Author
W.M.J. Batten
Bio: W.M.J. Batten is an academic researcher from University of Southampton. The author has contributed to research in topics: Turbine & Turbulence. The author has an hindex of 14, co-authored 27 publications receiving 2370 citations.
Papers
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TL;DR: In this paper, the results of cavitation tunnel and tank tests on an 800 mm diameter model of a marine current turbine (MCT) were presented, and the results provided useful information for the hydrodynamic design of MCTs and detailed data for the validation of numerical models.
671 citations
TL;DR: In this paper, the authors developed a blade element momentum (BEM) model for the hydrodynamic design of marine current turbines, which includes routines for interpolation of 2D section data and extrapolation for stall delay.
352 citations
TL;DR: In this paper, the authors report on the development and verification of simulation tools based on blade element momentum theory for marine current turbines, including a commercial code (GH-Tidal Bladed) and an academic in-house code (SERG-tidal).
273 citations
TL;DR: In this paper, a methodology for the hydrodynamic design of horizontal axis marine current turbines is presented, where a numerical model of a typical 3D rotor is used to demonstrate parametric variations of the design parameters and the use of alternative blade sections.
265 citations
TL;DR: In this paper, a study has been carried out on the power, thrust and cavitation characteristics of a 1/20th scale model of a possible 16 m diameter horizontal axis tidal turbine.
238 citations
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TL;DR: A review of the current state of the art in computational optimization methods applied to renewable and sustainable energy can be found in this article, which offers a clear vision of the latest research advances in this field.
Abstract: Energy is a vital input for social and economic development. As a result of the generalization of agricultural, industrial and domestic activities the demand for energy has increased remarkably, especially in emergent countries. This has meant rapid grower in the level of greenhouse gas emissions and the increase in fuel prices, which are the main driving forces behind efforts to utilize renewable energy sources more effectively, i.e. energy which comes from natural resources and is also naturally replenished. Despite the obvious advantages of renewable energy, it presents important drawbacks, such as the discontinuity of generation, as most renewable energy resources depend on the climate, which is why their use requires complex design, planning and control optimization methods. Fortunately, the continuous advances in computer hardware and software are allowing researchers to deal with these optimization problems using computational resources, as can be seen in the large number of optimization methods that have been applied to the renewable and sustainable energy field. This paper presents a review of the current state of the art in computational optimization methods applied to renewable and sustainable energy, offering a clear vision of the latest research advances in this field.
1,394 citations
TL;DR: In this paper, the results of cavitation tunnel and tank tests on an 800 mm diameter model of a marine current turbine (MCT) were presented, and the results provided useful information for the hydrodynamic design of MCTs and detailed data for the validation of numerical models.
671 citations
TL;DR: Tidal energy has the potential to play a valuable part in a sustainable energy future and is an extremely predictable energy source, depending only on the gravitational pull of the moon and the sun and the centrifugal forces created by the rotation of the earth-moon system as discussed by the authors.
433 citations
TL;DR: In this article, the authors show that the fractional power loss increases from 1/3 to 2/3 as the fraction of the channel cross-section spanned by the turbines increases from 0 to close to 1.
Abstract: There is an upper bound to the amount of power that can be generated by turbines in tidal channels as too many turbines merely block the flow. One condition for achievement of the upper bound is that the turbines are deployed uniformly across the channel, with all the flow through them, but this may interfere with other uses of the channel. An isolated turbine is more effective in a channel than in an unbounded flow, but the current downstream is non-uniform between the wake of the turbines and the free stream. Hence some energy is lost when these streams merge, as may occur in a long channel. We show here, for ideal turbine models, that the fractional power loss increases from 1/3 to 2/3 as the fraction of the channel cross-section spanned by the turbines increases from 0 to close to 1. In another scenario, possibly appropriate for a short channel, the speed of the free stream outside the turbine wake is controlled by separation at the channel exit. In this case, the maximum power obtainable is slightly less than proportional to the fraction of the channel cross-section occupied by turbines.
382 citations
TL;DR: In this paper, the authors developed a blade element momentum (BEM) model for the hydrodynamic design of marine current turbines, which includes routines for interpolation of 2D section data and extrapolation for stall delay.
352 citations