Numerical Analysis of the Influence of Design Parameters on the Efficiency of an OWC Axial Impulse Turbine for Wave Energy Conversion

Luo, Yongyao; Presas, Alexandre; Zhengwei, Wang

doi:10.3390/en12050939

Cited by 13 publications

(5 citation statements)

References 19 publications

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“…The literature on OWC PTO systems primarily focuses on improving the converter's efficiency through the optimization of air turbine characteristics ( [191][192][193], among others) and the installation of high-speed safety valves [75,194,195]. On the other hand, only a few papers deal with the joint study of air turbines and generators, developing control algorithms under different sea states.…”

Section: Future Developmentsmentioning

confidence: 99%

Floating Oscillating Water Column Wave Energy Converters: A Review of Developments

Konispoliatis

2024

J Energ Power Technol

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The main challenge in designing offshore renewable energy structures is to ensure their structural integrity on a life cycle basis while operating in harsh environments and, in parallel, being financially competitive and environmentally friendly concerning other types of energy systems. The Oscillating Water Column (OWC) converters are among the first energy converters to be developed and deployed into the sea due to their relative simplicity of operation and relatively small number of moving parts. This review provides an overview of the recent floating OWC prototypes and projects and the latest research developments in wave energy conversion using the oscillating water column principle. Furthermore, critical structural advances are discussed, mainly focusing on the converter’s geometry and type and its mooring system design towards amplifying the absorbed wave power.

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Section: Future Developmentsmentioning

confidence: 99%

Floating Oscillating Water Column Wave Energy Converters: A Review of Developments

Konispoliatis

2024

J Energ Power Technol

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“…Figure 3 shows the CFD simulation results of the impulse turbine under steady-state conditions, which include the input coefficient CA, torque coefficient CT, and overall efficiency  of the turbine under different flow coefficients . In addition, the numerical results are compared with the experimental results of Setoguchi [16], the experimental results of Liu [17], and the simulation results of Luo [18]. As shown in figure 3(a), the input coefficient CA of the turbine shows an upward trend followed by a slow decline as the flow coefficient increases.…”

Section: Outflow Characteristicsmentioning

confidence: 99%

Analysis of OWC impulse turbine flow characteristics considering the blade tip clearance

Jiajie,

Yexiang,

Jie

et al. 2024

J. Phys.: Conf. Ser.

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Oscillating water column (OWC) ocean wave energy recovery device is a popular technology in current wave energy research, which possesses the advantages of a sturdy structure and low-maintenance requirements. The device recovers energy by unidirectional rotation in the reciprocating airflow generated by an impulse turbine. Its operational performance depends on the flow efficiency of the core component, the air turbine. In this paper, a prototype impulse turbine with blades tip clearance of 1 mm was considered, and the SST k-ω turbulence model is used to calculate the operating performance of the air turbine at different operating points. The calculation result shows that the efficiency of the turbine under the optimal operating conditions is about 51.41%. When the flow coefficient is less than 0.8, the primary focus of energy loss in the rotor occurs at the blade tip. The low flow rate leads to a high inlet angle causing fluid friction. In these small flow conditions, the pressure drop at the leaf top gap is cantered on the inlet, and the speed in the gap flow field is significantly reduced. When the flow coefficient is greater than 1.4, the concentration of energy loss in the rotor primarily occurs within the flow channel, where the high-velocity air causing a local high-speed zone.

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“…Only a few references, e.g. [13], analysed some basic parameters in the case of axial impulse turbine. Nevertheless, an important design parameter such as skew, lean and sweep angle, which have been extensively studied for Wells turbines, have not been almost studied for impulse turbines.…”

Section: Introductionmentioning

confidence: 99%

Influence of the blade leaning angle on the performance of a radial impulse turbine for OWC converters

Valladares

Díaz

Pereiras

et al. 2022

J. Phys.: Conf. Ser.

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Oscillating Water Column systems (OWC) have been in the spotlight in the last 20 years since these devices are considered one of the most promising devices among wave energy technology. These systems produce electricity by means a generator driven by a turbine, which takes advantage of the bidirectional flow created by the OWC itself. Among these turbines suitable for bidirectional flows, it is possible to find radial impulse turbines, which are the focus of this work. Traditionally, the radial impulse turbines have shown lower efficiencies than their competitors. However, the radial turbines present interesting mechanical features and, recently, some research show that the difference has been reduced. Following this thread, this work deals with another modification in the radial impulse turbine looking for a further improvement. By using a validated CFD model, it has been analysed the influence of the lean angle of the blade. Until now, all the turbines present in the literature are leaned zero degrees, leading to a strong interaction between the guide vanes and the blades. This work shows results of the same turbine, equipped with blades leaning from -5deg to 25deg, in order to determine the influence such a modification on the maximum total-to-static efficiency. Results have revealed a slight improvement in the maximum efficiency for positive leaning angles, whereas negative angles drive the turbine to worse performance.

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Numerical Analysis of the Influence of Design Parameters on the Efficiency of an OWC Axial Impulse Turbine for Wave Energy Conversion

Cited by 13 publications

References 19 publications

Floating Oscillating Water Column Wave Energy Converters: A Review of Developments

Floating Oscillating Water Column Wave Energy Converters: A Review of Developments

Analysis of OWC impulse turbine flow characteristics considering the blade tip clearance

Influence of the blade leaning angle on the performance of a radial impulse turbine for OWC converters

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