Wind Short course - UMass IGERT Offshore Wind Energy Program

January 13, 2018 | Author: Anonymous | Category: Engineering & Technology, Electrical Engineering
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The International Design Standard for Offshore Wind Turbines: IEC 61400-3 IGERT Seminar February 21, 2013 J. F. Manwell, Prof. Wind Energy Center Dept. of Mechanical & Industrial Engineering Univ. of Mass., Amherst, MA 01003

Why Are Standards Necessary? • Without proper design standards, failures are much more likely 

• Offshore presents particular challenges! 2

Who Cares About Standards? • • • • •

Regulators Banks Insurance companies Designers Project developers/owners

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The Larger Context Design Standards Analytical Assessment of Components Component Certification Component Testing

Type Certification

Analytical Assessment of Entire Turbine Prototype Testing

Project Certification

Analytical Assessment of Project 4

Design Standards Process: IEC 61400-3 International Electrotechnical Commission (IEC)

• • • • • •

Prepare preliminary design (“PD”) Develop structural dynamic model of PD Specify external conditions Specify load cases Determine structural loads and stresses Check that stresses are acceptable, given chosen material • Adapt design if necessary and repeat

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Antecedent: IEC 61400-1 • The offshore wind turbine design standard started with conventional, land-based turbine design standard, IEC 61400-1 • IEC 61400-1 is still directly relevant, especially to the rotor nacelle assembly (RNA), and IEC-61400-3 is compatible with it to the extent possible

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What is an Offshore Wind Turbine? • A wind turbine shall be considered as an offshore wind turbine if the support structure is subject to hydrodynamic loading. • Note! 61400-3 is not sufficient for floating offshore wind turbines – But an IEC working group is presently developing guidelines for floating OWTs

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Parts of an Offshore Wind Turbine RNA

• Defined here • Includes: – Rotor/nacelle assembly (RNA) – Support structure • Tower • Substructure • Foundation

rotor-nacelle assembly

Tower tower

tower support structure

platform

water level

Substructure

sub-structure

sub-structure

pile

sea floor pile seabed

Foundation foundation

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Common Types of Fixed Bottom Support Structures • • • •

Monopiles Gravity base Jackets Others – Tripods – Suction bucket http://www.theengineer.co.uk/in-depth/the-bigstory/wind-energy-gets-serial/1012449.article

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Parts of Floating Offshore Wind Turbine RNA Tower

Floating substructure (hull) Mooring system (moorings and mooring lines 10

Scope of 6100-3 • Requirements (beyond IEC 61400-1) for: – Assessment of the external conditions at an offshore wind turbine site – Essential requirements to ensure the structural integrity of offshore wind turbines – Subsystems such as control and protection mechanisms, internal electrical systems and mechanical systems

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Design Methods • Requires the use of a structural dynamics model of PD to predict design load effects • Load effects to be determined for all relevant combinations of external conditions and design situations • Design of support structure to be based on sitespecific external conditions • Design of RNA to be based on IEC 61400-1 (to extent possible) 12

Structural Dynamics Model • Example: FAST – From US National Renewable Energy Laboratory – FAST is “an aeroelastic computer-aided engineering tool for horizontal axis wind turbines…[it] models the wind turbine as a combination of rigid and flexible bodies.” – FAST for offshore also includes modules for incorporating effect of waves

• Accompanying software: TurbSim (turbulent wind input), BModes (dynamic properties)

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External Conditions • Wind conditions • Marine conditions

Meteorological /oceanographic or “Metocean” Conditions

– Waves, sea currents, water level, sea ice, marine growth, seabed movement and scour

• Other environmental conditions • Soil properties at the site – Including time variation due to seabed movement, scour and other elements of seabed instability 14

Occurrences of External Conditions • Normal – Recurrent structural loading conditions

• Extreme – Rare external design conditions of greater than normal magnitude or effect

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Wind Turbine Classes • Follows that of IEC 61400-1 – Based on: wind speed and turbulence parameters (I, II, II) and special conditions (S)

– Design lifetime: at least 20 years 16

Wind Conditions • Normal: – More often than once per year

• Extreme: – Recurrence of once per year or per 50 years

• For RNA, use wind conditions as in 61400-1, with some differences: – Wind shear, inclination of mean flow

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Marine Conditions • Assumed to primarily affect support structure • Conditions include at least: – Waves, sea currents, water level, sea ice, marine growth, scour and seabed movement

• Normal: – More often than once per year

• Extreme: – Recurrence of once per year or per 50 years 18

Waves • Stochastic wave model assumed • Design sea state: – – – –

Wave spectrum, S (f) (m2/Hz) Significant wave height, Hs (m) Peak spectral period, Tp (s) Mean wave direction, wm (deg)

• Normal, severe, extreme conditions – Breaking waves

• Wind/wave correlations

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Sea Currents • Sub-surface currents generated by tides, storm surge, atmospheric pressure variations, etc. • Wind generated, near surface currents • Near shore, breaking wave induced surf currents running parallel to the shore • Current models: – Normal, extreme

• See standard for details 20

Water Level D

• Reasonable range must be considered • Includes tidal range, storms

HSWL A HAT B

MSL LAT

C

CD LSWL

E HSWL HAT MSL LAT CD LSWL A B C D E

highest still water level highest astronomical tide mean sea level lowest astronomical tide chart datum (often equal to LAT) lowest still water level positive storm surge tidal range negative storm surge maximum crest elevation minimum trough elevation

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Sea Ice • Sea ice may seriously affect design of support structure

Cone breaks ice

– Special consideration, such as ice cones may be needed

• Detailed information given in standard http://www.nrc-cnrc.gc.ca/eng/projects/chc/model-test.html 22

Marine Growth • Marine growth may influence hydrodynamic loads, dynamic response, accessibility and corrosion rate of the structure • Classified as “hard” (e.g. Barnacles on ship mussels and barnacles) and “soft” (seaweeds http://www.dsdni.gov.uk/index/urcdgand kelps) 23 urban_regeneration/nomadic/dsdin_nomadic_gallery.htm

Seabed Movement and Scour • Seabed soil may move due to currents • Protection (“rip-rap”) may be needed around structure

http://sc.epd.gov.hk/gb/www.epd.gov.hk/eia/register/report/eiareport/eia_1772009/HTM24 L%20version/EIA%20Report/Section4.htm

Situations 1. As in 61400-1 – – – – – – – –

Power production Power production plus occurrence of fault Start up Normal shut down Emergency shut down Parked (standing still or idling) Parked and fault conditions Transport, assembly, maintenance and repair 25

For Each Situation… • • • • • • • •

Wind conditions Waves Wind and wave directionality Sea currents Water level Other conditions Type of analysis Partial safety factor 26

Types of Loads • As in 614000-1 – Ultimate (U) • Normal (N), abnormal (A), or transport and erection (T) • Consider: material strength, blade tip deflection and structural stability (e.g. Buckling)

– Fatigue (F) • Fatigue loads/fatigue strength

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Method of Analysis • Characteristics loads predicted by design tools (e.g. computer codes) • Method of partial safety factors • Expected "load function (effect)," multiplied by a safety factor, must be less than the "resistance function” • Design properties for materials from published data • Safety factors chosen according to established practice 28

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Ultimate Strength Analysis • Find characteristic load effect, Sk, from analysis • Find design load effect, Sd, using load safety factor Sd   f Sk

• Find characteristic material resistance, fk, from literature (or other source) • Find design material resistance, Rd, using material safety factor Rd  1 /  m Rk • Acceptable

Sd  Rd

Assessment of Metocean External Conditions • • • • • • • •

Wind speeds and directions Significant wave heights, wave periods and directions Correlation of wind and wave statistics Current speeds and directions Water levels Occurrence and properties of sea ice Occurrence of icing Other parameters: air, water temperatures, densities; water salinity; bathymetry, marine growth, etc 30

Assessment of External Electrical Conditions (examples) • • • • • • • • •

Normal voltage and range Normal frequency, range and rate of change Voltage imbalance Method of neutral grounding; Method of ground fault detection / protection; Annual number of network outages; Total lifetime duration of network outages; Auto-reclosing cycles; Required reactive compensation schedule; 31

Assessment of Soil Conditions • Geological survey of the site • Bathymetric survey of the sea floor including registration of boulders, sand waves or obstructions on the sea floor • Geophysical investigation • Geotechnical investigations consisting of insitu testing and laboratory tests

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Scope of IEC 61400-3: 2nd Edition • Consideration of comments from national committees during pre-publication review • Comments from others and from EU’s Upwind research program • Incorporating recent experience of the design of offshore wind turbines and their support structures

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General Areas of Interest • • • • • •

Load calculations and simulations External conditions Assessment of external conditions Support structure and foundation design The various annexes on design approaches Text referring to issues treated by IEC 61400-1

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Changes Likely… • • • • • • • •

General corrections Wave models Hurricanes/cyclones Wind shear as affected by waves Floating ice Boat (service vessel) impact Soil characterization Vortex induced vibrations 35

Issues for US • Wind/wave conditions (e.g. hurricanes) – 100 yr vs. 50 yr events

• Role of American Petroleum Institute (API), other US standards • Role of Bureau of Ocean Energy Management (BOEM) • Other standards referenced by 61400-3 – US vs. European or international – English units vs. metric (SI) units 36

Little or No Detail… • • • •

Foundation design (soil/structure interaction) Material properties Offshore data collection Environmental impact

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