating failure load or ultimate load on the anchors of floating systems in integrating wind and tidal turbines in New Zealand. Using either wind or tidal turbines in areas with harsh water currents is not cost-effective. Also, tidal energy, as a predictable source of energy, can be an alternative for wind energy when cut-in speed is not enough to generate wind power. The most expensive component after the turbine is the foundation. Using the same foundation for wind and tidal turbines may reduce the cost of electricity. Different environment scenarios as load cases have been set up to test the proposed system's performance, capacity and efficiency. Available tidal records from the national institute of Water and Atmospheric Research (NIWA) have been used to find the region suitable for offshore energy generation and to conduct simulation model runs. Based on the scenarios, Terawhiti in Cook Strait with 110 m water height was found as the optimized site. It can be seen that the proposed floating hybrid system is stable in the presence of severe environmental conditions of wind and wave loadings in Cook Strait and gives a procedure for sizing suction caisson anchors.</p> </abstract>
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Novico, Franto, Evi Hadrijantie Sudjono, Andi Egon, David Menier, Manoj Methew, and Munawir Bintang Pratama. "Tidal Current Energy Resources Assessment in the Patinti Strait, Indonesia." International Journal of Renewable Energy Development 10, no. 3 (February 24, 2021): 517–25. http://dx.doi.org/10.14710/ijred.2021.35003.

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Indonesia is currently intensively developing its renewable energy resource and targets at least 23% by 2025. As an archipelago country, Indonesia has the potential to benefit from its abundant renewable energy resources from its offshore regions. However, the short tidal range of mixed semi-diurnal and the suitable tidal turbine capacity may hinder marine renewable energy development in Indonesian waters. This paper presents higher-order hydrodynamic numerical models to provide spatial information for tidal current resource assessment of the Patinti Strait. The present study applied the hydrographic and oceanographic method to produce input of the numerical model. Based on the selected simulation analysis, the highest current speed could be identified around Sabatang and Saleh Kecil Island with up to 2.5 m/s in P1 and 1.7 m/s in P4. Besides, the operational hours for the two observation points are 69% and 74.5%, respectively. The results indicate that this location is of prime interest for tidal turbine implementation as an energy source, for medium capacity (300 kW) and high capacity (1 MW).
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10

Haque, Mohammad Asadul, and Mst Sujata Khatun. "Tidal Energy: Perspective of Bangladesh." Journal of Bangladesh Academy of Sciences 41, no. 2 (January 29, 2018): 201–15. http://dx.doi.org/10.3329/jbas.v41i2.35498.

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Bangladesh is blessed by the nature with renewable resources that are used all over the world in a wide range but in our country it is limited. The country has vast ocean area with various power resources such as Wave energy, Ocean Thermal Energy Conversion (OTEC) and Tidal energy. In the Bay of Bengal, the tidal range and tidal stream speed indicate the potentiality of tidal power generation in Bangladesh. This paper describes various methods of utilizing tidal power to generate electricity and assess the tidal energy resources of three potential sites of Bangladesh. The tidal data recorded by the Department of Hydrography of The Chittagong Port Authority (CPA) and Bangladesh Inland Water Transport Authority (BIWTA) have been analyzed. This study clearly indicates the bright prospects of tidal power in Bangladesh.Journal of Bangladesh Academy of Sciences, Vol. 41, No. 2, 201-215, 2017
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11

Pool, R. "Sink or Swim [tidal energy]." Engineering & Technology 13, no. 7 (August 1, 2018): 36–39. http://dx.doi.org/10.1049/et.2018.0703.

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12

Zheng, Jinhai, Peng Dai, and Jisheng Zhang. "Tidal Stream Energy in China." Procedia Engineering 116 (2015): 880–87. http://dx.doi.org/10.1016/j.proeng.2015.08.377.

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13

., T. S. Desmukh. "TIDAL CURRENT ENERGY AN OVERVIEW." International Journal of Research in Engineering and Technology 04, no. 07 (July 25, 2015): 147–51. http://dx.doi.org/10.15623/ijret.2015.0407022.

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14

Denny, Eleanor. "The economics of tidal energy." Energy Policy 37, no. 5 (May 2009): 1914–24. http://dx.doi.org/10.1016/j.enpol.2009.01.009.

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15

Do, Huy Toan, Thanh Binh Nguyen, and Tuan Minh Ly. "Tidal energy potential in coastal Vietnam." Ministry of Science and Technology, Vietnam 64, no. 1 (March 15, 2022): 85–89. http://dx.doi.org/10.31276/vjste.64(1).85-89.

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Tidal energy is a renewable energy source produced by the rise and fall of ocean tides. Tidal energy can be exploited using a special type of generator that converts tidal energy into electricity. Tidal power generation has the potential to open up many prospects for energy field and minimize carbon dioxide emissions that cause the greenhouse effect. To evaluate the possibility of tidal power, it is necessary to have documents and data on average annual tidal amplitude, tidal regime, and main tidal waves in the study area. To calculate the tidal power potential for the east coast of Vietnam, this article applies the calculation formula of tidal power energy by Russian scientist L.B. Bernstein. The annual mean tidal amplitude and the K1, O1, and M2 wave amplitude data at nearly 2000 calculation points along the coast of Vietnam were extracted from the TPOX8-Atlas harmonic constant set. Research results showed that Vietnam has great potential for tidal energy along the Hai Phong - Quang Ninh coastal area and the southeast region with a prospective 41.6 GWh/km2/y.
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16

Osman, Peter, Jennifer A. Hayward, Irene Penesis, Philip Marsh, Mark A. Hemer, David Griffin, Saad Sayeef, et al. "Dispatchability, Energy Security, and Reduced Capital Cost in Tidal-Wind and Tidal-Solar Energy Farms." Energies 14, no. 24 (December 16, 2021): 8504. http://dx.doi.org/10.3390/en14248504.

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The global tidal energy resource for electricity generation is small, and converting tidal kinetic energy to electricity is expensive compared to solar-photovoltaic or land-based wind turbine generators. However, as the renewable energy content in electricity supplies grows, the need to stabilise these supplies increases. This paper describes tidal energy’s potential to reduce intermittency and variability in electricity supplied from solar and wind power farms while lowering the capital expenditure needed to improve dispatchability. The paper provides a model and hypothetical case studies to demonstrate how sharing energy storage between tidal stream power generators and wind or solar power generators can mitigate the level, frequency, and duration of power loss from wind or solar PV farms. The improvements in dispatchability use tidal energy’s innate regularity and take account of tidal asymmetry and extended duration low-velocity neap tides. The case studies are based on a national assessment of Australian tidal energy resources carried out from 2018 to 2021.
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17

Soejianto, Eko, Khansa Hanifa Zahra, and Suci Nur Hidayah. "Tidal Energy Utilization of Larantuka Strait by Dual Tidal Turbines to Increase National Energy Resilience." Proceeding International Conference on Science and Engineering 2 (March 1, 2019): 73–77. http://dx.doi.org/10.14421/icse.v2.57.

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Currently, renewable energy can only support 5% of national energy needs. Meanwhile, in 2035 renewable energy targeted to sustain 14% of total national energy demand. The proper way for optimizing the renewable energy is needed to actualize the target. Tidal energy as one of the potentials that are still being developed and need more attention from the government. Tidal can be used for natural energy resource since it has zero emission, produce big energy, and has no impact to weather. Larantuka Strait located in Flores island, Nusa Tenggara Timur province can produce tidal velocity up to 2.859 m/s with water density as much as 1.025 gr/cc. In utilizing this energy, we use new innovation by using dual tidal turbines which placed at the foot of Palmerah Bridge. The construction of Palmerah Bridge is built both by the government of Flores Island and Adonara Island. Dual tidal turbines are more efficient than singl e turbine by reason of tidal that has passed through the first turbine can be used again for the second turbine. The using of the generator is meant to convert kinetic energy that produced by dual tidal turbines. To convert ocean currents into electrical energy optimally, it is necessary to plan turbine designs that are in accordance with the conditions of ocean currents and the surrounding environment such as current velocity, wind influences and so on. Horizontal-axis tidal turbine (HATTs) is one of the technologies that are being developed and tested in prototype form by several companies, an efficient blade design is very important for the success of the HATTs. The amount of turbine needs, in this case, is 15 turbines with each turbine’s length is 10 meters. The turbines installed in bridge’s column along 800 meters. Estimate electricity can be generated by the turbine is 1.48 Mega Watt (MW).
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18

O'Carroll, J. P. J., R. M. Kennedy, A. Creech, and G. Savidge. "Tidal Energy: The benthic effects of an operational tidal stream turbine." Marine Environmental Research 129 (August 2017): 277–90. http://dx.doi.org/10.1016/j.marenvres.2017.06.007.

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19

Green, J. A. Mattias, and Jonas Nycander. "A Comparison of Tidal Conversion Parameterizations for Tidal Models." Journal of Physical Oceanography 43, no. 1 (January 1, 2013): 104–19. http://dx.doi.org/10.1175/jpo-d-12-023.1.

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Abstract The conversion of barotropic to baroclinic tidal energy in the global abyssal ocean is calculated using three different formulations. The calculations are done both “offline,” that is, using externally given tidal currents to estimate the energy conversion, and “online,” that is, by using the formulations to parameterize linear wave drag in a prognostic tidal model. All three schemes produce globally integrated offline dissipation rates beneath 500-m depth of ~0.6–0.8 TW for the M2 constituent, but the spatial structures vary significantly between the parameterizations. Detailed investigations of the energy transfer in local areas confirm the global results: there are large differences between the schemes, although the horizontally integrated conversion rates are similar. The online simulations are evaluated by comparing the sea surface elevation with data from the TOPEX/Poseidon database, and the error is then significantly lower when using the parameterization provided by Nycander than with the other two parameterizations examined.
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20

Murali, K., and V. Sundar. "Reassessment of tidal energy potential in India and a decision-making tool for tidal energy technology selection." International Journal of Ocean and Climate Systems 8, no. 2 (June 6, 2017): 85–97. http://dx.doi.org/10.1177/1759313117694629.

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Oceans have significant renewable energy options to provide environmental friendly and clean energy. Technology for ocean energy systems and the feasibility for extraction of the same is an important area on which research is being focused worldwide. This article covers a detailed review of available tidal energy conversion technologies and case studies, with specific focus on tidal power potential in India. The proven option for tidal energy conversion is barraging. Recently, open-type turbine (usually known as tidal stream turbines) has been studied by several researchers and pilot demonstrations have been made. While conventional turbines of 10–20 MW rating are used in barrages, the application of tidal stream turbines of 0.5–2.0 MW has been demonstrated in water depths between 40 and 60 m. A new scale is proposed for categorizing the tidal energy potential in terms of tidal velocity and tidal range which could be used to categorize the potential sites and their ranking. A new systematic approach proposed for the assessment of tidal energy conversion potential can facilitate the suitability of either tidal stream energy or tidal barrage for a location. Within this, one could also decide the site could be developed as a major project or minor project. Therefore, the present work will be useful for engineers and decision makers in technology selection investment potential identification.
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21

Bourban, Sébastien E., Noémie D. C. Durand, Tom T. Coates, Lindsay Gill, Michael Harper, and Richardson Stephen. "MODELLING TIDAL ENERGY RESOURCE AND EXTRACTION." Coastal Engineering Proceedings 1, no. 32 (January 31, 2011): 6. http://dx.doi.org/10.9753/icce.v32.posters.6.

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A number of areas around the UK coast are being investigated as possible locations for tidal energy harnessing. Detailed assessment using regional hydrodynamic modelling supported by field measurements can be used to quantify the energy resource and to determine limitations in the potential development area, including those due to the interactions between waves and tides. Two case studies illustrate the techniques applied and the implications for tidal device deployment: (a) Marine Current Turbines (MCT) are planning to deploy an array of their SeaGen tidal devices off the northwest Anglesey coast, UK; and (b) THETIS Energy Ltd are planning a development off the north Northern Ireland coast in the North Channel. The sites are characterised by moderately severe wave conditions, strong currents, and complex geomorphologic features, yielding highly variable and spatially complex, tidal range dependent current patterns. The regional hydrodynamic models (based on the TELEMAC system, an unstructured finite element solver from Electricité de France, now publicly distributed under an open source license) were calibrated against good quality field data for both sites, and captured the strong variability of the currents to a grid resolution of about 10 m over 30-day tidal cycles. Some areas were found to have strong currents on the flood tide but much weaker currents on the ebb, and vice versa and directions were not necessarily opposite. Areas with appropriate water depths, consistently good flow characteristics and, therefore, commercially attractive energy resource comprised only parts of the pre-selected sites. Off the northwest Anglesey coast, the TELEMAC-2D hydrodynamic model was complemented with a third generation wave transformation model. The local wave conditions are strongly affected by currents, giving rise to potentially dangerous conditions for construction and maintenance operations, as well as complex forces on the energy devices. By simulating the power take-off and physical characteristics of the MCT SeaGen devices, the hydrodynamic model was used to assess the impact of individual devices on the current regime and the actual energy available from the proposed arrays taking account of wake effects (Figure 1). The extent and intensity of the wake areas were calibrated to some degree against field data obtained from the MCT Lynmouth SeaFlow deployment (installed May 2003). Wakes could extend over a significant area, requiring careful placement of the individual devices within each array to avoid reduction in power generation. Off the north Northern Ireland coast, the TELEMAC-3D hydrodynamic model was used to produce maximum and average kinetic power density maps to identify useful site survey locations. The presence of an amphidromic point not far from the site, with virtually no tidal range yet strong currents, was correctly reproduced by the hydrodynamic model. The modelling study followed or exceeded the Assessment of Tidal Energy Resource guidance set by the European Marine Energy Centre for a full feasibility stage. In particular, comparisons with observed bed-mounted current data showed differences in maximum speed at various elevations throughout the water column within 5% or better at two of the three sites (spring tide currents). Numerical modelling has proven to be effective and critical in investigating possible locations for tidal energy harnessing at a number of areas around the UK coast.
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22

Burrows, R., N. C. Yates, T. S. Hedges, M. Li, J. G. Zhou, D. Y. Chen, I. A. Walkington, J. Wolf, J. Holt, and R. Proctor. "Tidal energy potential in UK waters." Proceedings of the Institution of Civil Engineers - Maritime Engineering 162, no. 4 (December 2009): 155–64. http://dx.doi.org/10.1680/maen.2009.162.4.155.

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23

Palodichuk, Michael, Brian Polagye, and Jim Thomson. "Resource Mapping at Tidal Energy Sites." IEEE Journal of Oceanic Engineering 38, no. 3 (July 2013): 433–46. http://dx.doi.org/10.1109/joe.2012.2227578.

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24

Mohammed Abd Ali, Layth, Haider Ahmed Mohmmed, and Othman M. Hussein Anssari. "Modeling and Simulation of Tidal Energy." Journal of Engineering and Applied Sciences 14, no. 11 (November 30, 2019): 3698–706. http://dx.doi.org/10.36478/jeasci.2019.3698.3706.

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25

Padate, Ajinkya. "Tidal and Wind Energy Conversion Duo." International Journal of Renewable and Sustainable Energy 2, no. 4 (2013): 163. http://dx.doi.org/10.11648/j.ijrse.20130204.15.

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26

Bahaj, AbuBakr S. "New research in tidal current energy." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 371, no. 1985 (February 28, 2013): 20120501. http://dx.doi.org/10.1098/rsta.2012.0501.

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27

Brown, Jeff L. "Fish-Friendly Turbine Captures Tidal Energy." Civil Engineering Magazine Archive 80, no. 9 (September 2010): 44–45. http://dx.doi.org/10.1061/ciegag.0000618.

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28

Foreman, M. G. G., P. F. Cummins, J. Y. Cherniawsky, and Phyllis Stabeno. "Tidal energy in the Bering Sea." Journal of Marine Research 64, no. 6 (November 1, 2006): 797–818. http://dx.doi.org/10.1357/002224006779698341.

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29

Chi, Shunliang, and Mingjin Luo. "Tidal energy flow in solid earth." Acta Seismologica Sinica 5, no. 4 (November 1992): 877–81. http://dx.doi.org/10.1007/bf02651036.

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30

Lang, C. "Harnessing tidal energy takes new turn." IEEE Spectrum 40, no. 9 (September 2003): 13. http://dx.doi.org/10.1109/mspec.2003.1228000.

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31

Ali, Imran, Andrew Ragai Henry Rigit, Omar Bin Yaakob, Jane Labadin, and Altaf Hussain Rajpar. "Tidal energy assessment with hydrodynamic modelling." Indonesian Journal of Electrical Engineering and Computer Science 29, no. 2 (February 1, 2023): 1201. http://dx.doi.org/10.11591/ijeecs.v29.i2.pp1201-1212.

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<span lang="EN-US">The increasing demand for sustainable energy generation brings a need for tidal current energy resource exploration around the globe. Hydrodynamic modelling is an essential aspect to explore macro tidal sites. In the current research paper, a 2D hydrodynamic model is set up by utilizing the numerical application of Delft3D. The model is validated against the database results and the two macro tidal sites are identified along the coastline of Sarawak, Malaysia. The maximum available kinetic energy flux at the identified location is 0.6 kW/m2, during peak neap tide hours. This stands as a sound justification to have a detailed tidal energy assessment study in this area in future research.</span>
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32

Guillou, Nicolas, Georges Chapalain, and Simon P. Neill. "The influence of waves on the tidal kinetic energy resource at a tidal stream energy site." Applied Energy 180 (October 2016): 402–15. http://dx.doi.org/10.1016/j.apenergy.2016.07.070.

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33

Hwang, Su-jin, and Chul H. Jo. "Tidal Current Energy Resource Distribution in Korea." Energies 12, no. 22 (November 18, 2019): 4380. http://dx.doi.org/10.3390/en12224380.

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Korea is a very well-known country for having abundant tidal current energy resources. There are many attractive coastal areas for the tidal current power that have very strong currents due to the high tidal range and the acceleration through the narrow channels between islands in the west and south coasts of the Korean peninsula. Recently, the Korean government announced a plan that aims to increase the portion of electricity generated from renewable energy to 20% by 2030. Korea has abundant tidal current energy resources; however, as reliable resource assessment results of tidal current energy are not sufficient, the portion of tidal current power is very small in the plan. Therefore, a reliable resource assessment should be conducted in order to provide a basis for the development plan. This paper describes the resource assessment of tidal current energy in Korea based on the observational data provided by KHOA (Korean Hydrographic and Oceanographic Agency) and numerical simulation of water circulation. As the observational data were unable to present the detailed distribution of the complicated tidal current between islands, numerical simulation of water circulation was used to describe the detailed distribution of tidal current in Incheon-Gyeonggi and Jeollanam-do, where the tidal energy potentials are abundant. The west and south coastal areas of Korea were divided into seven regions according to the administrative district, and the theoretical tidal current potential was calculated using average power intercepted. The results of this research can provide the insight of the tidal current energy development plan in Korea.
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34

Abad, Mohammad Seydali Seyf, Jennifer A. Hayward, Saad Sayeef, Peter Osman, and Jin Ma. "Tidal Energy Hosting Capacity in Australia’s Future Energy Mix." Energies 14, no. 5 (March 8, 2021): 1479. http://dx.doi.org/10.3390/en14051479.

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This paper outlines a methodology to determine the amount of renewable energy that can be accommodated in a power system before adverse impacts such as over-voltage, over-loading and system instability occur. This value is commonly known as hosting capacity. This paper identifies when the transmission network local hosting capacity might be limited because of static and dynamic network limits. Thus, the proposed methodology can effectively be used in assessing new interconnection requests and provides an estimation of how much and where the new renewable generation can be located such that network upgrades are minimized. The proposed approach was developed as one of the components of the AUSTEn project, which was a three-year project to map Australia’s tidal energy resource in detail and to assess its economic feasibility and ability to contribute to the country’s energy needs. In order to demonstrate the effectiveness of the proposed approach, two wide area networks were developed in DIgSILENT PowerFactory based on actual Australian network data near two promising tidal resource sites. Then, the proposed approach was used to assess the local tidal hosting capacity. In addition, a complementary local hosting capacity analysis is provided to show the importance of future network upgrades on the locational hosting capaity.
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35

Park, Tae-Young, Han-Sung Kim, Yun-Wan Kim, Joo-Il Park, and Kyung-Su Kim. "The Feasibility Analysis for PungDo Tidal Current Power Generation using SeaGen 1.2MW(600kW×2) Turbine." Journal of Energy Engineering 22, no. 4 (December 31, 2013): 386–93. http://dx.doi.org/10.5855/energy.2013.22.4.386.

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36

López-González, José, Gerardo Hiriart-Le Bert, and Rodolfo Silva-Casarín. "Cuantificación de energía de una planta mareomotriz." Ingeniería, investigación y tecnología 11, no. 2 (April 1, 2010): 233–45. http://dx.doi.org/10.22201/fi.25940732e.2010.11n2.019.

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37

Wang, Taiping, and Zhaoqing Yang. "A Tidal Hydrodynamic Model for Cook Inlet, Alaska, to Support Tidal Energy Resource Characterization." Journal of Marine Science and Engineering 8, no. 4 (April 4, 2020): 254. http://dx.doi.org/10.3390/jmse8040254.

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Cook Inlet in Alaska has been identified as a prime site in the U.S. for potential tidal energy development, because of its enormous tidal power potential that accounts for nearly one-third of the national total. As one important step to facilitate tidal energy development, a tidal hydrodynamic model based on the unstructured-grid, finite-volume community ocean model (FVCOM) was developed for Cook Inlet to characterize the tidal stream energy resource. The model has a grid resolution that varies from about 1000 m at the open boundary to 100–300 m inside the Inlet. Extensive model validation was achieved by comparing model predictions with field observations for tidal elevation and velocity at various locations in Cook Inlet. The error statistics confirmed the model performs reasonably well in capturing the tidal dynamics in the system, e.g., R2 > 0.98 for tidal elevation and generally > 0.9 for velocity. Model results suggest that tides in Cook Inlet evolve from progressive waves at the entrance to standing waves at the upper Inlet, and that semi-diurnal tidal constituents are amplified more rapidly than diurnal constituents. The model output was used to identify hotspots that have high energy potential and warrant additional velocity and turbulence measurements such as East Foreland, where averaged power density exceeds 5 kw/m2. Lastly, a tidal energy extraction simulation was conducted for a hypothetical turbine farm configuration at the Forelands cross section to evaluate tidal energy extraction and resulting changes in far-field hydrodynamics.
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38

TSUDA, Muneo, Yoshinosuke KURAHARA, Soichi YMAMAGUCHI, Yusaku KYOZUKA, Hiromitsu KIYOSE, Hiroshi NAGASE, Shogo TAKASHIMA, and Akio KURIHARA. "THE CHARACTERISTICS OF TIDAL CURRENT AND TIDAL POWER GENERATION ENERGY AROUND GOTO ISLANDS." Journal of Japan Society of Civil Engineers, Ser. B3 (Ocean Engineering) 71, no. 2 (2015): I_120—I_125. http://dx.doi.org/10.2208/jscejoe.71.i_120.

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39

Sentchev, Alexei, Jérôme Thiébot, Anne-Claire Bennis, and Matthew Piggott. "New insights on tidal dynamics and tidal energy harvesting in the Alderney Race." Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 378, no. 2178 (July 27, 2020): 20190490. http://dx.doi.org/10.1098/rsta.2019.0490.

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The Introduction presents motivations, significance and some key points of the research activities performed in the Alderney Race. This article is part of the theme issue ‘New insights on tidal dynamics and tidal energy harvesting in the Alderney Race’.
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40

Neill, Simon P., M. Reza Hashemi, and Matt J. Lewis. "The role of tidal asymmetry in characterizing the tidal energy resource of Orkney." Renewable Energy 68 (August 2014): 337–50. http://dx.doi.org/10.1016/j.renene.2014.01.052.

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41

Guillou, Nicolas. "Modelling effects of tidal currents on waves at a tidal stream energy site." Renewable Energy 114 (December 2017): 180–90. http://dx.doi.org/10.1016/j.renene.2016.12.031.

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42

Dai, Peng, Jisheng Zhang, and Jinhai Zheng. "Tidal current and tidal energy changes imposed by a dynamic tidal power system in the Taiwan Strait, China." Journal of Ocean University of China 16, no. 6 (November 8, 2017): 953–64. http://dx.doi.org/10.1007/s11802-017-3237-4.

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Xia, Hainan, Xiangnan Wang, Jianjun Shi, Ning Jia, and Yunqi Duan. "Research on Analysis Method of Tidal Current Energy Resource Characteristics." Marine Technology Society Journal 56, no. 6 (December 15, 2022): 10–17. http://dx.doi.org/10.4031/mtsj.56.6.5.

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Abstract:
Abstract In the demonstration and validation of tidal energy converters, analyzing the characteristics of tidal current energy resource in the demonstration sea area of tidal energy converters is a key step to evaluate the economic performance of the tested tidal energy converter. Based on analyzing the research status and the evaluation demands of economic performance indicators of tidal energy converters at home and abroad, the analysis method of tidal current energy resource assessment and characterization was studied, a method for calculating the cumulative frequency of tidal current velocity was proposed, and it was applied in the processing and analyzing the tidal current field test data. Moreover, using the analysis results of tidal current energy resource characteristics, the annual energy production of the tested tidal energy converter was calculated. The results show that the analysis method studied in this technical note can analyze the tidal current energy resource characteristics comprehensively and objectively, and the proposed calculation method of cumulative frequency can reflect the availability of the tidal energy converter in the demonstration sea area. The research results not only provide a reference for analyzing the tidal current energy resource characteristics in the demonstration sea area of tidal energy converters, but also provide a reference for calculating the annual energy production of tidal energy converters.
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Mockler, Brenna, and Enrico Ramirez-Ruiz. "An Energy Inventory of Tidal Disruption Events." Astrophysical Journal 906, no. 2 (January 13, 2021): 101. http://dx.doi.org/10.3847/1538-4357/abc955.

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Binnie, Chris. "Tidal energy from the Severn estuary, UK." Proceedings of the Institution of Civil Engineers - Energy 169, no. 1 (February 2016): 3–17. http://dx.doi.org/10.1680/jener.14.00025.

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Firdaus, Ahmad M., Guy T. Houlsby, and Thomas A. A. Adcock. "Tidal energy resource in Larantuka Strait, Indonesia." Proceedings of the Institution of Civil Engineers - Energy 173, no. 2 (May 2020): 81–92. http://dx.doi.org/10.1680/jener.19.00042.

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Singh, Varun Kumar. "Tidal energy conversion and uses: A review." Asian Journal of Multidimensional Research 10, no. 11 (2021): 116–21. http://dx.doi.org/10.5958/2278-4853.2021.01062.4.

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Nicholls-Lee, R. F., and S. R. Turnock. "Tidal energy extraction: renewable, sustainable and predictable." Science Progress 91, no. 1 (March 1, 2008): 81–111. http://dx.doi.org/10.3184/003685008x285582.

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Couch, S. J., and I. Bryden. "Tidal current energy extraction: Hydrodynamic resource characteristics." Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment 220, no. 4 (December 2006): 185–94. http://dx.doi.org/10.1243/14750902jeme50.

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TSUTSUI, Toshihiro, and Hiroyuki NAGAI. "Effective utilization of The Surface-tidal Energy." Proceedings of the Tecnology and Society Conference 2019 (2019): G190611. http://dx.doi.org/10.1299/jsmetsd.2019.g190611.

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