Measurements of environmental conditions

For the use of offshore wind energy, a profound knowledge of the prevailing environmental conditions at existing and future sites is substantial. In the different project phases from planning to implementation to operation, different information is required. Fraunhofer IWES acquires, analyzes and evaluates all relevant environmental conditions for offshore power plants: wind, waves, currents and soil conditions.

The required site conditions depend on the respective project phase. In accordance with requirements specific information about the site from different sources is used. At an early time of planning Fraunhofer IWES creates an overall concept for the collection and analysis of data. In the design phase of the plant knowledge of design conditions like the extreme values of environmental parameters is essential for
estimating the loads on the turbines. Similarly, an exact knowledge about the soil conditions for the design of foundations is vital. For offshore wind farms a highly accurate acquisition of wind data at high altitudes and the combination of measured with modeled data allows more planning certainty for the wind farm layout. 

Infographic LiDAR Buoy
© Photo Fraunhofer IWES Nordwest

LiDAR systems send pulsed laser beams into the atmosphere, which reflect off of aerosol particles in the air. From the frequency shift of the backscattered signal, the wind speed and direction are calculated at the corresponding measurement heights

Measurement campaigns for an offshore wind resource assessment with the in-house developed Fraunhofer IWES Wind Lidar buoy include the complete yield assessment for the development of an offshore wind project. The floating system integrates a Wind-cube® v2 Lidar device in an adapted marine buoy. Its compact design, an autonomous power system and an efficient data processing and communication system ensure reliable and flexible offshore wind measurement campaigns at minimal costs. The motion correction algorithm guarantees high data accuracy and measurement uncertainties similar to those for offshore mast measurements. in all project phases including planning, installation and operation of offshore wind power plants.

Fraunhofer developed a correction algorithm that allows LiDAR systems to carry out measurements even on moving structures. The algorithm subtracts the buoy’s own movement from the measurement values.

Brochure "Validated LiDAR system for flexible offshore site assessment"

 

 

SERVICES

• Wind velocity measurements up to 200 m
• Additional measurements available: waves, currents, temperature etc.
• Full service contract including permission, deployment, service, data transfer, quality control
• Wind resource assessment based on these data
• Measurement campaigns from one week to one year possible.

 

 

Ship-based LiDAR system


For flexible wind measurements under offshore conditions, the "ship-based Lidar system" facilitates the application of standard wind lidar technology on ships. Whereas measurements from fixed platforms or anchored buoys are a recommendable solution for long-term applications, a ship-based solution is best when a ship is in use at the location of interest anyway or when a measurement is needed for a rather short period only.

A prerequisite for a precise measurement from a moving ship is the correction of the measured data with respect to the concurrent motions. Hence, an integrated motion-measurement system is an essential part of the developed Ship-Lidar System. Data for the up to six degrees of freedom of the system placed on the ship are recorded with high resolution, processed and applied for a correction of the concurrently recorded lidar data.

© Photo Fraunhofer IWES Nordwest

A multi-channel seismic system makes it possible to look at depths of down to 50 meters and provides high-resolution data.

 

 

Exact knowledge of local construction site conditions is an important prerequisite for the planning and development of offshore wind farms. This is the basis for the choice and optimal dimensioning of wind energy turbine support structures. As the foundation work costs have a comparatively large share of the total offshore wind energy turbine costs this area has a great cost optimization potential.

Established investigation methods such as geological drilling and penetration tests deliver important foundation-relevant information, however, they are limited to the respective test sites. Using these methods it is only partially possible to gain information on construction site conditions in the surrounding areas; this can be inadequate and especially for foundation structures such as ackets or tripods.


In contrast, geophysical methods give an extensive, comparatively fast and cost effective overview of the foundation conditions, however, they do not allow direct statements to be made concerning foundation characteristics. One of the aims of the Offshore Site Assessment, Ground group to consider the subject of foundation assessment holistically and to usefully and effectively apply the different methods in relation to each other.

 

 

In the geophysics field Fraunhofer IWES has developed a multi-channel seismic measuring process which is particularly tailored to offshore wind energy requirements. Common problems in conventional measuring processes such as inadequate signal penetration and the bad mapping of complex structures have been overcome. We have successfully conducted geophysical surveys for several customers for offshore wind farms with this method. The results show unprevailed resolution and signal penetration in the characterisation of subsoil conditions for offshore wind farms.

Regarding geotechnical offshore foundation structure dimensioning, the working group offers in-situ surveying methods (CPT) and geotechnical as well as both monotone and cyclical laboratory testing in order to characterize sea-bed samples. The parameters gained here are the basis for assessment and the foundation construction dimensioning process. The assessment is carried out pursuant to BSH standards, encompasses cyclic loading and is, according to client’s wishes and requirements, supported and safeguarded through implementing FE procedures.

 

Simple-shear cell

SERVICES

• Cyclic triaxial test
• Cyclic direct simple shear test DSS
• Consulting on using the test results in the technical design
• Consulting on planning and development

According to DNV GL OS-J101 and many other recent guidelines and national requirements, geotechnical soil investigation consists of in-situ testing of soil and of soil sampling with subsequent laboratory testing.
All this shall provide the following types of geotechnical data for all important layers:

• Data for soil classification and description
• Shear strength and deformation properties, as required for the type of analysis to be carried out
• in-situ stress conditions

The laboratory test program for determination of soil strength and deformation properties covers a set of different types of tests and a number of tests of each type, which will suffice to carry out a detailed foundation design. For mineral soils, such as sand and clay, direct simple shear tests and triaxial tests are relevant types of tests for determining strength properties.

Since the offshore wind turbines structures are subjected to waves and wind, the effects of cyclic loading on the soil properties shall be considered in foundation design. Cyclic shear stresses may lead to a gradual increase in pore pressure. Pore pressure build-up and the accompanying increase in cyclic and permanent shear strains may reduce the shear strength of the soil. These effects have to be taken into account in the assessment of the characteristic shear strength for usage in the design within applicable limit state categories as well as in the assessment of permanent foundation rotations.

Fraunhofer IWES in collaboration with cooperation partners offers advanced geotechnical laboratory testing and provides assistance in planning of cyclic and static test programs for determination of soil properties under a range of load conditions to be covered by the foundation design and installation procedure.

Geotechnical Laboratory Investigations

Aquadopp units measure the direction and speed of the current

© Photo Jan Meier

 

Detailed characterization of the current and wave conditions is vital for designing offshore wind turbines. Site assessment with accurate prediction of the expected energy output lowers the technical and financial risks for project planners and investors. The current conditions around the foundations of offshore wind turbines determine not only the loads on the structure but also cause sediment transport close to the structure which can lead to pitting.

Detailed analysis of current data has highlighted the complex spatial and time variability of sea currents. The cause of current variations are the effects of turbulence, waves and wind on the avarage current. As a consequence, the electrical output of the turbine varies considerabely and high dynamic loads on the rotor and structure can occur. Accurate analysis of the current field is limited by the low spatial and time resolution of the ADCP (Acoustic Doppler Current Profiler) method that is currently used - but can be improved significantly by using acoustic measuring units. In the direct vicinity of the foundation of an offshore wind turbine they allow detailed investigation of the interaction between the structure and current and the resulting sediment transport.

 

Publications

Entwicklung neuer Prüfmethoden zur Abbildung der Degradationsprozesse von Offshore-Windenergieanlagen und Aufbau einer entsprechenden Test- und Analyse-Infrastruktur für WEA-Komponenten
Kupferschmidt, C.; Collmann, M.; Kranz, O.
(Conference Presentation and book chapter)

45. Jahrestagung der Gesellschaft für Umweltsimulation (GUS)
16.-18. März 2016, Karlsruhe
zu Fraunhofer Publica



Project schedule assessment with a focus on different input weather data sources
Wolken-Möhlmann, Bendlin, Buschmann, Wiggert
(Poster)

Deep Sea Offshore Wind R&D Conference
Energy Procedia, Volume 94, September 2016, Pages 517-522
Jan. 20-22,Trondheim, Norway
urn:nbn:de:0011-n-4174014
http://publica.fraunhofer.de/dokumente/N-417401.html


WindScanner Measurements in Complex Terain
Lukas Pauscher, Nikola Vasiljevic, Doron Callies, Guillaume Lea, Jakob Mann, Fernando Borbón, Tobias Klaas, Julia Gottschall, Julian Hieronimus, Martin Kühn, Michael Courtney
(Conference Presentation)

18. Internat. Symposium for the Advancement of Boundary-Layer Remote Sensing
June 6-9, 2016, Varna, Bulgaria
noch nicht online


An Inter-Comparison Study of Multi- and DBS Lidar Measurements in Complex Terrain
Lukas Pauscher, Nikola Vasiljevic, Doron Callies, Guillaume Lea, Jakob Mann, Tobias Klaas, Julian Hieronimus, Julia Gottschall, Annedore Schwesig, Martin Kühn, and Michael Courtney
(magazine article)

Remote Sens. 2016, 8 (9)
DOI: 10.3390/rs8090782 (full version)
zu Fraunhofer Publica


Das ERA-NET+ Projekt NEWA - The New European Wind Atlas
Gottschall, J.; Lange, B.; Kühn, P.; Callies, D.; Heinemann, D.; Witha, B.; Steinfeld, G.
(Presentation)

Fachtagung Energiemeteorologie
20.-24. April 2016, Bremerhaven
zu Fraunhofer Publica


Floating Lidar Systems: Current Technology Status and Requirements for Improved Maturity
Gottschall, Gribben, Hughes, Stein, Würth, Bischoff, Schlipf, Verhoef, Clifton
(Conference Presentation)

Wind Europe Summit
25.-28. Sept. 2016, Hamburg
urn:nbn:de:0011-n-4173977 (full version)
zu Fraunhofer Publica

 

Innovative measurement technologies for offshore wind site characterization
Lange, Gottschall, Rudolph, Wolken-Möhlmann, Viergutz, Meier, Spieß
(Presentation)

MRP Offshore Wind Site Characterization Workshop
Woods Hole, USA
Oct. 6, 2016
urn:nbn:de:0011-n-4173956
(full version)
zu Fraunhofer Publica


Fraunhofer IWES Wind-LiDAR-Buoy
Lange, Bernhard
(Presentation)

IEA Wind Task 32 Workshop on Floating Lidar Systems: Current Technology Status and Requirements for Improved Maturity
Feb. 23-24, 2016, Blyth, UK
zu Fraunhofer Publica


IEA Wind Annex 32 Work Package 1.5 State-of-the-Art Report: Recommended Practices for Floating Lidar Systems
Bischoff, O.; Gottschall, J.; Gribben, B.; Hughes, J.; Stein, D.; Verhoef, H.; Würth, I.
(Report)
zu Fraunhofer Publica


Meer - Wind - Strom. Forschung am ersten deutschen Offshore-Windpark alpha ventus
Beteiligt: Durstewitz, Michael (Hrsg.); Lange, Bernhard (Hrsg.)
(Book)

Wiesbaden: Springer Fachmedien, 2016
zu Fraunhofer Publica


Neue Erkenntnisse zur Meteorologie aus FINO-Wind
Bastigkeit, I.; Leiding, T.
(Presentation)

FINO-Wind Abschlussworkshop
15. April 2016, Hamburg
zu Fraunhofer Publica


Standardized assessment of meteorological data from FINO platforms
Bastigkeit, I.; Bégué, F.; Frühmann, R.; Gates, L.; Herklotz, K.; Leiding, T.; Müller, S.; Neumann, T.; Schwenk, P.; Sedlatschek, R.; Senet, C.; Tinz, B.; Wilts,F.
(Poster)

4. Fachtagung Energiemeteorologie 2016
20.-22. April 2016, Bremerhaven
zu Fraunhofer Public