Difference between revisions of "Energy Storage"
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''“In new research appearing in the Journal of the American Chemical Society (JACS), the flagship journal of the ACS, lead author Brian Wadsworth, along with colleagues Anna Beiler, Diana Khusnutdinova, Edgar Reyes Cruz, and corresponding author Gary Moore describe technologies that combine light-gathering semiconductors and catalytic materials capable of chemical reactions that produce clean fuel.”'' | ''“In new research appearing in the Journal of the American Chemical Society (JACS), the flagship journal of the ACS, lead author Brian Wadsworth, along with colleagues Anna Beiler, Diana Khusnutdinova, Edgar Reyes Cruz, and corresponding author Gary Moore describe technologies that combine light-gathering semiconductors and catalytic materials capable of chemical reactions that produce clean fuel.”'' | ||
− | = Mechanical Energy | + | = Mechanical Energy Storage= |
=== Compressed Air Energy Storage === | === Compressed Air Energy Storage === | ||
Industrial development of compressed air energy storage (CAES) has made some advances. Since the 1870’s, CAES systems have been deployed to provide effective, on-demand energy for cities and industries. While many smaller applications exist, the first utility-scale CAES system was put in place in the 1970’s with over 290 MW nameplate capacity. Care has to be taken since compressing air heats it up and releasing the pressure cools it down. Thermodynamics have to be managed carefully to the decompress phase doesn't require fuels to heat it up. | Industrial development of compressed air energy storage (CAES) has made some advances. Since the 1870’s, CAES systems have been deployed to provide effective, on-demand energy for cities and industries. While many smaller applications exist, the first utility-scale CAES system was put in place in the 1970’s with over 290 MW nameplate capacity. Care has to be taken since compressing air heats it up and releasing the pressure cools it down. Thermodynamics have to be managed carefully to the decompress phase doesn't require fuels to heat it up. | ||
− | Unfortunately, large-scale CAES plants are very energy inefficient. Compressing and decompressing air introduces energy losses, resulting in an electric-to-electric efficiency of only 40-52%, compared to 70-85% for pumped hydropower plants, and 70-90% for chemical batteries. | + | Unfortunately, large-scale CAES plants are very energy inefficient. Compressing and decompressing air introduces energy losses, resulting in an electric-to-electric efficiency of only 40-52%, compared to 70-85% for pumped hydropower plants, and 70-90% for chemical batteries. See; |
− | + | :[https://www.lowtechmagazine.com/2018/05/ditch-the-batteries-off-the-grid-compressed-air-energy-storage.html "Ditch the Batteries: Off-Grid Compressed Air Energy Storage"] - Low-Tech Magazine - no date. | |
+ | |||
+ | ===Flywheel Energy Storage Systems=== | ||
+ | Flywheel energy storage systems (FESS) use electric energy input which is stored in the form of kinetic energy. Kinetic energy can be described as “energy of motion,” in this case the motion of a spinning mass, called a rotor. The rotor spins in a nearly frictionless enclosure. When short-term backup power is required because utility power fluctuates or is lost, the inertia allows the rotor to continue spinning and the resulting kinetic energy is converted to electricity. See; | ||
+ | |||
+ | :[https://www.scientificamerican.com/article/new-flywheel-design/ "Turn Up the Juice: New Flywheel Raises Hopes for Energy Storage Breakthrough"] - Scientific American - Chris Nelder - April 10, 2013 | ||
= Aluminum-air Flow Batteries = | = Aluminum-air Flow Batteries = | ||
:[https://phys.org/news/2018-10-catalyst-high-energy-aluminum-air-batteries.html "A novel catalyst for high-energy aluminum-air flow batteries"] - Phys.org - Ulsan National Institute of Science and Technology - Oct 15, 2018 | :[https://phys.org/news/2018-10-catalyst-high-energy-aluminum-air-batteries.html "A novel catalyst for high-energy aluminum-air flow batteries"] - Phys.org - Ulsan National Institute of Science and Technology - Oct 15, 2018 |
Revision as of 01:10, 2 June 2020
Contents
Hydrogen Energy Storage
Videos from CNBC:
Why hydrogen is becoming a big deal, CNBC
- Why hydrogen is becoming a big deal, part one | Sustainable Energy duration 15:49
- Why hydrogen is becoming a big deal, part two | Sustainable Energy duration 10:38
Gravity Energy Storage
Energy Vault
Gravitricity
Ares Systems
Rail based gravity system – reverse electrification (3rd rail)
https://www.aresnorthamerica.com/
Chemical Energy Storage
Photoelectrosynthesis
- Extracting clean fuel from sunlight, Phys.org - Richard Harth, Arizona State University - September 3, 2019
“In new research appearing in the Journal of the American Chemical Society (JACS), the flagship journal of the ACS, lead author Brian Wadsworth, along with colleagues Anna Beiler, Diana Khusnutdinova, Edgar Reyes Cruz, and corresponding author Gary Moore describe technologies that combine light-gathering semiconductors and catalytic materials capable of chemical reactions that produce clean fuel.”
Mechanical Energy Storage
Compressed Air Energy Storage
Industrial development of compressed air energy storage (CAES) has made some advances. Since the 1870’s, CAES systems have been deployed to provide effective, on-demand energy for cities and industries. While many smaller applications exist, the first utility-scale CAES system was put in place in the 1970’s with over 290 MW nameplate capacity. Care has to be taken since compressing air heats it up and releasing the pressure cools it down. Thermodynamics have to be managed carefully to the decompress phase doesn't require fuels to heat it up.
Unfortunately, large-scale CAES plants are very energy inefficient. Compressing and decompressing air introduces energy losses, resulting in an electric-to-electric efficiency of only 40-52%, compared to 70-85% for pumped hydropower plants, and 70-90% for chemical batteries. See;
- "Ditch the Batteries: Off-Grid Compressed Air Energy Storage" - Low-Tech Magazine - no date.
Flywheel Energy Storage Systems
Flywheel energy storage systems (FESS) use electric energy input which is stored in the form of kinetic energy. Kinetic energy can be described as “energy of motion,” in this case the motion of a spinning mass, called a rotor. The rotor spins in a nearly frictionless enclosure. When short-term backup power is required because utility power fluctuates or is lost, the inertia allows the rotor to continue spinning and the resulting kinetic energy is converted to electricity. See;
- "Turn Up the Juice: New Flywheel Raises Hopes for Energy Storage Breakthrough" - Scientific American - Chris Nelder - April 10, 2013
Aluminum-air Flow Batteries
- "A novel catalyst for high-energy aluminum-air flow batteries" - Phys.org - Ulsan National Institute of Science and Technology - Oct 15, 2018