Susumu Takakuwa scite author profile

Susumu Takakuwa

5Publications

31Citation Statements Received

83Citation Statements Given

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Subaru (Japan), Shinshu University

Publications

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A Large-Eddy Simulation-Based Assessment of the Risk of Wind Turbine Failures Due to Terrain-Induced Turbulence over a Wind Farm in Complex Terrain

Uchida

Takakuwa²

2019

Energies

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The first part of the present study investigated the relationship among the number of yaw gear and motor failures and turbulence intensity (TI) at all the wind turbines under investigation with the use of in situ data. The investigation revealed that wind turbine #7 (T7), which experienced a large number of failures, was affected by terrain-induced turbulence with TI that exceeded the TI presumed for the wind turbine design class to which T7 belongs. Subsequently, a computational fluid dynamics (CFD) simulation was performed to examine if the abovementioned observed wind flow characteristics could be successfully simulated. The CFD software package that was used in the present study was RIAM-COMPACT, which was developed by the first author of the present paper. RIAM-COMPACT is a nonlinear, unsteady wind prediction model that uses large-eddy simulation (LES) for the turbulence model. RIAM-COMPACT is capable of simulating flow collision, separation, and reattachment and also various unsteady turbulence–eddy phenomena that are caused by flow collision, separation, and reattachment. A close examination of computer animations of the streamwise (x) wind velocity revealed the following findings: As we predicted, wind flow that was separated from a micro-topographical feature (micro-scale terrain undulations) upstream of T7 generated large vortices. These vortices were shed downstream in a nearly periodic manner, which in turn generated terrain-induced turbulence, affecting T7 directly. Finally, the temporal change of the streamwise (x) wind velocity (a non-dimensional quantity) at the hub-height of T7 in the period from 600 to 800 in non-dimensional time was re-scaled in such a way that the average value of the streamwise (x) wind velocity for this period was 8.0 m/s, and the results of the analysis of the re-scaled data were discussed. With the re-scaled full-scale streamwise wind velocity (m/s) data (total number of data points: approximately 50,000; time interval: 0.3 s), the time-averaged streamwise (x) wind velocity and TI were evaluated using a common statistical processing procedure adopted for in situ data. Specifically, 10-min moving averaging (number of sample data points: 1932) was performed on the re-scaled data. Comparisons of the evaluated TI values to the TI values from the normal turbulence model in IEC61400-1 Ed.3 (2005) revealed the following: Although the evaluated TI values were not as large as those observed in situ, some of the evaluated TI values exceeded the values for turbulence class A, suggesting that the influence of terrain-induced turbulence on the wind turbine was well simulated.

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Dual reciprocity BEM for time-stepping approach to the transient heat conduction problem in nonlinear materials

Tanaka

Matsumoto

Takakuwa

2006

Computer Methods in Applied Mechanics and Engineering

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Numerical Investigation of Stable Stratification Effects on Wind Resource Assessment in Complex Terrain

Uchida

Takakuwa²

2020

Energies

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In the present study, we perform numerical simulations considering various stable atmospheric conditions for a small-scale simple topography. Based on the obtained simulation results, we visualize the flow field and discuss drastic changes in the flow patterns. A flow pattern similar to the potential flow suddenly appears around an isolated hill as the stability increases, regardless of the inclination angle of the hill. We show that a critical Richardson number clearly exists. Furthermore, the effect of stable stratification on the evaluation of power generation is shown for typical complex terrain. We evaluate the capacity factor (%) of a 2 MW large wind turbine based on one-year virtual mast data and consider the effect of stable stratification. It is shown, in the case of stable stratification, that the capacity factor is 2.775 times greater than that under neutral stratification.

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A Dual Reciprocity Time-Stepping BEM Applied to the Transient Heat Conduction Problem of Functionally Graded Materials.

Tanaka¹,

Matsumoto²,

Suda³

et al. 2002

Trans.JSME, Ser.A

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Dual Reciprocity Bem for Transient Heat Conduction Problems in Temperature-Dependent Materials

Tanaka

Matsumoto

Takakuwa

2004

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Susumu Takakuwa

A Large-Eddy Simulation-Based Assessment of the Risk of Wind Turbine Failures Due to Terrain-Induced Turbulence over a Wind Farm in Complex Terrain

Dual reciprocity BEM for time-stepping approach to the transient heat conduction problem in nonlinear materials

Numerical Investigation of Stable Stratification Effects on Wind Resource Assessment in Complex Terrain

A Dual Reciprocity Time-Stepping BEM Applied to the Transient Heat Conduction Problem of Functionally Graded Materials.

Dual Reciprocity Bem for Transient Heat Conduction Problems in Temperature-Dependent Materials

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