Oceanic Energy Associate Professor Mazen Abualtayef Environmental Engineering Department Islamic University of Gaza, Palestine 1
Adapted from a presentation by Professor S.R. Lawrence Leeds School of Business, Environmental Studies University of Colorado, Boulder, CO, USA 2
Course Outline Renewable Solar Power Hydro Power Wind Energy Oceanic Energy Geothermal Biomass Sustainable Hydrogen & Fuel Cells Nuclear Fossil Fuel Innovation Exotic Technologies Integration Distributed Generation 3
Oceanic Energy Outline Overview Tidal Power Technologies Environmental Impacts Economics Future Promise Wave Power Technologies Environmental Impacts Economics Future Promise Assessment 4
Overview of Oceanic Energy 5
Sources of New Energy Boyle, Renewable Energy, Oxford University Press (2004) 6
Global Primary Energy Sources 2002 Boyle, Renewable Energy, Oxford University Press (2004) 7
Renewable Energy Use 2001 Boyle, Renewable Energy, Oxford University Press (2004) 8
Tidal Power 9
Tidal Motions Video Boyle, Renewable Energy, Oxford University Press (2004) 10
Tidal Forces Boyle, Renewable Energy, Oxford University Press (2004) 11
Natural Tidal Bottlenecks Video Boyle, Renewable Energy, Oxford University Press (2004) 12
Tidal Energy Technologies 1. Tidal Turbine Farms 2. Tidal Barrages (dams) 13
1. Tidal Turbine Farms MCT Swan turbines Deep water current turbines Oscillating turbines Polo turbines Land tides 14
Tidal Turbines (MCT Seagen) Video 750 kw 1.5 MW 15 20 m rotors 3 m pile diameter 10 20 RPM Deployed in multi-unit farms or arrays Like a wind farm, but Water 800x denser than air Smaller rotors More closely spaced MCT Seagen Pile MCT: Marine current turbines http://www.marineturbines.com/technical.htm 15
Tidal Turbines (Swanturbines) Direct drive to generator علب التروس No gearboxes Gravity base (concrete block) Versus a bored foundation Fixed pitch turbine blades Improved reliability But trades off efficiency Video http://www.darvill.clara.net/altenerg/tidal.htm 16
Deeper Water Current Turbine Video Boyle, Renewable Energy, Oxford University Press (2004) 17
Oscillating Tidal Turbine Oscillates up and down 150 kw prototype operational (2003) Plans for 3 5 MW prototypes http://www.engb.com Boyle, Renewable Energy, Oxford University Press (2004) 18
Polo Tidal Turbine Vertical turbine blades Rotates under a حلقة مربوطة tethered ring 50 m in diameter 20 m deep 600 tons Max power 12 MW Boyle, Renewable Energy, Oxford University Press (2004) 19
Power from Land Tides (!) http://www.geocities.com/newideasfromtelewise/tidalpowerplant.htm 20
Advantages of Tidal Turbines Low Visual Impact Mainly, if not totally submerged. Low Noise Pollution Sound levels transmitted are very low High Predictability Tides predicted years in advance, unlike wind High Power Density Much smaller turbines than wind turbines for the same power http://ee4.swan.ac.uk/egormeja/index.htm 21
Disadvantages of Tidal Turbines High maintenance costs High power distribution costs Somewhat limited upside capacity Intermittent power generation 22
2. Tidal Barrage Schemes Barrages Offshore lagoons Fences 23
Definitions Barrage An artificial dam to increase the depth of water for use in irrigation or navigation, or in this case, generating electricity. Flood Ebb The rise of the tide toward land (rising tide) The return of the tide to the sea (falling tide) 24
Potential Tidal Barrage Sites Only about 20 sites in the world have been identified as possible tidal barrage stations Boyle, Renewable Energy, Oxford University Press (2004) 25
Schematic of Tidal Barrage Boyle, Renewable Energy, Oxford University Press (2004) 26
Cross Section of a Tidal Barrage http://europa.eu.int/comm/energy_transport/atlas/htmlu/tidal.html 27
Tidal Barrage Bulb Turbine Boyle, Renewable Energy, Oxford University Press (2004) 28
Tidal Barrage Rim Generator Canada. An annual output of 50GWh Boyle, Renewable Energy, Oxford University Press (2004) 29
Tidal Barrage Tubular Turbine Boyle, Renewable Energy, Oxford University Press (2004) 30
Sihwa Lake Tidal Power Barrage Sihawa lake (South Korea) This 254 MW (10x25.4MW), $250 million project is the first world s largest Mean tidal range is 5.6m Video The basin area was reduced to around 30 km 2 31
La Rance Tidal Power Barrage Video Rance River estuary, Brittany (France) 2 nd Largest in world (1 st in Korea) Completed in 1966 24 10 MW bulb turbines (240 MW) 5.4 meter diameter Capacity factor of ~40% Maximum annual energy: 2.1 TWh Realized annual energy: 840 GWh Electric cost: 1.8 /kwh http://en.wikipedia.org/wiki/rance_tidal_power_station Boyle, Renewable Energy, Oxford University Press (2004) 32 Tester et al., Sustainable Energy, MIT Press, 2005
La Rance Tidal Power Barrage The system used consists of a dam 330m long and a 22km 2 basin with a tidal range of 8.5m, it incorporates a lock to allow passage for small craft Construction cost: 95m (1967) about 580m (2009) http://www.stacey.peak-media.co.uk/brittany2003/rance/rance.htm 33
La Rance River, Saint Malo http://upload.wikimedia.org/wikipedia/commons/e/eb/barrage_de_la_rance.jpg 34
La Rance Barrage Schematic Boyle, Renewable Energy, Oxford University Press (2004) 35
Cross Section of La Rance Barrage river sea Tide going out http://en.wikipedia.org/wiki/file:coupebarrage_rance.jpg 36
La Rance Turbine Exhibit 37
Tidal Barrage Energy Calculations E E R = range (height) of tide (in m) A = area of tidal pool (in km 2 ) m = mass of water g = 9.81 m/s 2 = gravitational constant = 1025 kg/m 3 = density of seawater 0.40 = capacity factor (20-40%) mgr / 2 1397R 2 ( AR) gr / A 2 1 gar 2 kwh per tidal cycle Assuming 706 tidal cycles per year (12 hrs 24 min per cycle) 6 2 E yr 0.99710 R A 2 Tester et al., Sustainable Energy, MIT Press, 2005 38
La Rance Barrage Example = 40% R = 8.5 m A = 22 km 2 6 E 0.99710 R E E yr yr yr 0.99710 633 6 GWh/yr 2 A (0.40)(8.5 2 )(22) Tester et al., Sustainable Energy, MIT Press, 2005 39
Proposed Severn Barrage (1989) Video http://en.wikipedia.org/w/index.php?title=file:severn_barrages_map.svg&page=1 40
Proposed Severn Barrage (1989) Never constructed, but instructive Boyle, Renewable Energy, Oxford University Press (2004) 41
Proposed Severn Barrage (1989) Severn River estuary Border between Wales and England 216 40 MW turbine generators (9.0m dia) 8,640 MW total capacity 17 TWh average energy output Ebb generation with flow pumping 16 km total barrage length $15 billion estimated cost (1989) 42
Severn Barrage Layout Boyle, Renewable Energy, Oxford University Press (2004) 43
Severn Barrage Proposal Effect on Tide Levels Boyle, Renewable Energy, Oxford University Press (2004) 44
Severn Barrage Proposal Power Generation over Time Boyle, Renewable Energy, Oxford University Press (2004) 45
Severn Barrage Proposal Capital Costs ~$15 billion (1988 costs) Boyle, Tester Renewable et al., Sustainable Energy, Energy, Oxford MIT University Press, Press 2005 (2004) 46
Severn Barrage Proposal Energy Costs ~10 /kwh (1989 costs) Boyle, Renewable Energy, Oxford University Press (2004) 47
Severn Barrage Proposal Capital Costs versus Energy Costs 1p 2 Boyle, Renewable Energy, Oxford University Press (2004) 48
Offshore Tidal Lagoon Read this article Friends of the Earth Briefing: Tidal Lagoon vs. Barrage http://tidalelectric.com/news-friends.shtml Boyle, Renewable Energy, Oxford University Press (2004) 49
Tidal Fence Array of vertical axis tidal turbines No effect on tide levels Less environmental impact than a barrage 1000 MW peak (600 MW average) fences soon Boyle, Renewable Energy, Oxford University Press (2004) 50
Promising Tidal Energy Sites Country Location TWh/yr GW Canada Fundy Bay 17 4.3 Cumberland 4 1.1 USA Alaska 6.5 2.3 Passamaquody 2.1 1 Argentina San Jose Gulf 9.5 5 Russia Orkhotsk Sea 125 44 India Camby 15 7.6 Kutch 1.6 0.6 Korea 10 Australia 5.7 1.9 http://europa.eu.int/comm/energy_transport/atlas/htmlu/tidalsites.html 51
Tidal Barrage Environmental Factors Changes in estuary ecosystems Less variation in tidal range Fewer mud flats Less turbidity clearer water More light, more life Accumulation of silt Concentration of pollution in silt Visual clutter 52
Advantages of Tidal Barrages High predictability Tides predicted years in advance, unlike wind Similar to low-head dams Known technology Protection against floods Benefits for transportation (bridge) Some environmental benefits http://ee4.swan.ac.uk/egormeja/index.htm 53
Disadvantages of Tidal Turbines High capital costs Few attractive tidal power sites worldwide Intermittent power generation Silt accumulation behind barrage Accumulation of pollutants in mud Changes to estuary ecosystem 54
Wave Energy 55
Wave Structure Boyle, Renewable Energy, Oxford University Press (2004) 56
Wave Frequency and Amplitude Boyle, Renewable Energy, Oxford University Press (2004) 57
Wave Patterns over Time Boyle, Renewable Energy, Oxford University Press (2004) 58
Wave Power Calculations H s = Significant wave height (m) T e = average wave period (sec) P = Power in kw per meter of wave crest length P Example: H s = 3m, T e = 10sec 2 H s T e 2 P 2 2 H ste 3 10 45 2 2 kw m Gaza: H s = 0.75m, T e = 7sec P 2 H T 2 0.75 2 7 2 s e 2. 0 kw m 59
Global Wave Energy Averages Average wave energy (est.) in kw/m (kw per meter of wave length) http://www.wavedragon.net/technology/wave-energy.htm 60
Wave Energy Potential Potential of 1,500 7,500 TWh/year 10 and 50% of the world s yearly electricity demand IEA (International Energy Agency) 200,000 MW installed wave and tidal energy power forecast by 2050 Power production of 6 TWh/y Load factor of 0.35 DTI and Carbon Trust (UK) Independent of the different estimates the potential for a pollution free energy generation is enormous. http://www.wavedragon.net/technology/wave-energy.htm 61
Wave Energy Technologies 62
Wave Concentration Effects Boyle, Renewable Energy, Oxford University Press (2004) 63
Tapered Channel (Tapchan) http://www.eia.doe.gov/kids/energyfacts/sources/renewable/ocean.html 64
Oscillating Water Column Video http://www.oceansatlas.com/unatlas/uses/energyresources/background/wave/w2.html 65
Oscillating Column Cross-Section Boyle, Renewable Energy, Oxford University Press (2004) 66
LIMPET Oscillating Water Column Completed 2000 Scottish Isles Two counter-rotating Wells turbines Two generators 500 kw max power Boyle, Renewable Energy, Oxford University Press (2004) 67
Mighty Whale Design Japan It weights 4,400 tons and measures 50m long It has three air chambers that convert wave energy into pneumatic energy Wave action causes the internal water level in each chamber to rise and fall, forcing a bidirectional flow over an air-turbine to generate energy http://www.jamstec.go.jp/jamstec/mtd/whale/ 68
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Turbines for Wave Energy Turbine used in Mighty Whale Boyle, Renewable Energy, Oxford University Press (2004) 70 http://www.jamstec.go.jp/jamstec/mtd/whale/
Ocean Wave Conversion System http://www.sara.com/energy/wec.html 71
Wave Dragon Video Wave Dragon Copenhagen, Denmark http://www.wavedragon.net http://www.wavedragon.net/technology/wave-energy.htm 72
Wave Dragon Energy Output in a 24kW/m wave climate = 12 GWh/year in a 36kW/m wave climate = 20 GWh/year in a 48kW/m wave climate = 35 GWh/year in a 60kW/m wave climate = 43 GWh/year in a 72kW/m wave climate = 52 GWh/year. http://www.wavedragon.net/technology/wave-energy.htm 73
Declining Wave Energy Costs Boyle, Renewable Energy, Oxford University Press (2004) 74
Wave Energy Power Distribution Boyle, Renewable Energy, Oxford University Press (2004) 75
Wave Energy Supply vs. Electric Demand Boyle, Renewable Energy, Oxford University Press (2004) 76
Wave Energy Environmental Impacts 77
Wave Energy Environmental Impact Little chemical pollution Little visual impact Some hazard to shipping No problem for migrating fish, marine life Extract small fraction of overall wave energy Little impact on coastlines Release little CO 2, SO 2, and NO x 11g, 0.03g, and 0.05g / kwh respectively Boyle, Renewable Energy, Oxford University Press (2004) 78
Wave Energy Summary 79
Wave Power Advantages Onshore wave energy systems can be incorporated into harbor walls and coastal protection Reduce/share system costs Providing dual use Create calm sea space behind wave energy systems Development of mariculture Other commercial and recreational uses; Long-term operational life time of plant Non-polluting and inexhaustible supply of energy http://www.oceansatlas.com/unatlas/uses/energyresources/background/wave/w2.html 80
Wave Power Disadvantages High capital costs for initial construction High maintenance costs Wave energy is an intermittent resource Requires favorable wave climate. Investment of power transmission cables to shore Degradation of scenic ocean front views Interference with other uses of coastal and offshore areas navigation, fishing, and recreation if not properly sited Reduced wave heights may affect beach processes in the littoral zone http://www.oceansatlas.com/unatlas/uses/energyresources/background/wave/w2.html 81
Wave Energy Summary Potential as significant power supply (1 TW) Intermittence problems mitigated by integration with general energy supply system Many different alternative designs Complimentary to other renewable and conventional energy technologies http://www.oceansatlas.com/unatlas/uses/energyresources/background/wave/w2.html 82
Future Promise 83
World Oceanic Energy Potentials (GW) Source Tides Waves Currents OTEC 1 Salinity World electric 2 World hydro Potential (est) 2,500 GW 2,700 3 5,000 200,000 1,000,000 4,000 Practical (est) 20 GW 500 50 40 NPA 4 2,800 550 1 Temperature gradients 2 As of 1998 3 Along coastlines 4 Not presently available Tester et al., Sustainable Energy, MIT Press, 2005 84
Wave Energy in Gaza 85
Wave Energy in Gaza Wave data were obtained from Idku station in front of Alexandria s (Egypt). The wave conversion design for Gaza is based upon Eco Wave Power (EWP) company.
Wave Energy in Gaza
Power, kw Wave Energy in Gaza The hourly power generation from Eco Wave Power generator for Gaza wave conditions. 35 30 25 20 15 10 5 0 0 30 60 90 120 150 180 210 240 270 300 330 360 Period, days
Power, KWh Monthly Percentile Wave Energy in Gaza 2000 1800 1600 1400 1200 1000 800 600 400 200 0 Monthly Power, kwh Monthly Percentile Jan. Feb. Mar. Apr. May Jun. Jul. Aug.Sep. Oct. Nov.Dec. Monthly energy and its percentile 30% 25% 20% 15% 10% 5% 0%
Wave Energy in Gaza EWP installations on Gaza shoreline
Wave Energy in Gaza Cost Concrete base structure US$3,000 EWP 10,000 Transmission line 100,000 Production cost 0.30$/kWh
Next: Geothermal Energy http://www.c-a-b.org.uk/projects/tech1.jpg 92