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Published byReynold Carter Modified over 9 years ago
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What do you think the power from a wind turbine looks like over the course of a month?
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What do you think the power from a solar panel looks like over the course of a day?
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There is a need to store energy if your supply isn’t constant
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Grid Energy Storage What is the maximum power capacity needed here?
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Grid Energy Storage What is unrealistic about this example?
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Total Grid Energy Storage: >250 GW Most is pumped hydro
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Pumped hydro storage: (Example --- Luddington, Michigan)
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New Taum Sauk Reservoir
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Pumped hydro storage: ~ 70-85% efficient First used in 1890’s in Italy and Switzerland ~22 GW of power storage in the US Largest is in Bath County, VA 3 GW
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Batteries: 50 to >90% efficient 1917 English gasoline engine with 16 batteries that could supply 4.5 amps at 32 V for 7.5 hours
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Batteries:
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Lead-Acid Battery
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Traditional Batteries: Expensive, high maintenance, and limited lifetimes, but can supply large power for short amounts of time Many new compositions are being explored (lithium iron phosphate, sodium-sulfur, vanadium, etc.) A system in Puerto Rico has a capacity of 20 MW for 15 minutes (5 MWhr) A system in a remote area of Fairbanks (Alaska) provides 27 MW for 15 minutes (6.75 MWhr)
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Experimental: Liquid Metal Batteries
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Initially Magnesium/Anitmony; now Lead/Antimony Operates at 350-430°C (cooler than previous alloys) Energy storage efficiency of 70% (down to 60% after 10 yrs) Cost is $500/kWhr (needs to get down to ~$100/kWhr)
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Experimental: Liquid Metal Batteries Liquid is mobile (so more efficient)
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Many computer systems are hooked to UPCs (uninterruptible power supplies)
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Compressed Air Energy Storage (CAES): Usually <60% efficiency McIntosh, Alabama 27 efficiency http://www.powersouth.com/mcintosh_power_plant/compre ssed_air_energy
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Where is energy lost?
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Compressed Air: New technology involving adiabatic storage and retrieve (heat is retained with high insulation) German ADELE plant in development (2015?) Will operate at ~70% efficiency But then need a way to store heat (as hot oil, up to 300°C, or as molten salt, up to 600°C)
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Compressed Air Energy Storage: Good geologic locations are salt layers and aquifers Why?
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Compressed Air Energy Storage: Good geologic locations are salt layers and aquifers Why? How could you make a salt cavern?
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Flywheels: Small, but fast retrieval of power Beacon Power has a 20 MW flywheel energy storage plant in Stephentown, NY
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Flywheels: Beacon Power has a 20 MW flywheel energy storage plant in Stephentown, NY What happens if it gets too big?
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Size vs. Retrieval Time:
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Total Grid Energy Storage: >250 GW
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Hydrogen Storage: Energy can be converted into hydrogen by: 1)Steam reformation of hydrocarbons 2)Water electrolysis
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Hydrogen Storage: Energy can be converted into hydrogen by: 1)Steam reformation of hydrocarbons (~65%-75% efficient) Steam reacts with hydrocarbons (usually methane) to release hydrogen gas Ex/ 2-step process starting with methane: A)CH 4 + H 2 O CO + 3H 2 (“methanation”) B)CO + H 2 O CO 2 + 3H 2 (“water-gas shift”)
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Hydrogen Storage: Energy can be converted into hydrogen by: 2) Water electrolysis (~30-45% efficient): The decomposition of water (H 2 O) into oxygen gas (O 2 ) and hydrogen gas (H 2 ) by passing an electric current through the water.
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Water electrolysis
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Hydrogen Fuel Cells: The released hydrogen can then be compressed, transported and used for hydrogen fuel cell technology
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Hydrogen Fuel Cells: In a hydrogen fuel cell, the reverse of hydrolysis happens The hydrogen and oxygen combine to make water, driving an electric current
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Hydrogen Fuel Cell Cars: Target availability = 2015 Honda Clarity can now be leased in California for $600/mo Production costs have dropped from $1M/car to about $120K/car
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Electric Cars: Thomas Edison and a Detroit electric car, 1913
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Electric Cars: Nissan Leaf – best selling electric car 55,000 sold by March, 2013
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Electric Cars: Tesla (Roadster - $110,00) and Model S Sedan ($57,000). Soon, the Bluestar (~$30,000) http://www.youtube.com/watch?v=oLiLGTqzfBU
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98% of Evs use Lithium-ion batteries Expensive, but high energy density
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Tesla ESS (energy storage system) uses 6831 lithium cells
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87% of Hybrid Cars use NiMH (Nickel-Metal Hydride) Half the energy density and cost The Prius uses a battery back of 168 NiMH cells that are 1.2 V each
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Salar de Uyuni (Andes Mountains, Bolivia), salt polygons:
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Salar de Uyuni, mirror-like quality
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Salar de Uyuni: Harvesting Salt
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Salar de Uyuni, brine beneath salt crust
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Lithium plant at Salar de Uyuni
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Lithium plant at Atacama Salt Flats (Chile)
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Hydrogen Fuel Cell vs. Electric Cars: EVs more efficient
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It is still not clear which technology for cars will dominate: Hydrogen Fuel Cells vs. Electric Cars (Each has plenty of pros and cons)
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