Government seeks to advance ‘tomorrows energy storage.’
Last week the U.S. Department of Energy (DOE) announced 10 projects that will receive funding through a new Advanced Research Projects Agency-Energy (ARPA-E) program called Duration Addition to electricitY Storage (DAYS). The projects seek to provide up to 100 hours of energy storage.
The announcement was made by Under Secretary for Science Paul Dabbar at the Innovation XLab Energy Storage Summit at SLAC National Laboratory.
“The DAYS awardees will take a good look at what tomorrow’s grid-scale storage could be, and work to develop the technologies that get us there,” said Under Secretary Dabbar.
Most energy storage systems deliver power over a limited time to alleviate congestion, stabilize grid frequency and voltage, or provide intraday shifting services. DAYS projects’ extended discharge times will enable a new set of applications for grid storage, including long-lasting backup power and greater integration of intermittent, renewable energy resources, said DOE in a press release.
ARPA-E said the project teams will work to combine the long-term power output of technologies like pumped hydro with the flexibility of battery systems that can be deployed in multiple environments.
Project winners are listed below in order of funding received. You can find more about the DAYS funding opportunity here.
Form Energy $3.9M for Aqueous Sulfur Systems for Long-duration Grid Storage
Form Energy will develop a long-duration energy storage system that takes advantage of the low cost and high abundance of sulfur in a water-based solution. The team will pursue several competing approaches and ultimately select a single candidate to deliver as a prototype system.
Primus Power $3.5M for Minimal Overhead Storage Technology for Duration Addition to Electricity Storage
Primus Power will work with the Columbia Electrochemical Energy Center to develop a long-duration grid energy storage solution by using a new approach to the zinc bromine battery, a popular chemistry for flow batteries. Taking advantage of the way zinc and bromine behave in the cell, the battery will eliminate the need for a separator to keep the reactants apart when charged, as well as allow all the electrolyte to be stored in a single tank, instead of multiple cells. This reduction in “balance of plant” hardware will reduce system cost.
Quidnet Energy $3.2M for Geomechanical Pumped Storage
Quidnet Energy will develop a modified pumped hydro energy storage system using rocks beneath the Earth’s surface. The team will pump pressurized water into gaps in underground rocks. When energy is needed later, the induced strain in the surrounding rock will force water back through a generator to produce electricity.
Echogen Power Systems $3M for Low-cost, Long-duration Electrical Energy Storage Using a CO2-based Pumped Thermal Energy Storage System
Echogen Power Systems will develop an energy storage system that uses a carbon dioxide (CO2) heat pump cycle to convert electrical energy to thermal energy by heating a “reservoir” of low cost materials such as sand or concrete. The reservoir will retain heat that will be converted back into electricity on demand. To generate power, liquid CO2 will be pumped through the high-temperature reservoir to a supercritical state, after which it will expand through a turbine to generate electricity from the stored heat.
United Technologies Research Center $3M for High-performance Flow Battery with Inexpensive Inorganic Reactants
United Technologies Research Center will develop an energy storage system based on a new flow battery chemistry using inexpensive and readily available sulfur-manganese based active materials. The team will overcome challenges of system control and unwanted crossover between the two active materials through the flow membrane. The affordable reactants, paired with the unique requirements for long-duration electricity discharge, present the opportunity for very low cost energy storage.
Antora Energy $3M for Solid State Thermal Battery
Antora Energy will develop a thermal energy storage system that contains thermal energy in inexpensive carbon blocks. To charge the battery, power from the grid will heat the blocks to temperatures exceeding 2000 °C. To discharge, the hot blocks are exposed to thermophotovoltaic panels that are similar to traditional solar panels but specifically designed to efficiently use the heat radiated by the blocks. The team will seek to double panel efficiency through new materials and smart system design, allowing such a concept to be used cost effectively as a grid storage solution.
National Renewable Energy Laboratory: $2.7M for Economic Long-duration Electricity Storage by Using Low-cost Thermal Energy Storage and High-efficiency Power Cycle
NREL will develop a high temperature, low cost thermal energy storage system using a high-performance heat exchanger and closed loop Brayton cycle turbine to generate power. Electric heaters will warm stable, inexpensive solid particles to temperatures greater than 1100°C during charging. To discharge the system, the particles will be fed through the heat exchanger, heating a working fluid to drive the gas turbine attached to a generator. The electricity storage system is designed to be deployed economically anywhere in the United States.
Michigan State University, $2M for a Scalable Thermochemical Option for Renewable Energy Storage (STORES)
The Michigan State University team will develop a modular thermal storage system that uses electricity from sources like wind and solar power to heat up a bed of magnesium manganese oxide (Mg-Mn-O) particles to high temperatures. Once heated, the Mg-Mn-O will release oxygen and store the heat energy in the form of chemical energy. Later, when additional power is needed, the system will pass air over the particle bed, starting a chemical reaction that releases heat to drive a gas turbine generator.
Brayton Energy $1.99M for Improved Laughlin-Brayton Cycle Energy Storage
The team will develop an energy storage system that combines thermal storage and a gas turbine to generate power. When the system is charging, an electrically driven heat pump will accumulate thermal energy in a molten salt solution, which can then be discharged later by heating gas and sending it through the generation turbine. Brayton Energy’s innovation lies in their reversible turbine design, in which each turbine acts as the comp pression stage for the other, whether during charging or discharging. This approach simplifies the system and increases durability.
University of Tennessee, Knoxville $1.5M for Reversible Fuel Cells for Long-duration Storage
University of Tennessee, Knoxville will develop an energy storage system based on an innovative electrolyzer/fuel cell combination. Typically, fuel cells make water from hydrogen and oxygen, which can be stored in tanks. The Tennessee team will instead use the fuel cell to produce hydrogen peroxide: a liquid that can be easily stored and converted to oxygen. When extra power is needed on the grid, the fuel cell will produce peroxide and electricity. Available electricity then can be used to efficiently convert the peroxide back to oxygen during the charging cycle.