Deployable Energy is a young company with a guiding principle. They believe that nuclear energy should be a product, not a project. Founded in 2025 after a period of intensive study and design work, the company has developed a product branded as the Unity Nuclear Battery (UNB).

It’s a 1 MWe (3 MWth) micro reactor whose general features arise from a unique combination of nuclear fuel, reactor coolant and neutron moderator. The choices the company made arise from a desire to move fast using materials that are affordable and available for use today. That criteria requires the materials to be in commercial service from suppliers that can provide a price list or firm quote given delivery terms and conditions. Where appropriate, it also means that the materials are qualified for use in nuclear reactors and for exposure to neutron and gamma flux.

UNB designers determined that they would use regular fuel – uranium enriched to < 5% U-235 and in the form of uranium dioxide (UO2) in sintered pellets mass manufactured by an established vendor. Zirconium alloy tubes separate the fuel from the coolant and moderator and retain fission products that might be released by the ceramic UO2 pellets during and after operation. The heat transfer fluid, more frequently referred to as reactor coolant, is inert helium gas that is blown through the core at high velocity and a pressure of approximately 50 bar (~725 psi). The neutron moderator is water at atmospheric pressure and a temperature that is roughly equal to residential hot water.

The reactor vessel that is needed to contain the chosen combination of functional core materials is small enough and light enough to be transported in the back of a short-bed American pick-up truck with a crew cab.

A full nuclear heat source system with transportation level shielding will fit into a 20 foot shipping container with a mass of about 20 tons. The additional shielding and physical protection layers added on site will add another 40 tons to the nuclear heat source portion of the system.

The system will be shielded with sufficient materials to reduce neutron and gamma radiation to below regulatory standards both during and after operation.

The pressurized helium will transfer the heat generated in the reactor to heat exchanger(s) where either water or supercritical CO2 will pick up the helium’s heat for either steam or hot sCO2 production. Steam or sCO2 will go to the balance of plant, which will be housed in a 40 foot transportation container. Depending on application, hot fluids can be used in industrial applications or used to turn turbine generators. The ultimate heat sink is the atmosphere with air coolers mounted on top of the balance of plant container. Many of Deployable Energy’s target customers and applications value low water use.

Knowing that permissions required for construction, manufacturing, transportation and operating are key milestones, Deployable Energy began its pre-application engagement with the NRC in October 2025, within months of its corporate founding.

The company also began engaging with the Department of Energy regarding its initial demonstration unit. It wasn’t ready to compete for the Reactor Pilot Program, but it was one of four companies selected for the Nuclear Energy Launch Pad, which is the DOE’s follow-on to the foundational Reactor Pilot Program and Fuel Line Pilot Program. Deployable Energy plans to catch up to the Reactor Pilot Program participants and achieve initial criticality by July 4, 2026.

To learn more about Deployable Energy and their Unity Nuclear Battery, I talked with Bobby Gallagher, Deployable Energy’s CEO and Chief Technical Officer. Bobby’s background in the Australian military, oil and gas, shipbuilding, offshore development and successful technology start-up founder might seem to be a rather odd path towards designing a product using a nuclear fission heat source, but he explains how he arrived at his current position rather well.

During our discussion, Bobby described the decision criteria and process used to determine the UNB’s final combination of fuel, heat transfer fluid and moderator. He provided some of the historical background from other nuclear reactor designs that inspired the decisions.

But more of our conversation’s content was on the company’s choices related to manufacturing and deployment. We talked about Deployable Energy’s choice to put the center of its operations in Houston, Texas where the local manufacturing base for vessels, tanks, valves, tubes, skids, and other key components is well established and has been honed and expanded during the past several decades of world-leading “unconventional” oil and gas development.

Houston is an energy town with a deep understanding of the value and risks associated with providing power to the population. The city’s residents know how to manufacture, build and heavy equipment and they know how to create and finance innovative companies.

We had a fascinating conversation. I’m confident that you will learn something by listening to the show at least once. We no longer accept comments here for a number of reasons, but you can ask questions and make comments to @atomicrod on X.