Charging ahead —

US grid-battery costs dropped 70% over 3 years

The EIA expects 6,900 megawatts of battery capacity in the next few years.

US grid-battery costs dropped 70% over 3 years

In recent years, the cost of solar and wind energy has declined precipitously, which has accelerated the growth of these renewable energy technologies. Increasingly, utilities are now planning for a future grid dominated by solar and wind. That will require changes in grid management and transmission upgrades as well as the addition of storage to smooth out the supply from variable generators.

Grid storage is still pretty early days, but we’re already seeing huge cost reductions as the industry matures. The US Energy Information Administration (EIA) highlighted this recently, showing that grid-scale battery-project costs in the United States dropped 70 percent in just a few years.

Between 2015 and 2018, average project costs decreased from $2,152 per kilowatt-hour of storage to $625. Costs will need to drop much more for grid batteries to scale, but that’s a huge improvement in a short period of time.

Average costs (per kilowatt-hour capacity) dropped about 70 percent from 2015 to 2018.
Enlarge / Average costs (per kilowatt-hour capacity) dropped about 70 percent from 2015 to 2018.

By the end of 2018, the US had 869 megawatts of battery power capacity and 1,236 megawatt-hours of energy capacity. (Power is the rate at which the batteries can supply electricity, while energy is the total amount it can supply when going from full charge to empty.) EIA also has installation data for 2019, which saw the addition of another 150 megawatts/450 megawatt-hours. And in just the first seven months of 2020, yet another 300 megawatts of power capacity were installed.

EIA doesn’t see this slowing down. It expects installed battery storage to increase by 6,900 megawatts “in the next few years”—a figure ambiguous enough to allow for a rapid spike in planned projects.

While you might think that one battery is more or less the same as another, there are regional differences hidden within the average costs of recent projects. In the Midwest- to mid-Atlantic region of the grid managed by PJM, for example, the average cost between 2013 and 2018 was $1,946 per kilowatt-hour. Projects in Hawaii averaged just $947 per kilowatt-hour.

Average costs for different grid regions, with circle size representing capacity. Batteries can be designed to prioritize power (rate) or energy (total storage).
Enlarge / Average costs for different grid regions, with circle size representing capacity. Batteries can be designed to prioritize power (rate) or energy (total storage).

Much of this difference can be explained by the fact that batteries are serving many different purposes. In the PJM region, for example, that cost drops to $1,004 if you calculate it per kilowatt rather than per kilowatt-hour. And by that metric, Hawaii’s average cost goes up to $1,498.

Batteries aren’t just used to soak up solar generation during the afternoon and release it in the evening. They can provide a number of unique grid-stability services, which is what a number of these early projects were built for. By quickly varying its charge or discharge rate, a battery can help regulate frequency for a section of the grid. In a similar buffering role, batteries can act as a sort of waiting room on busy transmission connections, storing electricity until capacity opens to send it down the line. Both of these services prioritize power (watts) over energy (watt-hours).

Another service is “black start” capability—a back-up contingency in case of outages to help generating plants spin back up. While this is rarely (if ever) needed, utilities are willing to spend more on these small-scale, specialized kinds of safety nets.

But with prices dropping, the economics of adopting significant amounts of storage to pair with cheap but variable generation are improving.

Channel Ars Technica