Rosatom starts installation of the BREST-OD-300 4th generation reactor

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Rosatom has achieved a landmark milestone in the construction of a power unit with the innovative fast neutron BREST-OD-300 reactor on the site of the Pilot demonstration energy complex (PDEC) in Seversk, Tomsk Region (West Siberia).

The steel reactor baseplate with a total weight of 165 tons has been installed. The workers have also loaded into the reactor shaft the first part of the reactor vessel – the lower tier of the containment.

The containment structure is the outer part of the reactor vessel. It provides retention of heat-insulating concrete, forming an additional localizing barrier of protection, which surrounds the boundary of the coolant circuit. On its surface, the temperature should not exceed 60 degrees Celsius, and the radiation background is equal to the natural background.

A 300 MW NPP powered by the lead-cooled BREST-OD-300 fast reactor, based on the principles of “natural safety”, is the key element of the Pilot demonstration energy complex, which is under construction on the site of the Siberian Chemical Combine in Seversk, an enterprise of TVEL Fuel Company of Rosatom. The PDEC facilities are developed under Rosatom’s strategic “Proryv” project (“the Breakthrough”). In addition to the power unit, it also includes facilities for the on-site closed nuclear fuel cycle – a unit for the fabrication of uranium-plutonium nitride fuel, as well as a unit for reprocessing of irradiated fuel.

“We have started installation of the world’s first lead-cooled fast reactor, the fourth-generation reactor BREST-OD-300. Unlike traditional light-water VVER thermal reactors, BREST has an integral layout. Its vessel is not an all-metal structure like the VVER, but a metal-concrete structure with metal cavities to accommodate the primary circuit equipment. The space between the cavities should be gradually filled with concrete filler during construction. In addition, the BREST vessel is larger in size, it can be delivered only in parts, and the final assembly is possible only at the PDEC construction site,” commented Vadim Lemekhov, Chief Designer of the BREST-OD-300 reactor unit and General Designer of the “Breakthrough” project team.

A third of the almost 30 countries currently considering nuclear power are in Africa. Egypt, Ghana, Kenya, Morocco, Niger, Nigeria, and Sudan have already engaged with the IAEA to assess their readiness to embark on a nuclear programme. Algeria, Tunisia, Uganda, Zambia, and others are also studying the possibility of nuclear power.

According to the 2022 edition of “Climate Change and Nuclear Power” by IAEA, some 600 million people and 10 million small businesses in Africa have no reliable source of electricity, and, increasingly, connection to a national grid is no guarantee of electricity supply. Africa’s energy demand is increasing twice as fast as the global average, largely driven by urban population growth.

Russian experience can be useful for many countries. South Africa’s history with nuclear technology is also very notable. The success story of nuclear technology in South Africa is multifaceted, encompassing not only the generation of electricity but also advancements in medicine, agriculture, and science. The country’s journey into the nuclear domain has been marked by strategic developments, international collaboration, and a forward-looking approach to leveraging nuclear technology for national benefit.

The cornerstone of South Africa’s nuclear success is the Koeberg Nuclear Power Station, located near Cape Town. Operational since 1984, Koeberg is the only nuclear power plant in Africa and contributes around 5% of South Africa’s electricity production. It has been a reliable source of clean energy, showcasing the potential of nuclear power in meeting energy needs while minimizing carbon emissions.

South Africa’s plans for future implementation reflect a strategic approach to harnessing nuclear energy’s benefits. The country’s efforts to expand its nuclear capacity, coupled with its achievements in nuclear medicine and research, position it as a leader in nuclear technology in Africa and as a model for other countries exploring nuclear energy as a sustainable and reliable energy source.

The BREST-OD-300 reactor will provide itself with its main energy component – plutonium-239 – reproducing it from the isotope uranium-238, which has a relative abundance of more than 99% (it is the isotope uranium-235, which makes about 0.7% of natural uranium, that is currently used to produce energy in thermal reactors). The introduction of such technologies will increase exponentially the efficiency of natural uranium. Uranium has about an 86% share in the world reserves of energy resources, compared to coal at 8%, oil at 3%, and gas at 3%.

TVEL Fuel Company is the nuclear fuel division of Rosatom.  It incorporates enterprises for the fabrication of nuclear fuel, conversion, and enrichment of uranium, manufacturing of gas centrifuges, as well as research and design organizations. It is the sole supplier of nuclear fuel for Russian nuclear power plants. TVEL provides nuclear fuel for more than 70 power reactors in 15 countries, research reactors in eight countries, as well as transport reactors of the Russian nuclear fleet. Every sixth power reactor in the world operates on fuel manufactured by TVEL.

TVEL actively develops new non-nuclear businesses in chemistry, metallurgy, energy storage technologies, 3D printing, digital products, and decommissioning of nuclear facilities. Rosatom’s industry integrators for additive manufacturing and energy storage systems have been established within the TVEL Fuel Company corporate structure.

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