For 60 minutes in January 2023, a power plant like no other existed in the U.S. Mountain West. It contained a solar array, lithium-ion battery, hydrogen electrolyzers, and a nuclear reactor, all coordinating to provide reliable power. Even more unusual, the plant combined actual and simulated technologies hundreds of miles apart.

This unique power plant was part of a national research and development project to remotely connect energy assets in real-time using the Department of Energy’s (DOE’s) Energy Sciences Network (ESnet). By linking capabilities at the National Renewable Energy Laboratory (NREL) and the Idaho National Laboratory (INL), the researchers created a collaborative “SuperLab” allowing them to study energy systems currently not in existence. In this case, they demonstrated that renewable and nuclear energy, combined within a hybrid system, can complement each other well to support the grid.

“Integrating nuclear assets deployed at INL and connecting them with renewable energy assets at NREL showcases the power of energy hybridization technology and underscores the importance of connectivity in achieving sustainable energy solutions,” said Rob Hovsapian, ARIES research lead in hybrid energy systems at NREL. “Innovation without implementation is merely an idea, but at-scale validation is the bridge that makes ideas a reality. The Advanced Research on Integrated Energy Systems (ARIES) platform at NREL is the engine that powers this evolution, connecting multiple assets and de-risking complex energy systems for faster adoption of novel clean energy technologies,” Hovsapian said.

A Virtual Hybrid Plant

The SuperLab demonstration successfully linked energy grid and power production simulations from two laboratories:

  • At NREL (Golden, Colorado), the ARIES platform provided a solar array, battery storage system, hydrogen fuel electrolyzer, and a controllable grid interface. Digital real-time simulators enabled the researchers to connect the models and responses on both NREL and INL sides.
  • At INL (Idaho Falls, Idaho), researchers readied simulations of a small modular nuclear reactor and high-temperature electrolysis in the Human Systems Simulation Laboratory (HSSL).

ESnet-operated fiber-optic cabling provided high-speed, low-latency, and low-jitter data connections between the laboratories. This connection synchronized simulations and control signals, providing “virtual proximity” of the assets.

wind turbines, solar panels and energy storage facilities in a field

control room full of LED monitors and three people

NREL’s ARIES platform (top photo) was connected to INL’s Human Systems Simulation Laboratory (bottom photo) via ESnet6 OSCARS circuits creating a virtual hybrid renewable-nuclear plant. (Credits: [top] National Renewable Energy Laboratory, [bottom] Idaho National Laboratory)

This SuperLab demonstration followed months of preparation by several dozen researchers at INL, NREL, and ESnet. The demonstration was attended by over 60 energy experts, including representatives from other national laboratories and DOE representatives from the Office of Science, the Office of Nuclear Energy, the Office of Electricity, and the Office of Energy Efficiency and Renewable Energy.

Renewable-Nuclear Hybrid: A Complementary Pairing

The SuperLab demonstration showed that nuclear power and renewables could be used in combination for the electric grid. Nuclear reactors operate best in a steady state as a source of baseload power but cannot respond quickly to changes in demand. Wind and solar power can provide intermittent power but are not always dispatchable. Together, they provide stable power during abrupt changes in demand or weather conditions. And for an extra-functional design, the researchers added hydrogen electrolyzers and thermal batteries to store excess energy.

“A hybrid plant that incorporates both nuclear and renewable assets allows us to leverage the unique benefits offered by each of these clean energy technologies,” said Shannon Bragg-Sitton, Integrated Energy & Storage Systems Division director at INL. “It ensures that grid demands are met reliably and affordably at all times while taking advantage of the heat provided by a nuclear thermal generator to produce clean hydrogen and support the decarbonization of industry.”

During the demonstration, the researchers found that their hybrid plant performed as desired. First, they simulated a sudden loss in solar power from a passing cloud, and the nuclear reactor stepped in to support grid demand. Then, when they simulated a storm knocking out neighborhood power lines, the nuclear reactor ramped down its power to the grid and redirected it to increase hydrogen production and storage. These scenarios provide developers with a baseline and high-quality operational data for how hybrid renewables-nuclear designs might operate together for a reliable power grid.

“Demonstrating integrated use of diverse generation assets in a controlled experimental facility allows us to better understand how these systems can mutually support a varying energy demand before major investments are decided,” Bragg-Sitton said. “These demonstrations can emulate performance under both expected and off-nominal conditions to gain confidence in their operations. Through this SuperLab, each laboratory in the DOE complex brings unique expertise to the challenge of clean energy systems of the future.”

Not the First SuperLab

The January demonstration was not just an achievement for hybrid power plants. It also made strides for the network backbone supporting SuperLab: ESnet. This demonstration was one of several – with more to come – to connect megawatts of power hardware using ESnet. In 2017, eight laboratories connected for the first demo using virtual private network connections. It was a successful proof of concept, but varying latency made it difficult to co-simulate power signals requiring millisecond sensitivity.

The ESnet team reduced latency variance, bringing it down from 11.5 milliseconds to 0.02 milliseconds which was useful in 2021 when another SuperLab was assembled to support a remote Alaskan city with its microgrid controls.

 

 

 

 

Researchers were treated to another improvement during the January demonstration when ESnet6 was unveiled. The next-generation high-speed science network features higher data capacity, real-time data visualization, and new automation and cybersecurity tools. It is the latest improvement to an extraordinary scientific platform that has steadily grown since 1986.

“ESnet is proud to support the ARIES project,” said Eli Dart, Science Engagement Group lead at ESnet. “These demonstrations effectively use the OSCARS virtual circuit capabilities of ESnet6. ARIES requires low jitter and deterministic behavior, which OSCARS can provide over dedicated point-to-point connections. Together, ESnet and the ARIES team worked on both demonstrations, and we look forward to continuing this collaboration in the future.”

From its headquarters at Lawrence Berkeley National Laboratory, ESnet branches and converges at laboratories around the nation, reaching many powerful research nodes that include several in Europe. It is really a continental laboratory, with NREL and INL’s experiment as one small (but no less super) link; meanwhile, other researchers using ESnet are synchronizing genetic data and simulating quantum materials. ESnet brings their physical capabilities closer together so that laboratories can share their supercomputers, particle reactors, and wind turbines, regardless of their geographic location.

“As ARIES scales up to thousands of devices and many more laboratories, we are excited to be a part of this team,” Dart said. “The goal is to ensure that the U.S. has a power grid capable of reliably integrating the modern energy technologies we need for the 21st century. Codesign with the SuperLab program allows ESnet to ensure our advanced network supports the success of power grid research. Bringing together the complementary expertise of the national labs is what we do best—everyone brings their best game, and we all work together.”

The renewable-nuclear hybrid demo also provided something in return to ESnet: a blueprint for how to build similar experiments. The next experiment is already in the works since NREL, INL, and other laboratories have already validated and established their SuperLab connections.

More Power, More Devices, and a Major Outage

In the spirit of resilience and with an interest in pushing the limits, the next SuperLab demonstration will simulate a national-scale disaster across eight national laboratories. The researchers plan to study how a major outage from a hurricane or cyberattack would play out on a distributed energy system. The scale of this experiment will be much greater than anything before; while the 2017 demo ran 80 devices, the upcoming demo, scheduled for late 2023, will aim for 10,000 devices.

Once the demonstration is complete, it will be a milestone for the SuperLab concept: The research community will be able to emulate national-scale scenarios on real power hardware, helping to reduce risk for future energy transition strategies. And that is just the start of what can be achieved when all U.S. research capabilities are combined.

“By connecting multiple labs through ESnet by 2024, we’ll unlock the full potential of our national laboratories, their research assets, cutting-edge technologies, and talented scientists,” Hovsapian said. “This SuperLab 2.0 infrastructure will prepare us to address large-scale emergent challenges to meet the nation’s clean energy goals and to reinforce the energy security needs of every community.”

This article comes from the National Renewable Energy Laboratory’s website.

 

 


About Computing Sciences at Berkeley Lab

High performance computing plays a critical role in scientific discovery. Researchers increasingly rely on advances in computer science, mathematics, computational science, data science, and large-scale computing and networking to increase our understanding of ourselves, our planet, and our universe. Berkeley Lab’s Computing Sciences Area researches, develops, and deploys new foundations, tools, and technologies to meet these needs and to advance research across a broad range of scientific disciplines.

About Computing Sciences at Berkeley Lab

High performance computing plays a critical role in scientific discovery. Researchers increasingly rely on advances in computer science, mathematics, computational science, data science, and large-scale computing and networking to increase our understanding of ourselves, our planet, and our universe. Berkeley Lab's Computing Sciences Area researches, develops, and deploys new foundations, tools, and technologies to meet these needs and to advance research across a broad range of scientific disciplines.