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Macrogrid study: Big value in connecting America’s eastern and western power grids


A map illustration showing where wind and solar power are produced in the country, with a macrogrid connecting the resources and the eastern and western grids.

This map shows how a macrogrid (the red lines) could cross the seam separating the Eastern and Western interconnections, allowing the entire country to share electricity, including Midwest wind energy and Southwest solar energy. Larger image. Map courtesy of the Interconnections Seam Study, the U.S. Department of Energy’s ³Ô¹ÏÍøÕ¾ Renewable Energy Laboratory.

AMES, Iowa – Two of the biggest power grids on the planet are connected by seven small threads.

Those seven threads (technically, they’re back-to-back, high-voltage, direct-current connections) join America’s Eastern and Western interconnections and have 1,320 megawatts of electric-power handling capacity. (The seam separating the grids runs, roughly, from eastern Montana, down the western borders of South Dakota, Nebraska and Kansas and along the western edges of the Oklahoma and Texas panhandles. Texas, with its own grid, is mostly outside the two big grids.)

And they are big grids – the eastern grid has a generating capacity of 700,000 megawatts and the western 250,000 megawatts. So, up to 1,320 megawatts isn’t much electricity moving between the two.

But what if there were bigger connections between the two grids? What if more power moved back and forth? Could that move Iowa wind power, Southwest solar power and Eastern off-shore wind power from coast to coast? Could the West help the East meet its peak demand, and vice versa? Would bigger connections boost grid reliability, resilience and adaptability? Would the benefits exceed the costs?

The short answer: Yes.

That’s according to the , a two-year, $1.5 million study launched as part of a $220 million announced in January 2016 by the .

Researchers, including engineers from Iowa State University, shared early findings during a and the latest findings in two papers published this and by , the Institute of Electrical and Electronics Engineers.

Modeling grid improvements

Iowa State engineers contributed computer modeling expertise to the project, building a capacity expansion model that simulates 15 years of improvements to power generation and transmission. The model includes four designs for cross-seam transmission and eight generation scenarios with differences in transmission costs, renewable-electricity generation, gas prices and retirements of existing power plants.

The Iowa State models took the grid-improvement process up to 2038. Researchers from the U.S. Department of Energy’s in Colorado used the 2038 data to complete an hour-by-hour model of one year of power-sharing across the seam.

“The results show benefit-to-cost ratios that reach as high as 2.5, indicating significant value to increasing the transmission capacity between the interconnections under the cases considered, realized through sharing generation resources and flexibility across regions,” says a summary of the latest paper.

“So, for every dollar invested, you get up to $2.50 back,” said James McCalley, an Iowa State Anson Marston Distinguished Professor in , the Jack London Chair in and a co-author of the papers.

How much would you have to invest?

McCalley said it would take an estimated $50 billion to build what researchers are calling a “macrogrid” of major transmission lines that loop around the Midwest and West, with branches filling in the middle and connecting to Texas and the Southeast.

Identifying the value

The more transmission across the seam, the better, according to the researchers’ paper published this summer.

“B/C (benefit-to-cost) ratio tracks cross-seam transmission capacity: The conditions resulting in the highest cross-seam transmission capacity are the conditions having the highest B/C ratio,” the researchers wrote.

One key finding in the study: “Cross-seam transmission pays for itself: This shows that under conditions associated with a high-renewable future greater than 40%, cross-seam transmission benefits exceeds costs, based only on a 35-year period to assess savings generated by generation investments and operational efficiencies.”

McCalley said the macrogrid pays for itself in three primary ways:

  1. Over a day, different parts of the country have peak demands at different times. With a macrogrid, different regions can help each other meet their daily peaks.
  2. As coal- and gas-fired power plants are retired, a macrogrid allows wind- and solar-power resources to be shared across the country. “The Midwest makes wind energy,” McCalley said. “But not as many people live in the Midwest. So we need to move that energy.”
  3. Utilities now have to build extra capacity to meet their highest demand of the year. A macrogrid can help different parts of the country meet each other’s peak demand, therefore decreasing the amount of peak capacity that has to be built in any once place.

And what about storms – such as the that blew across Iowa in August 2020 or the that cut off power to Texas in February 2021? Could a macrogrid help with those kinds of disasters?

“Another benefit of the macrogrid is being able to deal with these kind of resilience problems,” McCalley said. “You could get electricity assistance from other regions very simply. Iowa and other states would be interconnected with other areas.”

While studies are beginning to quantify the value of an American macrogrid, McCalley said there are many challenges to actually seeing one built. There’s cost, certainly. There are policy and political decisions that have to be made. And there are people who don’t want transmission lines, wind turbines or solar panels anywhere nearby.

What does he say to those people?

“My response has been that every form of energy has negatives,” McCalley said. “Tell me a better alternative.”

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