Minimize fission power peaking factor in radial direction of water-cooled and water-moderated thermionic conversion reactor core

Alekseev, Pavel A.; Krotov, Aleksei; Ovcharenko, M. K.; Linnik, Vladimir Alekseevich

doi:10.26583/npe.2017.4.03

Cited by 1 publication

(1 citation statement)

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“…As it was shown in (Ushakov et al 1974, Alekseev et al 2017, due to the irregular heat generation along the height and radius of the core inherent to nuclear reactors (irregularity ratios may reach up to the value of 1.3) the thermionic converters are working in the conventional reactor-converters under the operation modes determined by their location in the reactor core which is not optimal both regarding their efficiency and the generated electrical power. Moreover, the total reactor capacity is limited due to the limitations on the maximum fuel temperature, and peripheral thermionic converters are operating under the strongly underloaded conditions which are also impacting their efficiency.…”

Section: Assessment Of Thermionic Converter Operation Efficiencymentioning

confidence: 99%

The concept of a thermionic reactor-converter with evaporative heat transfer

Alekseev¹,

Lazarenko²,

Linnik³

et al. 2022

NUCET

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As a result of the analytical studies of the designs of thermionic reactor-converters, four groups of technical solutions have been identified that differ in the method of heat transfer from the fuel to the emitters of the thermionic converter: one option with direct in-core transfer (combining the fuel cladding with the emitter) and three options with thermionic converters taken away from the reactor core, in which case the heat is removed either by heat pipes (common or individual for each fuel element) or is arranged based on the principle of a steam chamber. The article describes the advantages and disadvantages for each of these methods. It is shown that at present the most developed design remains the version with in-core power conversion and, in the future it will be based on the steam chamber since the ingress of gaseous fission products into the inter-electrode gap as well as the influence of fuel swelling on the inter-electrode gap size are excluded and it ensures constant temperature and heat flux density on the surface of all emitters of the thermionic converters, which makes it possible to select the optimal operating parameters for them. A model of a thermionic reactor-converter with a steam chamber containing a reactor core and a zone of thermionic converters has been developed in which the fuel element of the reactor core and the power generating channels of the thermionic converter are separated in space, covered with a capillary porous structure and interconnected by a honeycomb capillary porous spacer plate to provide for circulation of the liquid metal coolant and to let its steam pass through. Neutronic calculations have demonstrated the possibility of a duration for the reactor campaign in excess of ten years following the nuclear safety regulations when a gadolinium oxide coating is applied to the surface of the fuel rods and the reactor vessel in the area of the reactor core. The assessment of thermal and electrical parameters shows that, due to the constant temperature and heat flux density on the surface of all emitters and optimization of the power conversion process for all the thermionic converters, one can expect to reach the maximum efficiency of 20%.

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Section: Assessment Of Thermionic Converter Operation Efficiencymentioning

confidence: 99%