Radial Impulse Turbine for Wave Energy Conversion: A New Geometry

The Oscillating Water Column system (OWC) is an interesting concept for ocean wave energy extraction. Several kinds of air turbines have been used for pneumatic energy conversion to mechanical energy. The Wells turbine has been used widely in OWC plants. However, as an alternative the self-rectifying turbine called Impulse turbine has been studied during the last years. We are interested in the radial version of the Impulse turbine, which was initially proposed by McCormick. A former research work aimed to improve the knowledge of the local flow behaviour and the prediction of the performances for this kind of turbine has been carried out using CFD (FLUENT®). The objectives of that work were connected mainly to the elaboration of a suitable 3D model for air flow simulation in a radial Impulse turbine. Model validation was conducted through a comparison with available experimental results. In the present, the objective is, using the numerical model, to develop a new radial impulse turbine geometry that gets better performances than the original one. This new turbine geometry will be exploited next in a project for an OWC of 250 kW. In this paper we describe the flow behaviour and the performances of this new turbine. For that, we study the Torque and Input coefficients, the losses and flow direction in the turbine elements.

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Air Turbines for Wave Energy Conversion

International Journal of Rotating Machinery ◽

10.1155/2012/717398 ◽

2012 ◽

Vol 2012 ◽

pp. 1-10 ◽

Cited By ~ 41

Author(s):

Manabu Takao ◽

Toshiaki Setoguchi

Keyword(s):

Energy Conversion ◽

Wave Energy ◽

Cross Flow ◽

Wave Energy Conversion ◽

Wells Turbine ◽

Impulse Turbine ◽

Sea Trial ◽

Irregular Wave ◽

Wave Conditions ◽

Starting Characteristics

This paper describes the present status of the art on air turbines, which could be used for wave energy conversion. The air turbines included in the paper are as follows: Wells type turbines, impulse turbines, radial turbines, cross-flow turbine, and Savonius turbine. The overall performances of the turbines under irregular wave conditions, which typically occur in the sea, have been compared by numerical simulation and sea trial. As a result, under irregular wave conditions it is found that the running and starting characteristics of the impulse type turbines could be superior to those of the Wells turbine. Moreover, as the current challenge on turbine technology, the authors explain a twin-impulse turbine topology for wave energy conversion.

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A Sea Trial of Wave Power Plant With Impulse Turbine

Volume 6: Nick Newman Symposium on Marine Hydrodynamics; Yoshida and Maeda Special Symposium on Ocean Space Utilization; Special Symposium on Offshore Renewable Energy ◽

10.1115/omae2008-57535 ◽

2008 ◽

Author(s):

Manabu Takao ◽

Eiji Sato ◽

Shuichi Nagata ◽

Kazutaka Toyota ◽

Toshiaki Setoguchi

Keyword(s):

Power Plant ◽

Energy Conversion ◽

Wave Energy ◽

Rotational Speed ◽

Guide Vane ◽

Wave Power ◽

Wave Energy Conversion ◽

Wells Turbine ◽

Impulse Turbine ◽

Sea Trial

A sea trial of wave power plant using an impulse turbine with coreless generator has been carried out at Niigata-nishi Port, in order to demonstrate usefulness of the turbine for wave energy conversion. Oscillating water column (OWC) based wave power plant has been installed at the side of a breakwater and has an air chamber with a sectional area of 4 m2 (= 2m × 2m). The impulse turbine used in the sea trial has fixed guide vanes both upstream and downstream, and these geometries are symmetrical with respect to the rotor centerline in order to rotate in a single direction in bi-directional airflow generated by OWC. The turbine is operated at lower rotational speed in comparison with conventional turbines. The rotor has a tip diameter of 458 mm, a hub-to-tip ratio of 0.7, a tip clearance of 1 mm, a chord length of 82.8 mm and a solidity of 2.0. The guide vane with chord length of 107.4 mm is symmetrically installed at the distance of 30.7 mm downstream and upstream of the rotor. The guide vane has a solidity of 2.27, a thickness ratio of 0.0279, a guide vane setting angle of 30° and a camber angle of 60°. The generator is coreless type and can generate electricity at lower rotational speed in comparison with conventional generator. The rated and maximum powers of the generator are 450 W and 880 W respectively. The experimental data obtained in the sea trial of wave power plant with the impulse turbine having coreless generator was compared to these of Wells turbine which is the mainstream of the turbine for wave energy conversion. As a result, total efficiency of the plant using the impulse turbine was higher than that of Wells turbine.

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Wells Turbine for Wave Energy Conversion —Improvement of the Performance by Means of Impulse Turbine for Bi-Directional Flow

Open Journal of Fluid Dynamics ◽

10.4236/ojfd.2013.32a006 ◽

2013 ◽

Vol 03 (02) ◽

pp. 36-41 ◽

Cited By ~ 8

Author(s):

Shinya Okuhara ◽

Manabu Takao ◽

Akiyasu Takami ◽

Toshiaki Setoguchi

Keyword(s):

Energy Conversion ◽

Wave Energy ◽

Wave Energy Conversion ◽

Wells Turbine ◽

Impulse Turbine ◽

Directional Flow

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Performance Characteristics in Runner of an Impulse Water Turbine with Splitter Blade

Processes ◽

10.3390/pr9020303 ◽

2021 ◽

Vol 9 (2) ◽

pp. 303

Author(s):

Lingdi Tang ◽

Shouqi Yuan ◽

Yue Tang ◽

Zhijun Gao

Keyword(s):

Energy Conversion ◽

Flow Direction ◽

Mechanical Energy ◽

Experimental Tests ◽

High Energy ◽

Negative Energy ◽

Water Turbine ◽

Conversion Performance ◽

Water Turbines ◽

Current Energy

The impulse water turbine is a promising energy conversion device that can be used as mechanical power or a micro hydro generator, and its application can effectively ease the current energy crisis. This paper aims to clarify the mechanism of liquid acting on runner blades, the hydraulic performance, and energy conversion characteristics in the runner domain of an impulse water turbine with a splitter blade by using experimental tests and numerical simulations. The runner was divided into seven areas along the flow direction, and the power variation in the runner domain was analyzed to reflect its energy conversion characteristics. The obtained results indicate that the critical area of the runner for doing the work is in the front half of the blades, while the rear area of the blades does relatively little work and even consumes the mechanical energy of the runner to produce negative work. The high energy area is concentrated in the flow passage facing the nozzle. The energy is gradually evenly distributed from the runner inlet to the runner outlet, and the negative energy caused by flow separation with high probability is gradually reduced. The clarification of the energy conversion performance is of great significance to improve the design of impulse water turbines.

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