Ian Prowell scite author profile

Ian Prowell

5Publications

224Citation Statements Received

63Citation Statements Given

How they've been cited

275

200

How they cite others

Affiliations

University of California, San Diego, Office of Scientific and Technical Information, National Renewable Energy Laboratory

Publications

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Summary of Conclusions and Recommendations Drawn From the DeepCwind Scaled Floating Offshore Wind System Test Campaign

Robertson

Jonkman

Goupee

et al. 2013

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The DeepCwind consortium is a group of universities, national labs, and companies funded under a research initiative by the U.S. Department of Energy (DOE) to support the research and development of floating offshore wind power. The two main objectives of the project are to better understand the complex dynamic behavior of floating offshore wind systems and to create experimental data for use in validating the tools used in modeling these systems. In support of these objectives, the DeepCwind consortium conducted a model test campaign in 2011 of three generic floating wind systems: a tension-leg platform (TLP), a spar-buoy (spar), and a semi-submersible (semi). Each of the three platforms was designed to support a 1/50th-scale model of a 5-MW wind turbine and was tested under a variety of wind/wave conditions. The focus of this paper is to summarize the work done by consortium members in analyzing the data obtained from the test campaign and its use for validating the offshore wind modeling tool, FAST.

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Experimental and Numerical Seismic Response of a 65 kW Wind Turbine

Prowell

Veletzos

Elgamal

et al. 2009

Journal of Earthquake Engineering

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Estimation of Seismic Load Demand for a Wind Turbine in the Time Domain: Preprint

Prowell¹,

Elgamal²,

Uang³

et al. 2010

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Shake table testing and numerical simulation of a utility‐scale wind turbine including operational effects

Prowell¹,

Elgamal

Uang

et al. 2013

Wind Energy

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Shake table tests were undertaken on an actual wind turbine (65 kW rated power, 22.6 m hub height and a 16 m rotor diameter) using the Network for Earthquake Engineering Simulation Large High Performance Outdoor Shake Table at the University of California, San Diego. Each base shaking event was imparted in two states, whereas the turbine rotor was still (parked), and while it was spinning (operational). Each state was tested in two orientations of shaking direction, one parallel (fore-aft) and another perpendicular (side-to-side) to the axis of rotation of the rotor. Structural response characteristics are presented for motions imparted in both configurations and both operational states. Modal parameters (natural frequencies, damping ratios and mode shapes) were estimated throughout the testing program. It is found that shaking imparted in the fore-aft direction while spinning is the only observed situation where operational effects appear significant, with reductions up to 33% in seismic bending moment demand near the tower base. Using modifications developed by the research team to the FAST code, experimental results are compared with corresponding simulations to show that dynamic characteristics, acceleration time histories and trends in tower bending seismic demand can be numerically approximated. This experimental evidence and associated numerical simulations suggest that modeling of combined wind and earthquake loading with existing turbine specific codes produce meaningful results. Discrepancies between experimental and numerical results support that further refinement of simulation codes can improve accuracy beyond the current state.

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A computational platform for considering the effects of aerodynamic and seismic load combination for utility scale horizontal axis wind turbines

Asareh

Prowell²,

Volz

et al. 2016

Earthq. Eng. Eng. Vib.

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Ian Prowell

Summary of Conclusions and Recommendations Drawn From the DeepCwind Scaled Floating Offshore Wind System Test Campaign

Experimental and Numerical Seismic Response of a 65 kW Wind Turbine

Estimation of Seismic Load Demand for a Wind Turbine in the Time Domain: Preprint

Shake table testing and numerical simulation of a utility‐scale wind turbine including operational effects

A computational platform for considering the effects of aerodynamic and seismic load combination for utility scale horizontal axis wind turbines

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