BWXT selected by US DOD to deliver prototype reactor - Nuclear Engineering International

2022-06-15 10:58:48 By : Ms. Angel Cheng

BWX Technologies (BWXT) has said it will build the first advanced nuclear microreactor in the United States under a contract awarded by the US Department of Defense (DOD) Strategic Capabilities Office (SCO). The Project Pele full-scale transportable microreactor prototype will be completed and delivered in 2024 for testing at the Idaho National Laboratory (INL).

SCO has partnered with the US Department of Energy (DOE) to develop, prototype and demonstrate a transportable microreactor that can provide a resilient power source to the DOD for a variety of operational needs that have historically relied on fossil fuel deliveries and extensive supply lines. Transportable microreactors deliver clean, zero-carbon energy where and when it is needed in a variety of austere conditions for not only the DOD, but also potential commercial applications for disaster response and recovery, power generation at remote locations, and deep decarbonisation initiatives.

The prototype will be built under a cost-type contract valued at approximately $300 million, depending on options selected, by BWXT Advanced Technologies in facilities in Lynchburg, Virginia and Euclid, Ohio. Over the next two years, BWXT expects that approximately 120 employees will work on the project, including roughly 40 skilled trades, engineers and other positions that will be hired to support this effort and other projects.

“We are on a mission to design, build and test new nuclear technology to protect the environment while providing power,” said Joe Miller, BWXT Advanced Technologies LLC president. “The entire nuclear industry recognises that advanced reactors are an important step forward to support growing power needs and significant carbon reduction imperatives.”

The high-temperature gas-cooled reactor (HTGR) will operate at a power level of 1-5MWe and will be transportable in commercially available shipping containers. It will be powered by Triso fuel, a specific design of high-assay low-enriched uranium (Haleu) fuel that can withstand extreme heat and has very low environmental risks. The transportable reactor core and associated control system is designed to maintain safety under all conditions, including transitional conditions throughout transport. BWXT said the fuel has been tested and verified to temperatures far exceeding the operating conditions of the reactor.

The transportable design consists of multiple modules that contain the microreactor’s components in 20-foot long, ISO-compliant CONEX shipping containers. The reactor is designed to be safely and rapidly moved by road, rail, sea or air. The entire reactor system is designed to be assembled on-site and operational within 72 hours. Shut down, cool down, disconnection and removal for transport is designed to occur in less than seven days.

A diverse team of companies are joining BWXT to support delivery and successful operation of the Project Pele prototype. BWXT is the prime contract and integration lead, and is responsible for reactor module manufacture. Other companies include: Northrop Grumman, Aerojet Rocketdyne, Rolls-Royce LibertyWorks, and Torch Technologies.

The reactor and fuel will be shipped separately, with fuelling taking place at the test site. Once fuelled, the system will undergo up to three years of testing at INL to confirm performance and operability. The test programme will demonstrate that the reactor can produce reliable off-grid electric power. Power generated by the reactor will be transferred to load banks that accurately mimic the operational load that a power source would see in actual application.  In addition, the system will be disassembled and re-assembled to prove transportability.

BWXT said that, consistent with the non-commercial nature of the project, testing and operation will proceed under authorisation by DOE. The Nuclear Regulatory Commission, consistent with its role as an independent safety and security regulator, is participating to provide SCO with accurate, current information on applicable regulations and licensing processes.