Energy storage: Difference between revisions
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{{Image|Fuel Energy Density.png|right|350px|Fig.1 Comparison of specific energy (energy per mass or gravimetric density) and energy density (energy per volume or volumetric density) for several fuels.<ref>https://www.energy.gov/eere/fuelcells/hydrogen-storage</ref>}} | {{Image|Fuel Energy Density.png|right|350px|Fig.1 Comparison of specific energy (energy per mass or gravimetric density) and energy density (energy per volume or volumetric density) for several fuels.<ref>https://www.energy.gov/eere/fuelcells/hydrogen-storage</ref>}} | ||
{{Image|Fuel Energy Density WNA.png|right|350px|Add image caption here.}} | {{Image|Fuel Energy Density WNA.png|right|350px|Add image caption here.}} | ||
This article is a brief | {{Image|Sulfur-Iodine Process.png|right|350px|Add image caption here.}} | ||
This article is a brief review of the technologies relevant to the large-scale '''energy storage''' <ref>See [https://world-nuclear.org/information-library/current-and-future-generation/electricity-and-energy-storage.aspx Electricity and Energy Storage] for a more complete review.</ref> needed for wind and solar and other intermittent energy sources. | |||
The most important point of comparison is cost per kilowatt hour (kWh) of storage, including the cost of ancillary equipment like power inverters or heat storage tanks. Other costs, like battery replacement can be included by assuming a reasonable time over which these capital costs are depreciated.<ref>For example, a $100M system providing 1000 megawatt hours (MWh) total storage would have a capital cost of $100/kWh. If 80% of that system had to be replaced every 100 months, using straight-line depreciation, the monthly cost would be $800,000. Add that to the financing cost, say 0.5% per month, and other operating costs, maybe another 0.5% per month, and the total monthly cost is $1.8M.</ref> | The most important point of comparison is cost per kilowatt hour (kWh) of storage, including the cost of ancillary equipment like power inverters or heat storage tanks. Other costs, like battery replacement can be included by assuming a reasonable time over which these capital costs are depreciated.<ref>For example, a $100M system providing 1000 megawatt hours (MWh) total storage would have a capital cost of $100/kWh. If 80% of that system had to be replaced every 100 months, using straight-line depreciation, the monthly cost would be $800,000. Add that to the financing cost, say 0.5% per month, and other operating costs, maybe another 0.5% per month, and the total monthly cost is $1.8M.</ref> | ||
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In a power grid with a mix of intermittent and dispatchable sources, and insufficient storage, the capital cost of the dispatchable sources is determined by the peak demand on the grid. Adding intermittent sources reduces only the fuel costs of the dispatchable sources, not their capital costs. | In a power grid with a mix of intermittent and dispatchable sources, and insufficient storage, the capital cost of the dispatchable sources is determined by the peak demand on the grid. Adding intermittent sources reduces only the fuel costs of the dispatchable sources, not their capital costs. | ||
''See also [[Nuclear power reconsidered]].'' | |||
==Pumped hydro== | ==Pumped hydro== | ||
This is the energy storage most widely used by utilities, where available. Near a river with a big reservoir, cost per kWh can be very low, limited only by the cost of operating the motor/pump/turbine/generator. Where water is limited, the capital cost of building | This is the energy storage most widely used by utilities, where available. Near a river with a big reservoir, cost per kWh can be very low, limited only by the cost of operating the motor/pump/turbine/generator. Where water is limited, the capital cost of building reservoirs, upper and lower, should be added to the cost of the intermittent sources.<ref>To store 100 megawatts for 10 hours you will need a hill 500 feet high with 250 acre reservoirs at each end that you can draw up or down 10 feet.</ref> | ||
==Batteries== | |||
Batteries are still too expensive for most utility-scale systems.<ref>Tesla's Megapack provides utility-scale storage for $384 per kWh (price as of 5/30/22 for 1000 Megapacks, 3.9 GWh total storage) https://www.tesla.com/megapack/design</ref> Even with an optimistic projection of future Li-ion battery technology ($100 per kWh) a 10 GW grid might need 300 GWh hours of storage, requiring a $30 billion capital investment.<ref>Liquid metal batteries might cut this cost in half. https://ambri.com/technology</ref> Some newer battery technologies promise lower cost per kWh, but at the scale needed to power the world, there may be resource limitations.<ref name=ambri/><ref name=EIABattRpt/> | |||
==Hydrogen== | |||
The volumetric energy density of hydrogen is too low for transportation uses <ref>"The Hydrogen and Fuel Cell Technologies Office (HFTO) is developing onboard automotive hydrogen storage systems that allow for a driving range of more than 300 miles while meeting cost, safety, and performance requirements." - US Department of Energy https://www.energy.gov/eere/fuelcells/hydrogen-storage</ref> (see Fig.1) but may be possible for utilities. | |||
Hydrogen energy storage may become an important competitor to pumped hydro, if the efficiency of the process, including electrolyzers and fuel cells can be improved. | |||
The US Department of Energy has a ten-year goal of generating hydrogen at $1 per kg.<ref>The first "Earthshot" – [https://www.energy.gov/eere/articles/five-things-you-might-not-know-about-hydrogen-shot Hydrogen Shot] – sets an ambitious yet achievable “1 1 1” goal to reduce the cost of hydrogen to $1 per 1 kilogram in one decade.</ref> | |||
There is also a thermochemical process that might bypass electrolysis and generate hydrogen directly from water using abundant high-temperature heat from a nuclear reactor. See Fig.X | |||
==Thermal== | ==Thermal== | ||
There are many technologies for storing heat,<ref>https://en.wikipedia.org/wiki/Thermal_energy_storage</ref> but for concentrated solar power (CSP) systems, the choice has been molten salt.<ref>https://en.wikipedia.org/wiki/Concentrated_solar_power</ref> | There are many technologies for storing heat,<ref>https://en.wikipedia.org/wiki/Thermal_energy_storage</ref> but for concentrated solar power (CSP) systems, the choice has been molten salt.<ref>https://en.wikipedia.org/wiki/Concentrated_solar_power</ref> | ||
Thermal storage is also being considered at nuclear plants to allow rapid load following in grids that have a large component of wind and solar.<ref>https://natriumpower.com/</ref> Research is continuing on on sensible, latent, and thermochemical energy storage with a goal of $15 per kWh.<ref>[https://www.energy.gov/eere/solar/thermal-storage-rd-csp-systems Thermal Storage R&D for CSP Systems | Department of Energy]</ref> | Thermal storage is also being considered at nuclear plants to allow rapid load following in grids that have a large component of wind and solar.<ref>https://natriumpower.com/</ref> Research is continuing on on sensible, latent, and thermochemical energy storage with a goal of $15 per kWh.<ref>[https://www.energy.gov/eere/solar/thermal-storage-rd-csp-systems Thermal Storage R&D for CSP Systems | Department of Energy]</ref> | ||
==Other== | ==Other== | ||
Although not storing energy to be used for generating electricity, high-temperature reactors can perform the equivalent of energy storage by using excess available energy to power processes that don't care if the energy is intermittent, like the production of steel, cement, and fertilizer. This "process heat" is a big part of our world energy consumption, and can be timed to take advantage of periods when the intermittent sources are at full power. | Although not storing energy to be used for generating electricity, high-temperature reactors can perform the equivalent of energy storage by using excess available energy to power processes that don't care if the energy is intermittent, like the production of hydrogen, steel, cement, and fertilizer. This "process heat" is a big part of our world energy consumption, and can be timed to take advantage of periods when the intermittent sources are at full power. | ||
==Further reading== | ==Further reading== | ||
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== Notes and References == | == Notes and References == | ||
{{Reflist| | {{Reflist|refs= | ||
<ref name=ambri>The [https://ambri.com/technology Liquid Metal Battery] uses low-cost calcium as the anode, but antimony for the cathodes may be in short supply if this technology is scaled up.</ref> | |||
<ref name=EIABattRpt>[https://www.eia.gov/analysis/studies/electricity/batterystorage/pdf/battery_storage.pdf EIA Report on Battery Storage] U.S. Energy Information Administration, 2020</ref> | |||
}}[[Category:Suggestion Bot Tag]] |
Latest revision as of 11:00, 12 August 2024
This article is a brief review of the technologies relevant to the large-scale energy storage [2] needed for wind and solar and other intermittent energy sources. The most important point of comparison is cost per kilowatt hour (kWh) of storage, including the cost of ancillary equipment like power inverters or heat storage tanks. Other costs, like battery replacement can be included by assuming a reasonable time over which these capital costs are depreciated.[3]
Other factors to consider in buying energy storage are the peak power needed and the round-trip-efficiency. Pumped hydro and batteries return about 80% of the energy put in.[4] Thermal storage, where there is no conversion to other forms of energy, can be near 100% efficient.
In a power grid with a mix of intermittent and dispatchable sources, and insufficient storage, the capital cost of the dispatchable sources is determined by the peak demand on the grid. Adding intermittent sources reduces only the fuel costs of the dispatchable sources, not their capital costs.
See also Nuclear power reconsidered.
Pumped hydro
This is the energy storage most widely used by utilities, where available. Near a river with a big reservoir, cost per kWh can be very low, limited only by the cost of operating the motor/pump/turbine/generator. Where water is limited, the capital cost of building reservoirs, upper and lower, should be added to the cost of the intermittent sources.[5]
Batteries
Batteries are still too expensive for most utility-scale systems.[6] Even with an optimistic projection of future Li-ion battery technology ($100 per kWh) a 10 GW grid might need 300 GWh hours of storage, requiring a $30 billion capital investment.[7] Some newer battery technologies promise lower cost per kWh, but at the scale needed to power the world, there may be resource limitations.[8][9]
Hydrogen
The volumetric energy density of hydrogen is too low for transportation uses [10] (see Fig.1) but may be possible for utilities.
Hydrogen energy storage may become an important competitor to pumped hydro, if the efficiency of the process, including electrolyzers and fuel cells can be improved. The US Department of Energy has a ten-year goal of generating hydrogen at $1 per kg.[11]
There is also a thermochemical process that might bypass electrolysis and generate hydrogen directly from water using abundant high-temperature heat from a nuclear reactor. See Fig.X
Thermal
There are many technologies for storing heat,[12] but for concentrated solar power (CSP) systems, the choice has been molten salt.[13] Thermal storage is also being considered at nuclear plants to allow rapid load following in grids that have a large component of wind and solar.[14] Research is continuing on on sensible, latent, and thermochemical energy storage with a goal of $15 per kWh.[15]
Other
Although not storing energy to be used for generating electricity, high-temperature reactors can perform the equivalent of energy storage by using excess available energy to power processes that don't care if the energy is intermittent, like the production of hydrogen, steel, cement, and fertilizer. This "process heat" is a big part of our world energy consumption, and can be timed to take advantage of periods when the intermittent sources are at full power.
Further reading
- Electricity and Energy Storage World Nuclear Association.
Notes and References
- ↑ https://www.energy.gov/eere/fuelcells/hydrogen-storage
- ↑ See Electricity and Energy Storage for a more complete review.
- ↑ For example, a $100M system providing 1000 megawatt hours (MWh) total storage would have a capital cost of $100/kWh. If 80% of that system had to be replaced every 100 months, using straight-line depreciation, the monthly cost would be $800,000. Add that to the financing cost, say 0.5% per month, and other operating costs, maybe another 0.5% per month, and the total monthly cost is $1.8M.
- ↑ https://www.eia.gov/todayinenergy/detail.php?id=46756
- ↑ To store 100 megawatts for 10 hours you will need a hill 500 feet high with 250 acre reservoirs at each end that you can draw up or down 10 feet.
- ↑ Tesla's Megapack provides utility-scale storage for $384 per kWh (price as of 5/30/22 for 1000 Megapacks, 3.9 GWh total storage) https://www.tesla.com/megapack/design
- ↑ Liquid metal batteries might cut this cost in half. https://ambri.com/technology
- ↑ The Liquid Metal Battery uses low-cost calcium as the anode, but antimony for the cathodes may be in short supply if this technology is scaled up.
- ↑ EIA Report on Battery Storage U.S. Energy Information Administration, 2020
- ↑ "The Hydrogen and Fuel Cell Technologies Office (HFTO) is developing onboard automotive hydrogen storage systems that allow for a driving range of more than 300 miles while meeting cost, safety, and performance requirements." - US Department of Energy https://www.energy.gov/eere/fuelcells/hydrogen-storage
- ↑ The first "Earthshot" – Hydrogen Shot – sets an ambitious yet achievable “1 1 1” goal to reduce the cost of hydrogen to $1 per 1 kilogram in one decade.
- ↑ https://en.wikipedia.org/wiki/Thermal_energy_storage
- ↑ https://en.wikipedia.org/wiki/Concentrated_solar_power
- ↑ https://natriumpower.com/
- ↑ Thermal Storage R&D for CSP Systems | Department of Energy