Your search keyword '"Ryan Ashton"' showing total 5 results

1. Identification of tower-wake distortions using sonic anemometer and lidar measurements

Author

Paul T. Quelet, Mithu Debnath, W. Alan Brewer, Daniel E. Wolfe, James M. Wilczak, G. Valerio Iungo, Katherine McCaffrey, Ryan Ashton, Aditya Choukulkar, Julie K. Lundquist, and Steven P. Oncley

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, lcsh:TA715-787, Planetary boundary layer, 020209 energy, lcsh:Earthwork. Foundations, 02 engineering and technology, Wind direction, Wake, 01 natural sciences, Wind speed, lcsh:Environmental engineering, Anemometer, Turbulence kinetic energy, Wind wave, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TA170-171, Tower, Geology, 0105 earth and related environmental sciences

Abstract

The eXperimental Planetary boundary layer Instrumentation Assessment (XPIA) field campaign took place in March through May 2015 at the Boulder Atmospheric Observatory, utilizing its 300 m meteorological tower, instrumented with two sonic anemometers mounted on opposite sides of the tower at six heights. This allowed for at least one sonic anemometer at each level to be upstream of the tower at all times and for identification of the times when a sonic anemometer is in the wake of the tower frame. Other instrumentation, including profiling and scanning lidars aided in the identification of the tower wake. Here we compare pairs of sonic anemometers at the same heights to identify the range of directions that are affected by the tower for each of the opposing booms. The mean velocity and turbulent kinetic energy are used to quantify the wake impact on these first- and second-order wind measurements, showing up to a 50 % reduction in wind speed and an order of magnitude increase in turbulent kinetic energy. Comparisons of wind speeds from profiling and scanning lidars confirmed the extent of the tower wake, with the same reduction in wind speed observed in the tower wake, and a speed-up effect around the wake boundaries. Wind direction differences between pairs of sonic anemometers and between sonic anemometers and lidars can also be significant, as the flow is deflected by the tower structure. Comparisons of lengths of averaging intervals showed a decrease in wind speed deficit with longer averages, but the flow deflection remains constant over longer averages. Furthermore, asymmetry exists in the tower effects due to the geometry and placement of the booms on the triangular tower. An analysis of the percentage of observations in the wake that must be removed from 2 min mean wind speed and 20 min turbulent values showed that removing even small portions of the time interval due to wakes impacts these two quantities. However, a vast majority of intervals have no observations in the tower wake, so removing the full 2 or 20 min intervals does not diminish the XPIA dataset.

Published

2017

2. Assessing State-of-the-Art Capabilities for Probing the Atmospheric Boundary Layer: The XPIA Field Campaign

Author

Scott P. Sandberg, Clara M. St. Martin, Steven P. Oncley, Armita Hamidi, Laura Bianco, Ruben Delgado, W. Alan Brewer, James M. Wilczak, Rob K. Newsom, Paul T. Quelet, Edward Strobach, Patrick Langan, John L. Schroeder, Joseph C. Y. Lee, Aleya Kaushik, Brian Joseph Vanderwende, Ryan Ashton, Rochelle Worsnop, David Noone, Katja Friedrich, William J. Shaw, Giacomo Valerio Iungo, Branko Kosovic, Katherine McCaffrey, Alexandra St. Pé, A. M. Weickmann, L. C. Sparling, Evan Lavin, Julie K. Lundquist, Adam Lass, Daniel E. Wolfe, Andrew Clifton, Aditya Choukulkar, Mithu Debnath, Ken Tay, and W. Scott Gunter

Subjects

Atmospheric Science, Measurement method, Wind power, 010504 meteorology & atmospheric sciences, Meteorology, business.industry, Planetary boundary layer, 020209 energy, 02 engineering and technology, 01 natural sciences, Radar systems, Lidar, Observatory, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Spatial variability, business, Field campaign, 0105 earth and related environmental sciences, Remote sensing

Abstract

To assess current capabilities for measuring flow within the atmospheric boundary layer, including within wind farms, the U.S. Department of Energy sponsored the eXperimental Planetary boundary layer Instrumentation Assessment (XPIA) campaign at the Boulder Atmospheric Observatory (BAO) in spring 2015. Herein, we summarize the XPIA field experiment, highlight novel measurement approaches, and quantify uncertainties associated with these measurement methods. Line-of-sight velocities measured by scanning lidars and radars exhibit close agreement with tower measurements, despite differences in measurement volumes. Virtual towers of wind measurements, from multiple lidars or radars, also agree well with tower and profiling lidar measurements. Estimates of winds over volumes from scanning lidars and radars are in close agreement, enabling the assessment of spatial variability. Strengths of the radar systems used here include high scan rates, large domain coverage, and availability during most precipitation events, but they struggle at times to provide data during periods with limited atmospheric scatterers. In contrast, for the deployment geometry tested here, the lidars have slower scan rates and less range but provide more data during nonprecipitating atmospheric conditions. Microwave radiometers provide temperature profiles with approximately the same uncertainty as radio acoustic sounding systems (RASS). Using a motion platform, we assess motion-compensation algorithms for lidars to be mounted on offshore platforms. Finally, we highlight cases for validation of mesoscale or large-eddy simulations, providing information on accessing the archived dataset. We conclude that modern remote sensing systems provide a generational improvement in observational capabilities, enabling the resolution of finescale processes critical to understanding inhomogeneous boundary layer flows.

Published

2017

3. Evaluation of single and multiple Doppler lidar techniques to measure complex flow during the XPIA field campaign

Author

Aditya Choukulkar, Steven P. Oncley, Daniel E. Wolfe, Ryan Ashton, James M. Wilczak, A. M. Weickmann, W. Alan Brewer, Julie K. Lundquist, Mithu Debnath, Laura Bianco, Timothy A. Bonin, Ruben Delgado, Scott P. Sandberg, G. Valerio Iungo, and R. Michael Hardesty

Subjects

Atmospheric Science, Radiometer, 010504 meteorology & atmospheric sciences, lcsh:TA715-787, Planetary boundary layer, Instrumentation, lcsh:Earthwork. Foundations, 0211 other engineering and technologies, 02 engineering and technology, 01 natural sciences, Wind speed, Flow measurement, lcsh:Environmental engineering, Lidar, Anemometer, Measurement uncertainty, Environmental science, lcsh:TA170-171, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing

Abstract

Accurate three-dimensional information of wind flow fields can be an important tool in not only visualizing complex flow but also understanding the underlying physical processes and improving flow modeling. However, a thorough analysis of the measurement uncertainties is required to properly interpret results. The XPIA (eXperimental Planetary boundary layer Instrumentation Assessment) field campaign conducted at the Boulder Atmospheric Observatory (BAO) in Erie, CO, from 2 March to 31 May 2015 brought together a large suite of in situ and remote sensing measurement platforms to evaluate complex flow measurement strategies. In this paper, measurement uncertainties for different single and multi-Doppler strategies using simple scan geometries (conical, vertical plane and staring) are investigated. The tradeoffs (such as time–space resolution vs. spatial coverage) among the different measurement techniques are evaluated using co-located measurements made near the BAO tower. Sensitivity of the single-/multi-Doppler measurement uncertainties to averaging period are investigated using the sonic anemometers installed on the BAO tower as the standard reference. Finally, the radiometer measurements are used to partition the measurement periods as a function of atmospheric stability to determine their effect on measurement uncertainty. It was found that with an increase in spatial coverage and measurement complexity, the uncertainty in the wind measurement also increased. For multi-Doppler techniques, the increase in uncertainty for temporally uncoordinated measurements is possibly due to requiring additional assumptions of stationarity along with horizontal homogeneity and less representative line-of-sight velocity statistics. It was also found that wind speed measurement uncertainty was lower during stable conditions compared to unstable conditions.

Published

2018

4. Vertical profiles of the 3D wind velocity retrieved from multiple wind LiDARs performing triple range-height-indicator scans

Author

Aditya Choukulkar, Daniel E. Wolfe, William J. Shaw, Julie K. Lundquist, James M. Wilczak, W. Alan Brewer, Ryan Ashton, G. Valerio Iungo, Ruben Delgado, and Mithu Debnath

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Planetary boundary layer, 020209 energy, Instrumentation, Astrophysics::High Energy Astrophysical Phenomena, Magnitude (mathematics), 02 engineering and technology, 01 natural sciences, Wind speed, symbols.namesake, Anemometer, 0202 electrical engineering, electronic engineering, information engineering, Astrophysics::Solar and Stellar Astrophysics, lcsh:TA170-171, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Remote sensing, Propagation of uncertainty, lcsh:TA715-787, lcsh:Earthwork. Foundations, Wind direction, Geodesy, lcsh:Environmental engineering, Physics::Space Physics, symbols, Doppler effect, Geology

Abstract

Vertical profiles of the 3D wind velocity are retrieved from triple range-height-indicator (RHI) scans performed with multiple simultaneous scanning Doppler wind lidars. This test is part of the eXperimental Planetary boundary layer Instrumentation Assessment (XPIA) campaign carried out at the Boulder Atmospheric Observatory. The three wind velocity components are retrieved, then compared with the data acquired through various profiling wind lidars, and high-frequency wind data obtained from sonic anemometers installed on a 300-m meteorological tower. The results show that the magnitude of the horizontal wind velocity and the wind direction obtained from the triple RHI scans are generally retrieved with good accuracy. However, poor accuracy is obtained for the evaluation of the vertical velocity, which is mainly due to its typically smaller magnitude, and the error propagation connected with the data retrieval procedure and accuracy in the experimental setup.

Published

2016

5. Hub vortex instability within wind turbine wakes: Effects of wind turbulence, loading conditions, and blade aerodynamics

Author

Simone Camarri, François Gallaire, Ryan Ashton, Giacomo Valerio Iungo, and Francesco Viola

Subjects

Fluid Flow and Transfer Processes, Physics, 010504 meteorology & atmospheric sciences, Blade (geometry), business.industry, Turbulence, Computational Mechanics, Aerodynamics, 01 natural sciences, Instability, Turbine, 010305 fluids & plasmas, Vortex, Physics::Fluid Dynamics, Linear stability analysis, Modeling and Simulation, 0103 physical sciences, Aerospace engineering, business, Wind turbulence, 0105 earth and related environmental sciences

Abstract

The near wake of wind turbines is characterized by the presence of the hub vortex, which is a coherent vorticity structure generated from the interaction between the root vortices and the boundary layer evolving over the turbine nacelle. Bymoving downstream, the hub vortex undergoes an instability with growth rate, azimuthal and axial wavenumbers determined by the characteristics of the incoming wind and turbine aerodynamics. Thus, a large variability of the hub vortex instability is expected for wind energy applications with consequent effects on wake downstream evolution, wake interactions within a wind farm, power production, and fatigue loads on turbines invested by wakes generated upstream. In order to predict characteristics of the hub vortex instability for different operating conditions, linear stability analysis is carried out by considering different statistics of the incoming wind turbulence, thrust coefficient, tip speed ratio, and blade lift distribution of a wind turbine. Axial and azimuthal wake velocity fields are modeled through Carton-McWilliams velocity profiles by mimicking the presence of the hub vortex, helicoidal tip vortices, and matching the wind turbine thrust coefficient predicted through the actuator disk model. The linear stability analysis shows that hub vortex instability is strongly affected by the wind turbine loading conditions, and specifically it is promoted by a larger thrust coefficient. A higher load of the wind turbines produces an enhanced axial velocity deficit and, in turn, higher shear in the radial direction of the streamwise velocity. The axial velocity shear within the turbine wake is also the main physical mechanism promoting the hub vortex instability when varying the lift distribution over the blade span for a specific loading condition. Cases with a larger velocity deficit in proximity of the wake center and less aerodynamic load towards the blade tip result to be more unstable. Moreover, wake swirl promotes hub vortex instability, and it can also affect the azimuthal wave number of the most unstable mode. Finally, higher Reynolds stresses and turbulent eddy viscosity decrease both growth rate and azimuthal wave number of the most unstable mode.