Tidal Hydrokinetic Energy

Transcription

1 Tidal Hydrokinetic Energy Brian Polagye Research Assistant Professor University of Washington September 23, 2010

2 Tidal Energy Challenges Northwest National Marine Renewable Energy Center

3 Tidal Energy Barrage Hydrokinetic Comparable to hydroelectric Very high cost and environmental footprint Comparable to wind Potentially lower cost and environmental footprint

4 Tidal Energy Resource Idle Operating

5 Other Forms of Marine Energy Wave Ocean Thermal Ocean Current Offshore Wind

6 Tidal Hydrokinetic Devices

7 Typical Sites and Devices Gearbox GeneratorGenerator Direct Drive Generator Pile Chain Anchor Rotor 5 20 m rpm Drive Train Gravity Base Tension Leg 2 4 m/s m Foundation

8 Worldwide Demonstrations CleanCurrent FORCE OpenHydro CleanCurrent MCT EMEC OpenHydro Tidal Generation Ltd. Voith Hydro Atlantis Hammerfest Strøm Pulse Tidal MCT Voith Hydro ORPC Verdant Power

9 Tidal Energy in Puget Sound Race Rocks Demonstration turbine Admiralty Inlet Pilot project Marrowstone Island Demonstration array

10 Motivation Local ldi Drivers I 937: 15% renewable energy by 2020 Limited transmission capacity for new wind energy US Navy target of 50% alternative energy by 2020 National and Global Drivers Predictable resource No CO 2 emissions No visual impact Close to load

11 Tidal Energy Challenges Northwest National Marine Renewable Energy Center

12 Tidal Energy Challenges Societal Concerns Environmental Effects Technical Readiness Economic Viability

13 Technical Challenges Deep water deployments Most of the resource is in water deeper than 20m Most wind deployments in water less than 20m Biofouling and corrosion Long term reliability Moving parts in the marine environment 20+ year service life 2+ year service interval

14 Survivability and Reliability Hydrodynamic performance Reduced power output Orme, Masters, Griffiths (2001) Structural performance Increased ceasedloads Metal corrosion Composite aging 316 Stainless Crevice Corrosion

15 Shallow Water Biofouling Example Clean Current turbine 15m depth 6 months deployment Before After

16 Cost of Energy Marine renewables more expensive than terrestrial alternatives Wave energy: $/MWh Tidal energy: $/MWh Ocean thermal energy: 500+ $/MWh Several contributors to higher cost Capital cost for extended marine deployments Operations and maintenance in marine environment Long and uncertain permitting requirements Intensive environmental monitoring requirements

17 Potential Environmental Effects Effects on aquatic species Avoidance Aggregation Strike Entanglement Far field environment Circulationl Nearshore environment Water quality Near field environment Noise (device, vessels) Wake (sediment transport) Hard substrate (artificial reef) EMF Toxicity (coatings, lubricants)

18 Barriers to Resolving Uncertainty Chicken and Egg Problem Need devices in the water to reduce large uncertainties Cannot receive permit to operate with large uncertainties Technology readiness of monitoring You can only analyze what you can measure Existing tools focused on stock assessments, not individuals Significant overlap with fundamental research needs High natural variability in relation to project scale

19 Mitigation Trade offs Environment Further from shore less sensitive Temporary shut down Environment Slackmoorings are quiet Taut moorings pose a low entanglement risk vs. vs. Economics Higher cost of energy Higher cost of energy, financing Environment Slack moorings pose a high entanglement risk Taut moorings strum loudly

20 Existing Uses Tribes Usual and Accustomed Treaty Rights Fishing and crabbing Commercial Users Fishing and crabbing Shipping Recreational Users Fishing and crabbing Diving Military

21 Tidal Energy Challenges Northwest National Marine Renewable Energy Center

22 Northwest National Marine Renewable Energy Center () UW Tidal Energy OSU Wave Energy Resource and Site Assessment Device and Array Optimization 8 Faculty members involved 10 Graduate student tresearchers supported td Testing Environmental Materials Facilities Effects Suitability

23 Resource and Site Assessment Shipboard Survey R/V Jack Robertson Seabed Instrumentation Measurement Tripod Land Observation AIS Ship Tracks

24 Seabed Characterization

25 Sea Spider Instrumentation Tripod Acoustic release (redundant recovery) ADCP (Acoustic Doppler Current Profiler) Hydrophone (background noise) Programmed for 3 month deployments CTDO (conductivity, temperature, depth, dissolved oxygen partnership with WA Dept of Ecology) Fish Tag Recorder (partnership with NMFS) T Pod/C Pod (porpoise clicks) Lead Weight (650 lbs)

26 Deployment Time Lapse

27 Rough Deployment

28 IR Detection of Marine Mammals Lime Kiln State Park July 5, 2010 at 0350 HD Webcam IR Camera

29 Turbine Noise Two Open Hd Hydro Turbines Northern Admiralty Inlet 1 km 2 km 3 km

30 Biofouling Prevention Biocides: Anti fouling Effective Toxic Low friction: Foul release Cost Long term effectiveness

31 Deep Water Screening Experiment

32 Large Annual Variability

33 Composite Aging Water absorption, leading to loss of strength In situ screening tests 9 18 months exposure Four composite material systems

34 Test Platform Goals Provide a fully instrumented and permitted platform for testing tidal energy conversion devices. Provide objective performance evaluations of tidal energy devices in realistic conditions. Provide comprehensive environmental monitoring to study potential ti environmental effects of tidal energy conversion. Accelerate commercialization by reducing development cost and uncertainty.

35 Site Characteristics Marrowstone Island Whidbey Island Proposed Site Boundary Water Depth (m) Realistic hydrokinetic resource Peak currents ~ 25m/s 2.5 Supports range of devices Depth varies from 20m to 50m over 1 km distance Full range of aquatic species present Fish Marine mammals Diving seabirds

36 Infrastructure Concept Monitoring Node Test Berth Berth B (30m) Berth A (20 m) Berth C (50 m) Water Depth (m) Grid connection Environmental and performance monitoring nodes Plug and play foundation Power and data sockets

37 Leveraging Infrastructure Build on NSF Ocean Observing Initiative Fiber optic to Ethernet: real time observations Robust nodal dlarchitecture, "daisy chain interconnections Simple retrievals for service/upgrade (independent from tidal device maintenance) Potential to integrate proven technologies next to beta UW APL Regional Scale Nodes project

38 National Tidal Energy Platform Design test berths Commission berths Platform Infrastructure Engagement Cable routing Design junction boxes Install cables Install junction boxes Design shore facilities Build shore facilities Monitoring Portable monitoring Engagement Node design Cabled monitoring Permitting Engagement Adaptive management framework Operational permits Industry Engagement RFP for maritime services RFP to test

39 Conclusions Tidal energy is not a silver bullet, but will be regionally important. Significant challenges must be overcome before commercial development. Opportunity for universities i i to solve these problems and train first generation of marine energy engineers.

40 Thank You! To learn more about tidal energy, visit: