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How residential energy storage could help support the power grid Household batteries could contribute to making the grid more cost effective, reliable, resilient, and safe—if retail battery providers, utilities, and regulators can resolve delicate commercial, operational, and policy issues. The growth of battery storage in the power sector has attracted a great deal of attention in the industry and media. Much of that attention focuses on utility-scale batteries and on batteries for commercial and industrial customers. While these larger batteries are critical segments of the energy-storage market, the rapid growth of residential energy storage is outpacing expectations, and these household systems will likely become important assets sooner than many expect. The growth trajectory and potential value of these household systems to customers and the power grid warrants a closer look. During the past four years, annual installations of residential energy-storage systems in the United States have jumped from 2.25 megawatt-hours (MWh) in 2014 to 185 MWh in 2018. Many consumers clearly want the added control, reliability, and resilience that comes from having a battery at home. As a result, many communities may soon have an unexpected resource, a network of home-based batteries that residential customers have already paid for but are not used every day. What would it take to enable residential energy storage to help local utilities make power grids more cost effective, reliable, resilient, and safe? Grids in many regions are under increasing strain. Grid assets are aging. Intermittent sources of renewable energy generate increasing amounts of power, requiring more load balancing. The incidence of severe weather is rising. These trends are worsening bottlenecks and choke points in the energy delivery system, resulting in higher costs and threatening to increase local power outages. The rising incidence of severe weather, along with other trends, has put added strain on grids in many regions, resulting in higher costs and threatening to increase local power outages. Utilities are taking action to increase grid reliability and resilience. Some utilities already administer so-called demand-response programs that encourage customers to reduce power consumption during peak demand periods. Likewise, utilities are pursuing comprehensive grid-modernization programs to increase capacity and harden the grid system. And some utilities are investing heavily in utility-scale energy-storage solutions, putting big batteries next to power plants and transmission lines and in substations to reduce costs and improve reliability. As more customers invest in “behind the meter” residential energy-storage systems, utilities will gain another potential lever for balancing energy demand and supply. Residential batteries could be linked together and dispatched to deliver grid support services, much as utilities use demand-response programs and ancillary services resources today. Since the batteries are already in place, the marginal cost of dispatching residential energy storage resources could be quite low. This could help utilities avoid more costly remedies such as firing up inefficient peaking plants or building extra grid infrastructure that may only be used infrequently. Integrating residential-storage systems into an efficient, dispatchable network that supports the power grid won’t be easy. But evidence is emerging that it can be done. Some states have launched pilot programs that let utilities pay battery-equipped households for using some of their stored power at times when the system is under strain. To support market development, regulators and utilities will need to assess how and where residential batteries can support the grid (for example, by identifying capacity constraints at the feeder level) and incorporate their assessments into utilities’ resource- and grid-planning approaches. Regulators may also consider fine-tuning rate structures and other compensation mechanisms for batteries and think through how to integrate batteries into system design. Likewise, residential energy-storage network operators will need to make sure customers have bought in to using their batteries to support the grid and demonstrate to the local utility that these behind-the-meter systems are reliable and dispatchable at a moment’s notice when the utility grid network needs the support. Charting the growth of residential energy storage Residential energy-storage installations in the United States have increased dramatically—more than 200 percent annually—during the past four years, and rapid growth is expected to continue (Exhibit 1). Residential energy-storage installations even exceeded utility-scale storage installations for the first time in 2018, reflecting the high value customers are placing on having their own storage systems. Several factors have contributed to the rapid uptake of residential energy-storage systems:
Already, residential energy-storage systems are attractive for more than 20 percent of US households (Exhibit 3). That market should expand significantly as manufacturers drive down the cost of residential batteries and installers gain the experience and scale to cut installation costs. As a result, we expect continued strong residential energy-storage growth. Annual installations of residential energy-storage capacity could exceed 2,900 MWh by 2023. The more residential energy-storage resources there are on the grid, the more valuable grid integration may become. So several states are experimenting with grid-integration programs targeted at residential energy storage. Massachusetts and New York are developing “clean peak” policies that promote the use of residential storage, rather than auxiliary fossil-fuel plants, to meet peak demand. And starting in 2020, under an update to the state’s Title 24 standards for building energy efficiency, California is set to require new homes built in the state to have solar power and will encourage builders to add battery storage. Utilities are mounting experimental efforts of their own. National Grid offers customers a financial incentive to enroll in its bring-your-own-battery program. Liberty Utilities recently launched a pilot program that charges customers a small monthly fee to let Liberty install residential energy-storage systems, creating new backup power sources. ISO New England awarded Sunrun, a home-solar and energy-services company, a contract to deploy a certain number of residential solar-plus-storage systems, adding resources to the capacity market. Looking forward: Unlocking further value from residential energy storage As the installed base of residential batteries increases, these residential energy-storage assets will gain the density and scale to deliver grid services that create value in several ways:
As the installed base of residential batteries increases, these residential energy-storage assets will gain the density and scale to deliver grid services that create value. However, before the potential of residential energy storage to provide grid services can be realized, several changes will need to take place:
To start on this journey, utilities and residential energy-storage providers could establish partnerships to prioritize the adoption of residential batteries in areas with the worst grid constraints. Likewise, collaboration on dispatch software requirements could significantly reduce system-integration costs. With each passing year, US households install more residential energy-storage systems as storage prices fall and the value increases. These residential storage systems could be surprisingly valuable to local grid operators. Successful integration will require all involved stakeholders—utilities, homeowners, residential storage providers, and regulators—to collaborate to improve grid economics, reliability, and safety. Regions that decide to take advantage of installed residential energy-storage resources may find an unexpected resource that could help all utility customers benefit from energy-storage technology.
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