OCEN 201 Introduction to Ocean & Coastal Engineering Introduction Jun Zhang [email protected].
OCEN 201 Introduction to Ocean & Coastal Engineering
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Transcript of OCEN 201 Introduction to Ocean & Coastal Engineering
OCEN 201Introduction to Ocean &
Coastal Engineering
Renewable Marine Energy (2)Jun Zhang
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Cost of Ocean EnergyCost of Ocean Energy
<Carbon Trust Report, 2006>
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Status of Ocean Energy TechnologiesStatus of Ocean Energy Technologies
Demonstration scale
Cost estimate from
20-75cents/kWh for WEC and 5-
30cents/kWh for TEC. More realistic
estimation may be at its high end
More Research is needed not more
hype
Current Status Design and Maintenance:
1) Robustness and efficiency of
energy generator
2) Corrosion and survivability
3) Economics
Environmental impacts: ecology
(e.g. Shiwa tide power plant)
Transmission: Integration into the
grid (intermittent energy generation
and long distance)
Storage of Energy
Issues
Water Program Restarted in FY 2008
FY07 FY08 FY09 FY10 Recovery Act
$0M $10M $40M $40M - $60M? $32M
Appropriations address both conventional hydro (CH) and marine and hydrokinetic technologies (MHK)
Recovery Act focused on conventional hydropower for short-term impacts
Technology Definitions
Marine and Hydrokinetic (MHK): energy from:• Waves• Water currents (tides, rivers, ocean currents, man-made channels)• Ocean thermal energy (OTEC)
Program Areas and FundingProgram Areas and Funding
Ocean Energy Development in USOcean Energy Development in US
(Courtesy of Mr. Hoyt Battey, US (Courtesy of Mr. Hoyt Battey, US DOE)DOE)
Technology Development: Address technical barriers to device design, development, testing, and integration Market Acceleration: Address non-technical barriers to development, siting, and deployment
Marine & Hydrokinetic TD, $15.55,
41%
Marine & Hydrokinetic MA, $10.44,
28%
Conventional Hydro TD, $4.10, 11%
Program support, $2.66,
7%
Conventional Hydro MA, $4.86, 13%FY2009 Water Budget $37.6M
FY09 Water Budget AllocationFY09 Water Budget Allocation
Development in US
• System Deployment and Testing
– Facilitate the deployment and testing of full scale MHK prototypes and components
– Support the development of integrated test centers
– Generate data on performance, reliability and impacts
• Cost Reduction and System Performance/Reliability
– Support design and development of scale systems and components
– Develop design and testing protocol, support developers who follow it
• Understand Environmental Effects
– Collect/disseminate data on environmental impacts to reduce deployment costs and environmental effect
• Resource Assessments
– Determine the available, extractable, and cost-effective water resources in the US
• Develop Evaluation and Performance Standards
– Characterize, evaluate and compare the wide variety of MHK technologies; continue IEC/IEA standards development
MHK Program PrioritiesMHK Program PrioritiesDevelopment in US
FY2008 MHK ProjectsFY2008 MHK Projects Technology Development Projects
2008 Funding Opportunity Announcement, Topic Area 1: Advanced Water Power Renewable Energy In-Water Testing and Development Projects
– WaveConnect Wave Energy In-Water Testing and Development Project (Pacific Gas & Electric Company)
– Development and Demonstration of an Oscillating Water Column (OWC) Power System (Concepts ETI, Inc).
– Improved Structure and Fabrication of Large, High-Power Kinetic Hydropower Systems and Rotors (Verdant Power Inc).
– Puget Sound Tidal Energy In-Water Testing and Development Project (Snohomish County PUD)
– Advanced Composite OTEC Cold Water Pipe Project (Lockheed Martin)
– Northwest National Marine Renewable Energy Center (OSU/UW)
– National Marine Renewable Energy Center in Hawaii (U of Hawaii)
Development in US
FY2008 MHK ProjectsFY2008 MHK Projects Market Acceleration Projects
2008 Funding Opportunity Announcement, Topic Area 2: Marine and Hydrokinetic Renewable Energy Market Acceleration Projects
– Guidelines for Developers and a Framework for Siting Marine and Hydrokinetic Energy Projects (Pacific Energy Ventures, re vision, PCCI)
– Wave Resource Assessment (Electric Power Research Institute -- EPRI)
– Tidal Resource Assessments (Georgia Tech Research Corporation)
– International Standards Development for Marine and Hydrokinetic Renewable Energy (Science Applications International Corporation)
Report to Congress: Potential Environmental Effects of Marine and Hydrokinetic Energy Technologies
International Energy Agency, Ocean Energy Systems (IEA-OES) Annex IV, Assessment of Environmental Effects and Monitoring Efforts for Ocean Wave, Tidal, and Current Energy Systems
Jobs and Economic Development Index (JEDI) modeling
Development in US
FY2009 Funding OpportunitiesFY2009 Funding Opportunities
Industry-led Projects
Topic Area 1: MHK Energy Conversion Device or Component Design and Development
Topic Area 2: MHK Site-specific Environmental Studies and Information
Topic Area 3: Advanced Water Power Market Acceleration Projects/Analysis and Assessments
Laboratory-led Projects
Topic Areas 1 & 3: Supporting Research and Testing (MHK, CH)
– Computational tools/models to predict device/array behavior; advanced materials, device testing and validation codes
Topic Areas 2 & 4: Environmental Assessment and Mitigation Methods
– Tools and studies to predict, evaluate, and minimize environmental impacts
Development in US
Barriers and Actions to OvercomeBarriers and Actions to Overcome
Despite the increased interest and research and development activities, ocean energy technologies remain high risk and at an early stage of development.
Several technical and non-technical barriers are currently restricting development of ocean energy technologies.
–Lack of sufficient demonstration of prototypes in the marine environment
–Cost of connecting ocean energy systems to electricity networks impacts on demonstration projects
–Lack of understanding on environmental impacts
–Absence of internationally recognized standards for development, testing and measurement
Ocean energy technology could contribute to meeting cost-effective, sustainable and secure energy demands in the long term provided governments and device developers act to overcome the barriers identified and reduce the high cost and high risk associated with thesetechnologies.
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Wave Energy Resource DistributionWave Energy Resource Distribution
2,000TWh/year of energy, the equivalent of 10% of the world electricity consumption, could be harvested from the world’s oceans (CRES, 2006)2,000TWh/year of energy, the equivalent of 10% of the world electricity consumption, could be harvested from the world’s oceans (CRES, 2006)
Resources
Estimate of Wave Energy ResourceEstimate of Wave Energy Resource
• Wave Energy Density
Average wave energy per unit area it has unit (work/per unit area)
•Wave Energy Flux through unit length at ocean surface
•Wave Energy Resource (Energy Flux * Time per unit length) Time of the wave at this height (per year) and per length of
the wave field normal the wave direction, kw*hr/m/year
2 21 1
2 8E gA gH
2 2 2N-m/m (J/m ),or lb-ft/ft
(Jole/s/m, W/m)
Wave Group Velocity
g
g
F EC
C
Example of Estimating Wave Energy ResourceExample of Estimating Wave Energy Resource
1 1
2 2
3 3
4
Near a coast area, the year-long wave characteristics are described below
Jan - Mar H = 5 m, T = 10s
Apr - Jun H = 4 m, T = 8s
July - Sept H = 3 m, T = 6s
Oct - Dec H = 6 4
2 21 1
1
1 1
m, T = 12s
What is Wave energy resource per unit length at this area?
1Jan - Mar H 31.56 /
8Assuming deep water C 7.81 /
Energy Flux per unit length = *C 246.5 /
In three m
g
g
E g kN m m
m s
E kw m
5
onths (, the total energy flux per unit length
246.5 / *90 (days)*24 (hr) 5.324*10 /kw m kwhr m
Example of Estimating Wave Energy ResourceExample of Estimating Wave Energy Resource
1 1
2 2
3 3
4
Near a coast area, the year-long wave characteristics are described below
Jan - Mar H = 5 m, T = 10s
Apr - Jun H = 4 m, T = 8s
July - Sept H = 3 m, T = 6s
Oct - Dec H = 6 4
22 2
2 2
m, T = 12s
What is Wave energy resource per unit length at this area?
Apr-Jun 20.2 / , in deep water C 6.25 /
Energy Flux per unit length = *C 126.3 /
126.3 / *91 (da
g
g
E kN m m m s
E kw m
kw m
5
23 3
3 3
5
ys)*24 (hr) 2.757*10 /
July-Sept 11.36 / , in deep water C 4.68 /
Energy Flux per unit length = *C 53.21 /
53.21 / *92 (days)*24 (hr) 1.175*10 /
g
g
kwhr m
E kN m m m s
E kw m
kw m kwhr m
Example of Estimating Wave Energy ResourceExample of Estimating Wave Energy Resource
24 4
4 4
5
Oct-Dec 45.45 / , in deep water C 9.37 /
Energy Flux per unit length = *C 425.8 /
425.8 / *92 (days)*24 (hr) 9.402*10 /
Hence, each year, Energy Flux per unit len
g
g
E kN m m m s
E kw m
kw m kwhr m
5
5 5 5 6
6
gth = 5.324*10
2.757*10 1.175*10 9.402*10 1.866*10 / per year
Average Energy Flux over unit length
1.866*10 / / (365*24 ) 213.0 /
If the wave field is 10 km wide, then the wave energy a
kwhr m
kwhr m hr kw m
10
t this area
per year is equal to 1.866*10 per year.kwhr
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Storage (and Transport) of Renewable EnergyStorage (and Transport) of Renewable Energy
Because renewable energy such as wind, wave and current energy, in general is not steady, the issue of storage of their energy become an important issue. The benefits of storage are significant, especially in integrating distributed power generation. Storage protects against mistakes in forecasting, removes barriers in connecting renewable sources to a variety of grids, shifts demand peaks by storing off-peak energy to sell back to the grid during peak times, provides frequency regulation and deters expensive grid upgrades.
Storage of Renewable EnergyStorage of Renewable Energy
The followings are a few ideas1.Large Battery System (High Performance Hydroxyl Conductive Membrane For Advanced Rechargeable Alkaline Batteries, High Energy, Low Temperature Rechargeable Battery for Load Leveling Application, & Nanostructured Cathode for Magnesium Ion batteries)
2.Compress Air (For example, pumping pressured air into a massive case for storage) http://www.physorg.com/news188048601.html http://www.youtube.com/watch?v=dGd7PIC09AM3. Grid-scale Storage Project (pumping hydropower http://www.youtube.com/watch?v=iFdVX0NIPDE )
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Storage of Renewable EnergyStorage of Renewable Energy
4. Superconducting Magnetic Energy Storage http://www.youtube.com/watch?v=QU05d43dw6g
5. Combination the renewable energy device with other large energy consumption device (not only for storage but also saving transport cost)
1. Fuel Cell (use spare energy to produce Hydrogen & Oxygen from water)2.Desalination of sea water using renewable energy http://www.youtube.com/watch?v=bIrXKyWF8Nw3. Storage thermal energy (ice water, hot water and melting salts)4. Liquefy natural gas or industries consuming heavy power
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The successful commercial deployment of all kinds of RE (renewable energy) devices depends on the cost.
The following is an example of the cost of a fixed offshore wind turbine.
The figure shows the breakdown of total system cost
Economic Assessment of RE Devices
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Items in the total cost
1)Support Structure (24%)2)Wind Turbine (33%)3)Grid Connection (Cable) (15%)4)O&M (operation and Maintenance) (23%)5)Others (5%)
Economic Assessment of RE Devices
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Storage Examples
http://www.youtube.com/watch?v=RlfDXAuhjwU
http://www.youtube.com/watch?v=JgmbPf1Jd-8
http://www.youtube.com/watch?v=hCywnjG9tes&feature=related
http://www.youtube.com/watch?v=Ra5WTItC0_4