Historically, the vast majority of the world’s power has been consumed as quickly as it is made, or it’s wasted. But climate change has made governments interested in renewable energy, and renewable energy is variable—it can’t be dispatched on demand. Or can it? As research into utility-sized batteries receives more attention, the economics of adding storage to a grid or wind farm are starting to make more sense.
But grid-tied energy storage is not new; it has just always been limited to whatever resources a local power producer had at the time. Much like electricity production itself, storage schemes differ regionally. Power companies will invest in batteries that make sense on a local level, whether it is pumped storage, compressed air, or lithium-ion cells.
Looking at the kinds of storage that already exist is instructive in helping us see where storage is going to go, too. Lots of the latest battery projects merely build on engineering that has been in service for decades. To better see our way forward, we collected a number of images and diagrams of the world’s biggest energy storage schemes.
Pumped storage
Pumped storage is possibly one of the oldest forms of modern grid-tied energy storage, and it certainly packs the most punch as far as megawatt-hours delivered.
The way it traditionally works is simple: the system has a bottom reservoir of water to draw from and a top reservoir that’s topographically higher than the bottom reservoir. When there’s not a lot of demand for electricity, you use that power to “charge” the battery by pumping water up to the top reservoir. When demand for electricity is high, that reservoir can be drained via a hydroelectric generator, back down to the bottom reservoir.
The Guangzhou pumped storage hydropower plant is capable of delivering 2.4GW of power. The nearby Huizhou pumped storage facility is also capable of 2.4GW of power. The China Southern Power Grid manages both plants, which help the company serve a staggering 230 million people.
The Guangzhou pumped storage hydropower plant is capable of delivering 2.4GW of power. The nearby Huizhou pumped storage facility is also capable of 2.4GW of power. The China Southern Power Grid manages both plants, which help the company serve a staggering 230 million people.
The Ludington Pumped Storage plant is situated on the shores of Lake Michigan and was built in the early 1970’s by Consumers Energy and Detroit Edison. It has a nameplate capacity of 1,875 MW.
Consumers Energy
The Ludington Pumped Storage plant is situated on the shores of Lake Michigan and was built in the early 1970’s by Consumers Energy and Detroit Edison. It has a nameplate capacity of 1,875 MW.
Consumers Energy
The Guangzhou pumped storage hydropower plant is capable of delivering 2.4GW of power. The nearby Huizhou pumped storage facility is also capable of 2.4GW of power. The China Southern Power Grid manages both plants, which help the company serve a staggering 230 million people.
The Ludington Pumped Storage plant is situated on the shores of Lake Michigan and was built in the early 1970’s by Consumers Energy and Detroit Edison. It has a nameplate capacity of 1,875 MW.
Consumers Energy
Tumut 3 is an 1,800MW pumped storage facility in Australia. It’s part of the Snowy Hydro Scheme, a vast hydroelectric generating area with nine separate power stations. The Australian government recently announced a $2 billion plan to improve and expand pumped hydro storage in the Snowy Mountains, which could add another 2GW of capacity.
Compressed air energy storage, or CAES, is a lot like pumped hydro energy storage, except power producers use electricity during periods of low demand to pump ambient air into a storage container instead of water. When electricity is needed, the compressed air is allowed to expand and used to drive a turbine to generate power.
According to the Energy Storage Association, since air heats up as it’s compressed, that heat has to be removed from the high-pressure air before it’s stored. Then that heat has to be added back to the high-pressure air as it’s released. This is done via a generator (usually a natural gas generator) or in a more environmentally friendly way using heat saved from the storage process in an adiabatic CAES system.
Although compressed air energy storage schemes have been discussed for decades, the expense of building storage facilities means there are only a handful of deployed systems and a slightly larger handful of test systems.
This 110MW non-adiabatic compressed air plant in McIntosh, Alabama, has been operating since 1991.
This 110MW non-adiabatic compressed air plant in McIntosh, Alabama, has been operating since 1991. Power South
The McIntosh plant is the only commercially operating plant in the US. According to the plant’s owner, PowerSouth, pressure in the underground cavern reaches almost 1,100 pounds per square inch at full charge.
The McIntosh plant is the only commercially operating plant in the US. According to the plant’s owner, PowerSouth, pressure in the underground cavern reaches almost 1,100 pounds per square inch at full charge.PowerSouth
The Huntorf plant in Germany is another compressed air, non-adiabatic energy storage plant. It was built with a 290MW capacity and was retrofitted to boost power output to 320MW according AZG Consulting, the company that took part in the retrofit.
The Huntorf plant in Germany is another compressed air, non-adiabatic energy storage plant. It was built with a 290MW capacity and was retrofitted to boost power output to 320MW according AZG Consulting, the company that took part in the retrofit. BBC Mannheim
The McIntosh plant is the only commercially operating plant in the US. According to the plant’s owner, PowerSouth, pressure in the underground cavern reaches almost 1,100 pounds per square inch at full charge.PowerSouth
The Huntorf plant in Germany is another compressed air, non-adiabatic energy storage plant. It was built with a 290MW capacity and was retrofitted to boost power output to 320MW according AZG Consulting, the company that took part in the retrofit. BBC Mannheim
A drawing of how the Huntorf plant works, from BBC Mannheim, the company that designed the plant.
Hydrostor’s Toronto Island system is an adiabatic system that has been in operation since 2015 and has a power rating of 0.7MW.
Hydrostor
On the cutting edge, Canadian company Hydrostor is working to build bigger adiabatic compressed air systems in Ontario and Aruba.
Molten Salt Thermal Storage
Molten salt can retain heat for a long time, so it’s generally found in solar thermal plants, where dozens or hundreds of heliostats (large mirrors) use the heat from sunlight to create energy. In some plants, sunlight is directed toward a large central thermal tower that heats up quickly and boils a working fluid inside. In other plants, pipes full of fluid run in front of parabolic mirrors, and the fluid heats up in those pipes. Either way, that heat can be used immediately to drive a steam turbine, or it can be transferred to molten salt, where the heat can be stored for hours. This helps solar plants extend their working hours and provide electricity well into the evening.
This is a molten salt tank at the thermal solar Solana plant in Gila Bend, Arizona. It was the first US plant to use molten salt storage when it was completed in 2013. The plant has a generation capacity of 250MW. Ars reported from Gila Bend in 2014.
This is a molten salt tank at the thermal solar Solana plant in Gila Bend, Arizona. It was the first US plant to use molten salt storage when it was completed in 2013. The plant has a generation capacity of 250MW. Ars reported from Gila Bend in 2014.Department of Energy
The KaXu Solar One plant in Poffader, South Africa was built by Spanish company Abengoa Solar. It has a 100MW nameplate capacity and can provide up to 2.5 hours of electricity after dark due to molten salt storage.
The KaXu Solar One plant in Poffader, South Africa was built by Spanish company Abengoa Solar. It has a 100MW nameplate capacity and can provide up to 2.5 hours of electricity after dark due to molten salt storage. Abengoa
This is a molten salt tank at the thermal solar Solana plant in Gila Bend, Arizona. It was the first US plant to use molten salt storage when it was completed in 2013. The plant has a generation capacity of 250MW. Ars reported from Gila Bend in 2014.Department of Energy
The KaXu Solar One plant in Poffader, South Africa was built by Spanish company Abengoa Solar. It has a 100MW nameplate capacity and can provide up to 2.5 hours of electricity after dark due to molten salt storage. Abengoa
The Crested Dunes facility in Tonopah, Nevada, has a nameplate capacity of 110MW and can provide 10 hours of electricity from storage.
The Crested Dunes facility in Tonopah, Nevada, has a nameplate capacity of 110MW and can provide 10 hours of electricity from storage. SolarReserve
Another project of Abengoa, the Cerro Dominador facility in Chile already has photovoltaic capacity online, and a 110MW solar thermal plant with 17.5 hours of molten salt storage is expected to be completed in 2019.
Another project of Abengoa, the Cerro Dominador facility in Chile already has photovoltaic capacity online, and a 110MW solar thermal plant with 17.5 hours of molten salt storage is expected to be completed in 2019. Cerro Dominador
The Crested Dunes facility in Tonopah, Nevada, has a nameplate capacity of 110MW and can provide 10 hours of electricity from storage. SolarReserve
Another project of Abengoa, the Cerro Dominador facility in Chile already has photovoltaic capacity online, and a 110MW solar thermal plant with 17.5 hours of molten salt storage is expected to be completed in 2019. Cerro Dominador
On the horizon, molten salt seems to have a clear future. Researchers have been looking into perfecting molten salt batteries for a variety of uses, and just recently, SolarReserve announced plans for a solar thermal plant in Chile that would run for 24 hours a day thanks to a massive molten salt storage area.
Some companies are dreaming up ways to use molten salt energy storage without the need for solar energy, too. Bloomberg recently reported on a molten salt energy storage scheme from Alphabet’s X lab, which would use cheap electricity to heat up molten salt and cool antifreeze. When energy is needed, the process reverses to combine streams of hot and cold air that can push turbines.
Future systems may not use molten salt, either. Researchers from Georgia Tech recently built a ceramic pump that could move liquid metal at very high temperatures. Swapping super-hot liquid metal for molten salt could make this kind of energy storage more efficient.
Redox Flow Batteries
Redox flow batteries are huge batteries that charge and discharge through reduction-oxidation reactions (hence, redox).They usually involve giant shipping containers full of electrolytes, which flow into a common area and interact, often through a membrane, to create an electrical charge. Vanadium electrolytes have become common, although zinc, chlorine, and saltwater solutions have also been tried and proposed.
Although flow batteries are much lower density than the lithium-ion batteries most of us are familiar with, their drawbacks aren’t disqualifiers in a grid-tied situation. Their unwieldy size and weight aren’t a problem because utilities will never have to move them, and flow batteries generally have a long service life and few combustible materials in them, according to Sumitomo Electric, a Japanese technology company. Furthermore, you can always increase the capacity of flow batteries by simply adding more tanks.
Filling shipping containers from UniEnergy Technologies with vanadium solution for a 2MW, 8MWh flow battery in Snohomish County, Washington.
Filling shipping containers from UniEnergy Technologies with vanadium solution for a 2MW, 8MWh flow battery in Snohomish County, Washington. Snohomish PUD
A smaller vanadium redox flow battery bank from UniEnergy Technologies in Pullman, Washington. This system has a capacity rating of 1 MW/4MWh.
A smaller vanadium redox flow battery bank from UniEnergy Technologies in Pullman, Washington. This system has a capacity rating of 1 MW/4MWh.UET
A 2MW/8MWh flow battery installed by Japan’s Sumitomo Electric and San Diego Gas and Electric in Escondido, California.
Sumitomo
A 2MW/8MWh flow battery installed by Japan’s Sumitomo Electric and San Diego Gas and Electric in Escondido, California.
Sumitomo
A smaller vanadium redox flow battery bank from UniEnergy Technologies in Pullman, Washington. This system has a capacity rating of 1 MW/4MWh.UET
A 2MW/8MWh flow battery installed by Japan’s Sumitomo Electric and San Diego Gas and Electric in Escondido, California.
Sumitomo
This flow battery from Primus Power is different from the three before it, as it uses a zinc bromide solution instead of vanadium. Primus just released its modular 25 kW/125kWh system, which is being used at Microsoft’s Redmond facility to experiment with peak shaving.
This graph makes the flow battery system clearer.
Sumitomo Energy
There are few flow batteries currently on the grid, but there are several plans in the pipeline. The largest planned flow battery that we know of to date is being built by Chinese corporation Rongke on the Liaodong Peninsula. That battery will be a 200MW/800MWh system, expected to be completed by the end of 2018.
Conventional rechargeable battery
Probably the best-known among modern energy-storage options, the utility-size lithium-ion battery is the next incarnation of the lithium-ion batteries that power your laptop. Lithium-ion batteries were long considered too expensive to be of use in large-scale operations, but companies like Tesla and AES Energy Storage have been challenging that notion with (relatively) huge installations in California and Australia.
Energy storage can come from any number of sources—natural gas, wind, solar. But having the ability to store energy will allow utilities to put more intermittent renewable energy on the grid. This lithium-ion installation from AES Energy Storage is currently the largest in the world at 30 MW/120MWh.
SDG&E
Energy storage can come from any number of sources—natural gas, wind, solar. But having the ability to store energy will allow utilities to put more intermittent renewable energy on the grid. This lithium-ion installation from AES Energy Storage is currently the largest in the world at 30 MW/120MWh.
SDG&E
A collection of Powerpacks deliver 20MW/80MWh next to the Mira Loma substation in Southern California.
Megan Geuss
A collection of Powerpacks deliver 20MW/80MWh next to the Mira Loma substation in Southern California.
Megan Geuss
These are second-generation Tesla Powerpacks delivering 52MWh on Kauai.
Tesla
These are second-generation Tesla Powerpacks delivering 52MWh on Kauai.
Tesla
A collection of Powerpacks deliver 20MW/80MWh next to the Mira Loma substation in Southern California.
Megan Geuss
These are second-generation Tesla Powerpacks delivering 52MWh on Kauai.
Tesla
Tesla Powerpacks in South Australia. These batteries are only half of what will soon be the largest lithium-ion installation in the world at 129MWh.
This installation, also built by BYD, was completed in 2015 in LaSalle County, Illinois. The system has a 31.5MW power rating (MWh figures were not available).
BYD
In 2014, Southern California Edison built what was then the US’ largest lithium-ion grid-scale battery system, at 32MWh. The installation lives at the Monolith substation in Tehachapi, CA.
Southern California Edison
Lithium-ion batteries are also being explored on a smaller, distributed level by wind turbine manufacturers. Vestas Wind Systems is reportedly exploring pairing its turbines with lithium-ion batteries, as is Deepwater Wind, which is planning to purchase a 40MWh system from Tesla to pair with an offshore wind farm off the coast of Massachusetts, to be completed in 2022.
Before Tesla made grid-tied storage a chic topic and before building lithium-ion batteries was considered economically feasible, utilities and forward-looking companies were building chemical batteries with other materials. A lot of those battery systems are still working today (they’re not very old, after all, but most of them started life as test systems, not commercial systems).
This is an early battery bank created for China Southern Power Grid by Los Angeles-based company BYD in 2011. The batteries housed in this building aren’t lithium-ion; they’re actually iron-phosphate batteries. The system has a 10MW/40MWh capacity rating and was built for load-leveling and peak shaving.
BYD
This is an early battery bank created for China Southern Power Grid by Los Angeles-based company BYD in 2011. The batteries housed in this building aren’t lithium-ion; they’re actually iron-phosphate batteries. The system has a 10MW/40MWh capacity rating and was built for load-leveling and peak shaving.
BYD
Here we have “a 36 megawatt Battery Energy Storage System (BESS) at the site of Duke Energy’s 153MW Notrees wind farm in West Texas.” Started as an advanced lead-acid battery bank in 2012, lithium-ion batteries are being slowly integrated to extend the system’s life.
Here we have “a 36 megawatt Battery Energy Storage System (BESS) at the site of Duke Energy’s 153MW Notrees wind farm in West Texas.” Started as an advanced lead-acid battery bank in 2012, lithium-ion batteries are being slowly integrated to extend the system’s life.Younicos
A view of the Notrees battery bank next to the 153MW Notrees wind farm. As you can see… not a lot of trees.
A view of the Notrees battery bank next to the 153MW Notrees wind farm. As you can see… not a lot of trees. Younicos
Here we have “a 36 megawatt Battery Energy Storage System (BESS) at the site of Duke Energy’s 153MW Notrees wind farm in West Texas.” Started as an advanced lead-acid battery bank in 2012, lithium-ion batteries are being slowly integrated to extend the system’s life.Younicos
A view of the Notrees battery bank next to the 153MW Notrees wind farm. As you can see… not a lot of trees. Younicos
The Wind Energy Institute of Canada has a 2MWh sodium-nickel chloride battery with a 1MW inverter at the site of its wind farm. The battery system has been used to study “time shifting, demand and energy avoidance on a wind farm, diesel displacement, and frequency regulation,” according to WEICAN.
WEICAN
Golden Valley Electric Association (GVEA) in Fairbanks, Alaska, has a nickel-cadmium battery system that can supply 27MW for 15 minutes. GVEA brings power up from Anchorage, but if a generator loses power, those 15 minutes give the grid managers at GVEA time to start a local generator. The system has been operating since 2003, and in the last five years it has prevented between 52 and 78 outages per year.
PDC Engineering
Thermal storage
Like many of these energy storage systems, thermal storage is a dramatic departure from what a common person would think of as a “battery.” Much like compressed air and pumped storage, thermal storage systems take electricity when it’s cheap (usually at night) to freeze water. During the day, that ice is melted and circulated through a system that allows the neighboring facility to be cooled without running energy-intensive air conditioning in the middle of a hot day (when demand for electricity is already high and generating stations are inefficient because generators need to power cooling functions).
A company called Calmac has been making thermal energy storage systems for decades. One of the most notable was the thermal storage system on the Plano, Texas, JC Penny Headquarters in 1991, which provides 4MW of cooling. This image is of a similar system placed on the roof of the California Lottery Headquarters. The water/ice tanks are also covered with solar panels to maximize that rooftop utility.
Calmac
A company called Calmac has been making thermal energy storage systems for decades. One of the most notable was the thermal storage system on the Plano, Texas, JC Penny Headquarters in 1991, which provides 4MW of cooling. This image is of a similar system placed on the roof of the California Lottery Headquarters. The water/ice tanks are also covered with solar panels to maximize that rooftop utility.
Calmac
A company called Calmac has been making thermal energy storage systems for decades. One of the most notable was the thermal storage system on the Plano, Texas, JC Penny Headquarters in 1991, which provides 4MW of cooling. This image is of a similar system placed on the roof of the California Lottery Headquarters. The water/ice tanks are also covered with solar panels to maximize that rooftop utility.
Calmac
The utility serving the city of Redding, California, started funding thermal energy storage projects about a decade ago and partnered with Ice Energy Holdings to put some thermal systems on rooftops. These systems are called Ice Bears.
Redding Electric Utility
The utility serving the city of Redding, California, started funding thermal energy storage projects about a decade ago and partnered with Ice Energy Holdings to put some thermal systems on rooftops. These systems are called Ice Bears.
Redding Electric Utility
These rooftop systems in Redding provide a 95 percent reduction in cooling-related peak demand, the state of California says.
Redding Electric Utility
These rooftop systems in Redding provide a 95 percent reduction in cooling-related peak demand, the state of California says.
Redding Electric Utility
The utility serving the city of Redding, California, started funding thermal energy storage projects about a decade ago and partnered with Ice Energy Holdings to put some thermal systems on rooftops. These systems are called Ice Bears.
Redding Electric Utility
These rooftop systems in Redding provide a 95 percent reduction in cooling-related peak demand, the state of California says.
Redding Electric Utility
Thermal energy has its appeal in hot areas with cool nights, especially in California and the southwest. In May, thermal energy system builder Ice Energy partnered with NRG Energy to deliver 1,800 “ice batteries” to commercial and industrial customers of Southern California Edison, the local utility.
Flywheels
The Energy Storage Association (ESA) defines a flywheel system as one that stores electric energy as kinetic energy. Electric power is used to set a rotor spinning at high speeds, and then that energy is maintained through rotational energy. When energy is drawn off the flywheel to provide electricity to a system, the rotor slows down. But at times of low-energy demand, that flywheel can be sped back up again. Flywheels are generally operated in vacuum-sealed, near-frictionless environments to maintain efficiency.
Only a few “flywheel farms” exist, but it is a neat, if lesser-known, method of storing energy. Grid-tied systems tend to be used for frequency response (that is, smoothing out power delivery) rather than for storing energy to replace a generator in an outage, for example. But we’re including it anyway as a pretty cool technology that defers electricity consumption after electricity production.
Components of a flywheel system.
Beacon Power, LLC
Components of a flywheel system.
Beacon Power, LLC
Amazingly, flywheels were suggested as a means of powering buses in the 1940s and ’50s. A so-called Gyrobus would power up its flywheel at intervals along its route. The Gyrobus was an alternative to noisy, dirty internal combustion buses and avoided the need for an electric bus to stay connected to overhead power lines.
In 2013, Volvo also proposed a system that used a small flywheel to boost efficiency.
Volvo
But back to grid-tied energy storage. This 20 MW flywheel plant in Stephentown, New York, was built in 2011. It’s used for frequency regulation services for the New York Independent System Operator.
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