Abstract
As wind turbines during the past decade have increased in size so have the challenges met by the atmospheric boundary-layer meteorologists and the wind energy society to measure and characterize the huge-volume wind fields surpassing and driving them.At the DTU Wind Energy test site "Østerild" for huge wind turbines, the hub-height of a recently installed 8 MW Vestas V164 turbine soars 143 meters up above the ground, and its rotor of amazing 164 meters in diameter make the turbine tips flicker 225 meters into the sky.Following the revolution in photonics-based telecommunication at the turn of the Millennium new fibre-based wind lidar technologies emerged and DTU Wind Energy, at that time embedded within Rise National Laboratory, began in collaboration with researchers from wind lidar companies to measure remote sensed wind profiles and turbulence structures within the atmospheric boundary layer with the emerging, at that time new, all-fibre-based 1.55 μ coherent detection wind lidars.Today, ten years later, DTU Wind Energy routinely deploys ground-based vertical profilers instead of met masts for high-precision measurements of mean wind profiles and turbulence profiles. At the departments test site "Høvsøre" DTU Wind Energy also routinely calibrate and accredit wind lidar manufactures wind lidars.Meanwhile however, new methodologies for power curve assessment based on ground-based and nacelle based lidars have also emerged. For improving the turbines power curve assessments and for advancing their control with feed-forward wind measurements experience has also been gained with wind lidars installed on turbine nacelles and integrated into the turbines rotating spinners.A new mobile research infrastructure WindScanner.dk has also emerged at DTU Wind Energy. Wind and turbulence fields are today scanned from sets of three simultaneously in space and time synchronized scanning lidars. One set consists of three fast scanning continuous-wave based wind lidars (short-range system), and another consisting of three synchronized pulsed wind lidar systems (long-range system).Today, wind lidar profilers and WindScanners are routinely deployed and operated during field tests and measurement campaigns. Lidars have been installed and operated from ground, on offshore platforms, and also as scanning lidars integrated in operating turbines. As a result, wind profiles and also detailed 3D scanning of wind and turbulence fields have been achieved: 1) of the free wind aloft, 2) over complex terrain, 3) at coastal ranges with land-sea interfaces, 4) offshore, 5) in turbine inflow induction zone, and 6) of the complex and turbulent flow fields in the wakes inside wind parks.
Highlights
Since its early establishment in the 1960’s the Department of Wind Energy, until 2007 the Wind Energy Division at Risø National Laboratory, Roskilde, Denmark, and today referred to as DTU Wind Energy, has been engaged with atmospheric boundary-layer experimental measurement activities in particular with surface and boundary-layer mean wind and turbulence quantities.Most of the experimental investigations the department engaged in, from the early 1970’s throughout the 1990’s, were conveyed using quite heavy, cumbersome and expensive in-situ meteorological masts installations equipped with high-precision and calibrated micrometeorological instrumentation such as cup anemometers, wind vanes acoustic sonic anemometers, and various temperature and pressure sensors
Lidars have been installed and operated from ground, on offshore platforms, and as scanning lidars integrated in operating turbines
The aerosol Lidar was deployed as a tool to characterize puff and plume dispersion from point sources during many full-scale atmospheric diffusion tests
Summary
This content has been downloaded from IOPscience. Please scroll down to see the full text. Ser. 524 012007 (http://iopscience.iop.org/1742-6596/524/1/012007) View the table of contents for this issue, or go to the journal homepage for more. Download details: IP Address: 192.38.90.17 This content was downloaded on 18/06/2014 at 13:29 Please note that terms and conditions apply. Lidar-based Research and Innovation at DTU Wind Energy – a Review:. T Mikkelsen Department of Wind Energy, Technical University of Denmark, DTU Risø Campus, Frederiksborgvej 399; DK - 4000 Roskilde, Denmark
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