Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Remote Sensing of Winds Student: Paul Behrens Placement and monitoring of wind turbines Supervisor: Stuart Bradley.

Published byArnold Russell Modified over 8 years ago

Similar presentations

Presentation on theme: "The Remote Sensing of Winds Student: Paul Behrens Placement and monitoring of wind turbines Supervisor: Stuart Bradley."— Presentation transcript:

1 The Remote Sensing of Winds Student: Paul Behrens Placement and monitoring of wind turbines Supervisor: Stuart Bradley

2 Outline ● Modern wind profiling and its problems, ● Remote sensing as a solution, ● SODAR remote sensing (Acoustic), ● LIDAR remote sensing (Laser), ● New design bi-static SODAR, phased array, ● Other applications, ● Summary.

3 The Placement and Monitoring of Wind Turbines Problems: – Building Met masts for site profiling studies becomes cost prohibitive in an era of large turbine designs. – Requirements for mast planning permission slows procedures. – For complete profiling of all turbine placements many masts or mast movements are needed. – The cost of moving a portable mast is > $30,000. – $30,000 is the cost of one remote wind profiling instrument (a SODAR) – Offshore profiling. Riso, Denmark

4 The Solution: Remote Sensing Remote sensing instruments work on Doppler principles: 1. Transmit energy toward air parcel, 2. Some energy is reflected from air parcel, 3. Detect Doppler shift in phase (SODAR) or colour (LIDAR), 4. Estimate wind velocity component toward instrument, 5. Repeat process in two more directions for all 3 wind speed components, 5. The whole process is repeated for different heights. Two dominant types of remote sensing instrument: SODAR (SOund Detection And Ranging) or LIDAR (Light Detection And Ranging) Horizontal wind Transmitter & receiver

5 SODAR Technology Utilizes the reflection of sound from turbulence. Three beams using three antennas or phased array. Majority of SODARs monostatic, i.e. Transmitter and receiver co- located. SODAR problems: - Low turbulence == low data availability, - Reflections of acoustic pulses from buildings, turbines etc. - Tilted beams can sample different winds in complex terrain.

6 SODAR Accuracy Cup vs SODAR residuals Cup vs Cup residuals With proper calibration very little deviation from cup residuals. Slight under estimation wind speeds of 16 m/s and above? Cup vs Cup - Two anemometers sampling the same air parcel

7 LIDAR Technology Use particulates in atmosphere for Doppler shift. - Similar accuracy to SODARs LIDAR problems: In clear air, no particulates for reflection, High cloud gives false data. (Qinetiq) Tilted beams sample different winds, Low spatial resolution above hub height (Qinetiq) Two major manufactures of LIDAR: Qinetiq: Scan Conically Continuous beam Leosphere: Scan in N-E-S-W steps. Pulsed beam

8 The Tilted Beam Problem Tilted beams don’t sample the same winds in complex terrain Could be significant in New Zealand!

9 Advantages: Solves the tilted beam problem Able to use microphones instead of speaker to receive pulse return, Echo strength from air parcels greater (due to additional echo from ) Overall signal levels increase by 20-40dB. (100x increase in signal to noise). 5m vertical resolution – better than existing SODAR and LIDAR systems Horizontal wind Transmitter Receivers – two phased arrays 40m 5-200m The Bi-static SODAR: Separated Transmitter and receiver modules

10 Phased Array Receiver Voltages sampled at  t Progressive phase shift in memory   Use static array of microphones. Use software based phase shifting to receive signals from different angles. Combine signals from each phase shift for specific height. The two previous bi-static instruments looked at one height only………..

11 Current Work Software: Work with ADC board to obtain 12 channels of microphone data. Repeat triggering of listening. Hardware: Finding proto-type 12 microphone array beam pattern. Making cables Theory: Other meteorological applications?

12 Other Applications: Monitoring of incoming wind profile: With knowledge of incoming wind profile we can actively control blade pitch Increases power performance and reduces mechanical fatigue Mount LIDAR/Speaker on nacelle of wind turbine LIDAR SODAR Phased array Challenges: vibrations and noise

13 Other Applications: Kokako monitoring direct, intrusive and human intensive. Replace direct monitoring use two phased arrays and triangulate Kokako position. Remotely monitor Kokako movements. Challenges: Kokako acoustic signature, Scanning in software, Signal processing and background noise, Monitoring the endangered Kokako bird Phased array beam pattern

14 The Future Complete profiling coverage of potential wind speed sites. Knowledge of incoming wind profile with real-time blade pitch control. Bi-static development a possible key instrument in increasing accuracy and coverage.

15 Thanks!!

Download ppt "The Remote Sensing of Winds Student: Paul Behrens Placement and monitoring of wind turbines Supervisor: Stuart Bradley."

Similar presentations

Snodar (Surface layer NOn-Doppler Acoustic Radar) A new instrument to measure the height of the Atmospheric boundary layer on the Antarctic plateau. Colin.

Snodar (Surface layer NOn-Doppler Acoustic Radar) A new instrument to measure the height of the Atmospheric boundary layer on the Antarctic plateau. Colin.
Chapter3 Pulse-Echo Ultrasound Instrumentation

Chapter3 Pulse-Echo Ultrasound Instrumentation
23/06/2009 – CLRC 2009 Pulsed Doppler Lidar wind profile measurement process in complex terrain Matthieu Boquet, Bruno Ribstein, Rémy Parmentier, Jean-Pierre.

23/06/2009 – CLRC 2009 Pulsed Doppler Lidar wind profile measurement process in complex terrain Matthieu Boquet, Bruno Ribstein, Rémy Parmentier, Jean-Pierre.
TERRESTRIAL LASER SCANNING (TLS): APPLICATIONS TO ARCHITECTURAL AND LANDSCAPE HERITAGE PRESERVATION – PART 1.

TERRESTRIAL LASER SCANNING (TLS): APPLICATIONS TO ARCHITECTURAL AND LANDSCAPE HERITAGE PRESERVATION – PART 1.
Inflow angle and Energy Production Jørgen Højstrup Wind Solutions / Højstrup Wind Energy Power Curve Working Group, Louisville 6 October 2014.

Inflow angle and Energy Production Jørgen Højstrup Wind Solutions / Højstrup Wind Energy Power Curve Working Group, Louisville 6 October 2014.
Extracting Energy from Wind Matt Aldeman Senior Energy Analyst Center for Renewable Energy Illinois State University.

Extracting Energy from Wind Matt Aldeman Senior Energy Analyst Center for Renewable Energy Illinois State University.
7. Radar Meteorology References Battan (1973) Atlas (1989)

7. Radar Meteorology References Battan (1973) Atlas (1989)
Wake model benchmarking using LiDAR wake measurements of multi MW turbines Stefan Kern, Clarissa Belloni, Christian Aalburg GE Global Research, Munich.

Wake model benchmarking using LiDAR wake measurements of multi MW turbines Stefan Kern, Clarissa Belloni, Christian Aalburg GE Global Research, Munich.
Lecture 12 Content LIDAR 4/15/2017 GEM 3366.

Lecture 12 Content LIDAR 4/15/2017 GEM 3366.
Thermometer Variable: temperature Units: Degrees Celsius ( o C) Accuracy: marked to 0.5 o C Cost: £10 Site: in the shade (e.g. a Stevenson Screen) Mercury.

Thermometer Variable: temperature Units: Degrees Celsius ( o C) Accuracy: marked to 0.5 o C Cost: £10 Site: in the shade (e.g. a Stevenson Screen) Mercury.
Laser Anemometry P M V Subbarao Professor Mechanical Engineering Department Creation of A Picture of Complex Turbulent Flows…..

Laser Anemometry P M V Subbarao Professor Mechanical Engineering Department Creation of A Picture of Complex Turbulent Flows…..
CEREA – Group « Meteorological Measurements » 15 September 2006 1 METEOROLOGICAL MEASUREMENTS IN THE ATMOSPHERIC BOUNDARY LAYER E. Dupont – D. Demengel.

CEREA – Group « Meteorological Measurements » 15 September METEOROLOGICAL MEASUREMENTS IN THE ATMOSPHERIC BOUNDARY LAYER E. Dupont – D. Demengel.
Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.

Specular reflectorquasi-specular reflector quasi-Lambert reflector Lambert reflector Limiting Forms of Reflection and Scatter from a Surface.
Atmospheric structure from lidar and radar Jens Bösenberg 1.Motivation 2.Layer structure 3.Water vapour profiling 4.Turbulence structure 5.Cloud profiling.

Atmospheric structure from lidar and radar Jens Bösenberg 1.Motivation 2.Layer structure 3.Water vapour profiling 4.Turbulence structure 5.Cloud profiling.
How can we get a vertical profile of the wind in the atmosphere?

How can we get a vertical profile of the wind in the atmosphere?
Anomalous Propagation Greater density slows the waves more. Less dense air does not slow the waves as much. Since density normally decreases with height,

Anomalous Propagation Greater density slows the waves more. Less dense air does not slow the waves as much. Since density normally decreases with height,
PCWG meeting Louisville CO USA October 2014 Maintenance team MT12-1 Revision of IEC61400-12-1: Wind Turbines – Part 12-1: Power performance measurements.

PCWG meeting Louisville CO USA October 2014 Maintenance team MT12-1 Revision of IEC : Wind Turbines – Part 12-1: Power performance measurements.
LiDAR analysis at a site with simple terrain Alex Clerc, Lee Cameron Tuesday 2 nd September 2014 1.

LiDAR analysis at a site with simple terrain Alex Clerc, Lee Cameron Tuesday 2 nd September
How can we get a vertical profile of the atmosphere?

How can we get a vertical profile of the atmosphere?
Balloon-Borne Sounding System (BBSS) Used for atmospheric profiling Measures P, T, RH, wind speed and direction Uncertainties arise from incorrect surface.

Balloon-Borne Sounding System (BBSS) Used for atmospheric profiling Measures P, T, RH, wind speed and direction Uncertainties arise from incorrect surface.

Similar presentations

Ads by Google