Power

Micro modular reactor is cooled by supercritical S-CO2

9th March 2016
Enaie Azambuja
0

A research team at Korea Advanced Institute of Science and Technology (KAIST) (Prof. Jeong Ik Lee, Prof. Yonghee Kim, and Prof. Yong Hoon Jeong) has suggested an innovative concept of a reactor cooled by supercritical state carbon dioxide (S-CO2). The core has long life (20 years) without refueling as well as inherent safety features. The S-CO2 Brayton cycle was proposed as a power conversion system to achieve a compact and lightweight module.

Due to the compact core and power conversion system, the entire system can be contained in a single module and be transported viaground or maritime transportation.

Throughout the world, interest is moving towards small modular reactor systems. Although most currently proposed designs have succeeded in decreasing the size, they have not been able to completely modularise the whole reactor.

To break theselimits, the supercritical CO2 Brayton cycle was chosen over the steam Rankine cycle asthe power generation cycle. Also, the proposed reactor is a gascooled reactor thatcan run without refueling for 20 years. The power generation cycle is integrated with the reactor to further modularise it.

To guarantee its safety over a long operational time, new designs that have notbeen used in conventional large reactors were adopted in the power generation system.

The development of the proposed reactor will allow nuclear power to contribute not only in power generation but also in energydependent industries like offshore plants, the heavy chemical industry, and the steel industry, which would ultimately reduce greenhouse gas emissions. Furthermore, an energy supply for extreme environments (polar areas, deserts, space, etc.) will be available for long periods of time.

Existing small modular reactor designs usuallyuse water as coolant and oxidised uranium as fuel. Although these may be good choices in making large reactors economical, there are economical limits when the capacity is reduced.

The presentresearch aims to overcome these issues by adopting a supercritical COcooled micro modular reactor (KAIST MMR) concept that uses a long period core, which runs for more than 20 years without refueling, with supercritical CO2 as coolant and uranium-nitride as fuel.

Also, by actively adopting the supercritical CO2 power system, designated as one of top 13 industry engine projects, a research team comprised of Prof. simplified the power conversion system and developed a new nuclear power system that can passively remove the decay heat in the case of reactor shutdown to avoid another Fukushima accident.

The team's main research achievement, the feasibility of downsising and modularising of nuclear power plants, was confirmed by designing the reactor core and power generation system in one vessel.

Also, in terms reactor design, uranium-nitride, suitable for longperiod lowenriched uranium fast reactors, was selected, andthe dynamic properties and variables for nuclear reactor control were designed and evaluated.

In the power generation system, the small sizing and high efficiency advantage of the supercritical CO2 power conversion system was actively utilised to create a very simple and high efficiency system.

Moreover, PCHE, a nextgeneration heat exchanger that adopts the semiconductor manufacturing process, was used, and thetechnical accomplishment of using radial urbomachinery, which is not used for large reactors, was achieved.

As seen in the Fukushima accident, nuclear reactors produce large amounts of decay heat even after shutdown, and if external power source is not provided, catastrophes can happen. To avoid such outcomes, the proposed KAIST MMR (Micro Modular Reactor) consists of a passive heat removal system that can cool the reactor with natural circulation in case of reactor shutdown.

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