Publications

Berg, Dale E.; Resor, Brian R.

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Resor, Brian R.; Paquette, Joshua P.

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Berg, Jonathan C.; Paquette, Joshua P.; Resor, Brian R.

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Resor, Brian R.; Paquette, Joshua P.

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Resor, Brian R.

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Berg, Dale E.; Berg, Jonathan C.; Resor, Brian R.; Rumsey, Mark A.

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Resor, Brian R.; Berg, Jonathan C.; Barone, Matthew F.; Paquette, Joshua P.; Johnson, Wesley D.; Rumsey, Mark A.

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Resor, Brian R.

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Resor, Brian R.

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Berg, Dale E.; Resor, Brian R.; Berg, Jonathan C.

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Resor, Brian R.; Berg, Jonathan C.

Prior work on active aerodynamic load control (AALC) of wind turbine blades has demonstrated that appropriate use of this technology has the potential to yield significant reductions in blade loads, leading to a decrease in wind cost of energy. While the general concept of AALC is usually discussed in the context of multiple sensors and active control devices (such as flaps) distributed over the length of the blade, most work to date has been limited to consideration of a single control device per blade with very basic Proportional Derivative controllers, due to limitations in the aeroservoelastic codes used to perform turbine simulations. This work utilizes a new aeroservoelastic code developed at Delft University of Technology to model the NREL/Upwind 5 MW wind turbine to investigate the relative advantage of utilizing multiple-device AALC. System identification techniques are used to identify the frequencies and shapes of turbine vibration modes, and these are used with modern control techniques to develop both Single-Input Single-Output (SISO) and Multiple-Input Multiple-Output (MIMO) LQR flap controllers. Comparison of simulation results with these controllers shows that the MIMO controller does yield some improvement over the SISO controller in fatigue load reduction, but additional improvement is possible with further refinement. In addition, a preliminary investigation shows that AALC has the potential to reduce off-axis gearbox loads, leading to reduced gearbox bearing fatigue damage and improved lifetimes.

Resor, Brian R.

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Resor, Brian R.; Paquette, Joshua P.; Laird, Daniel L.; Griffith, Daniel G.

The blades of a modern wind turbine are critical components central to capturing and transmitting most of the load experienced by the system. They are complex structural items composed of many layers of fiber and resin composite material and typically, one or more shear webs. Large turbine blades being developed today are beyond the point of effective trial-and-error design of the past and design for reliability is always extremely important. Section analysis tools are used to reduce the three-dimensional continuum blade structure to a simpler beam representation for use in system response calculations to support full system design and certification. One model simplification approach is to analyze the two-dimensional blade cross sections to determine the properties for the beam. Another technique is to determine beam properties using static deflections of a full three-dimensional finite element model of a blade. This paper provides insight into discrepancies observed in outputs from each approach. Simple two-dimensional geometries and three-dimensional blade models are analyzed in this investigation. Finally, a subset of computational and experimental section properties for a full turbine blade are compared.

Gregory, Danny L.; Starr, Michael J.; Resor, Brian R.; Jew, Michael J.; Lauffer, James P.

The problem of understanding and modeling the complicated physics underlying the action and response of the interfaces in typical structures under dynamic loading conditions has occupied researchers for many decades. This handbook presents an integrated approach to the goal of dynamic modeling of typical jointed structures, beginning with a mathematical assessment of experimental or simulation data, development of constitutive models to account for load histories to deformation, establishment of kinematic models coupling to the continuum models, and application of finite element analysis leading to dynamic structural simulation. In addition, formulations are discussed to mitigate the very short simulation time steps that appear to be required in numerical simulation for problems such as this. This handbook satisfies the commitment to DOE that Sandia will develop the technical content and write a Joints Handbook. The content will include: (1) Methods for characterizing the nonlinear stiffness and energy dissipation for typical joints used in mechanical systems and components. (2) The methodology will include practical guidance on experiments, and reduced order models that can be used to characterize joint behavior. (3) Examples for typical bolted and screw joints will be provided.

Berg, Dale E.; Resor, Brian R.; Barone, Matthew F.; Berg, Jonathan C.

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Berg, Dale E.; Resor, Brian R.; Barone, Matthew F.; Berg, Jonathan C.

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Berg, Dale E.; Barone, Matthew F.; Resor, Brian R.; Berg, Jonathan C.; Paquette, Joshua P.; Zayas, Jose R.

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Berg, Dale E.; Barone, Matthew F.; Berg, Jonathan C.; Resor, Brian R.

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Resor, Brian R.; Starr, Michael J.

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Resor, Brian R.; Starr, Michael J.

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Resor, Brian R.

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Resor, Brian R.

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Resor, Brian R.

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Urbina, Angel U.; Paez, Thomas L.; Gregory, Danny L.; Resor, Brian R.

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Paez, Thomas L.; Urbina, Angel U.; Bitsie, Fernando; Gregory, Danny L.; Resor, Brian R.; Segalman, Daniel J.

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