• Journal of Advanced Marine Engineering and Technology
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• 제38권5호
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• pp.541-549
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• 2014

Horizontal axis tidal turbines are machinery inherited from the principle of wind turbines to enable the application of utilizing ocean's current energy. Its function does not differ from that of wind case, which is to convert fluid's kinetics energy to mechanical torque, therefore generates electricity. Since the ocean has been an enormous source of untapped power, tidal turbines have been being investigated recently to meet human's demand of energy with respect to environment friendly approach. This paper introduces a couple of turbine designs which are anticipated to have high performance. A comparison among recent works on the same topic is also made for validation.

• 한국해양공학회지
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• 제29권5호
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• pp.366-372
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• 2015

Ocean energy is one of the most promising renewable energy resources. In particular, South Korea is one of the countries where it is economically and technically feasible to develop tidal current power plants to use tidal current energy. In this study, based on the design code for HARP_Opt (Horizontal axis rotor performance optimizer) developed by NREL (National Renewable Energy Laboratory) in the United States, and applying the BEMT (Blade element momentum theory) and GA (Genetic algorithm), the optimal shape design and performance evaluation of the horizontal axis rotor for a 200-kW-class tidal current turbine were performed using different numbers of blades (two or three) and a pitch control method (variable pitch or fixed pitch). As a result, the VSFP (Variable Speed Fixed Pitch) turbine with three blades showed the best performance. However, the performances of four different cases did not show significant differences. Hence, it is necessary when selecting the final design to consider the structural integrity related to the fatigue, along with the economic feasibility of manufacturing the blades.

• International Journal of Ocean System Engineering
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• 제3권4호
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• pp.164-168
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• 2013

Tidal-current power is now recognized as a clean power resource. The turbine blade is the fundamental component of a tidal current power turbine. The kinetic energy available within a tidal current can be converted into rotational power by turbine blades. While in service, turbine blades are generally subjected to cyclic fatigue loading due to their rotation and the rotor-tower interaction. Predicting the fatigue life under a hydrodynamic fatigue load is very important to prevent blade failure while in service. To predict the fatigue life, hydrodynamic load data should be acquired. In this study, the vibration characteristics were analyzed based on three-dimensional unsteady simulations to obtain the cyclic fatigue load. Our results can be applied to the fatigue design of horizontal-axis tidal turbines.

• 한국신재생에너지학회:학술대회논문집
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• 한국신재생에너지학회 2011년도 추계학술대회 초록집
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• pp.159.2-159.2
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• 2011

Hyundai Heavy Industries has developed a tidal current energy converter utilizing the accumulated technology as the world largest constructor for ship and offshore structures. The model has two sets of turbines in both ends in order to utilize the bi-directional current flows in flood and ebb tide. The torque produced by turbine in tidal current is directly delivered to generator along the horizontal axis, in which the turbine, gear, generator, gear and turbine are connected successively. The manufactured model for field test has the turbine diameter of 5 meters to produce the maximum power of 500kW at maximum current speed of 5m/s. The technical verification of tidal power converter was performed by means of small scale model test in towing tank as well as field test at the Strait of Uldolmok located in Jindo of Jeollanamdo province. Field test was performed by mounting the tidal current converter on the SEP(Self Elevating Platform) which could lower the 4 vertical legs on the seabed and could elevate platform over the water surface using the hydraulic power for itself. The field test performed for a month shows that power output is similar or larger compared with the expected one in design stage. This paper presents the development of tidal current energy converter and real sea field test by Hyundai Heavy Industries. This project has finished successfully and provided the technical advance toward commercial services for tidal current power generation in the south-west region in Korea.

• International Journal of Naval Architecture and Ocean Engineering
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• 제4권3호
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• pp.241-255
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• 2012

Three types of 100 kW-class tidal stream turbines are proposed and their performance is studied both numerically and experimentally. Following a wind turbine design procedure, a base blade is derived and two additional blades are newly designed focusing more on efficiency and cavitation. For the three designed turbines, a CFD is performed by using FLUENT. The calculations predict that the newly designed turbines perform better than the base turbine and the tip vortex can be reduced with additional efficiency increase by adopting a tip rake. The performance of the turbines is tested in a towing tank with 700 mm models. The scale problem is carefully investigated and the measurements are compared with the CFD results. All the prediction from the CFD is supported by the model experiment with some quantitative discrepancy. The maximum efficiencies are 0.49 (CFD) and 0.45 (experiment) at TSR 5.17 for the turbine with a tip rake.

• 한국해양환경ㆍ에너지학회지
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• 제19권2호
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• pp.151-158
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• 2016

조류발전단지는 유망한 해역에 터빈을 복수로 다배열하여 발전하는 시스템을 말한다. 이러한 단지는 각 터빈이 최대 효율로 작동하고, 최대 발전량을 얻을 수 있도록 설계되어야 하는데, 이를 위해서는 터빈 사이의 간섭으로 인한 성능 저하가 발생하지 않도록 터빈은 일정 거리를 두고 배치되어야 한다. 수평축 터빈의 경우 EMEC(European Marine Energy Centre)에서 배치거리를 제안하고 있으나, 수직축 터빈은 그러한 규정이 제안된 바 없다. 여러 연구 결과들에 따르면 수직축 터빈이 인접할 경우 성능의 향상까지 도모될 수 있으므로, 그 배치는 수평축 터빈보다 더욱 중요하게 검토될 필요가 있다. 본 논문에서는 수직축 터빈에 대하여 수평축 터빈과 같이 일정 거리를 두고 배치하는 것과 터빈을 인접하도록 배치하는 것과의 차이를 조사하였다. 이를 위해 두 터빈간의 거리와 회전방향을 파라메터로 하여 그에 따른 성능 차이를 수치해석적으로 연구하였고, 그 이유를 파악하고자 하였다. 본 연구를 통하여 가장 적절한 수치해석 영역과 조건을 설정할 수 있었으며, 인접한 두 터빈이 각각 반시계-시계방향으로 회전하는 것이 단독 터빈 2기 대비 약 9.2%의 성능향상이 예측되었다. 터빈이 대각으로 배치된 경우는 최대 약 5.6%정도 성능이 향상됨을 확인하였다. 본 연구는 수직축 터빈을 이용한 조류발전단지를 설계시 유용한 정보가 될 것으로 기대된다.

• 수산해양교육연구
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• 제25권3호
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• pp.733-742
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• 2013

The Korea has significant tidal current energy resources, but it is so hard to work underwater for tidal turbine installation. Therefore commercial diving work is very important for tidal current generator. Also, Jangjuk channel is vary famous as proper area to generate tidal current energy. Nevertheless, no one is studied about characteristics of commercial diving works with installation of tidal current generator. The purpose of this study is to introduce commercial diving with work types and investigate critical limits of diving working under the conditions, which are working only to minutes at slack tide during the neap tide. As the results, work types are five as like mooring installation, OMAS(Offshore Maintenance Access System), support structure installation, cable and turbine installation. Here, the original construction period is expected about 4 months, but the construction take 18 months to complete. The cause of extends construction period is insufficiency of researching tidal current conditions at the site and ignorance of slack tide which need to secure diving working time. Total diving working times are 110th during 18 months, the highest percentage of diving times is turbine installation about 43.6 %, and cable, mooring installation and support structure construction are 27.3 %, 15.5 %, 13.6 %, respectively. On the basis of this study, estimation of times of commercial diving is possible with work types of tidal current power, and has a significance as basic data to determining construction period.

• 한국해양환경ㆍ에너지학회지
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• 제14권4호
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• pp.230-238
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• 2011

100 kW 용량의 조류발전용 수평축 터빈(HAT)임펠러의 성능에 대한 연구를 위하여 단면 및 날개 끝 형상을 변형시킨 지름700 mm의 모형 임펠러를 설계하고 부산대학교 예인수조에서 모형 시험을 수행하였다. 축척효과를 확인하기 위하여 각각의 임펠러에 대하여 회전수를 바꾸어 레이놀즈수 변화에 따른 특성을 살펴보았으며 날개끝속도비(TSR)별로 비교 검토 하였다. 본 연구에서 제안된 레이크 임펠러의 성능이 기존 임펠러 보다 우수함을 확인 하였으며 추후 실험시설을 보완하여 보다 큰 레이놀즈수에서 실험을 수행하고 계산과 비교할 예정이다.