V.Ya. Kumaev scite author profile

The sources of impurities entering the sodium in fast reactors were investigated. The analysis showed that oxygen and hydrogen can be removed from the sodium by using cold traps in all operating regimes of a nuclear power plant as well as hot traps. An operating regime preventing hydrogen accumulation in the first-loop cold trap is proposed for a system purifying the first two loops. A computer code for calculating the impurity mass transfer is perfected. Test calculations showed that the procedure developed and the code are both serviceable. The deviation of the computational results from the experimental data is about 30% on average. For a built-in purification system, it is essential to develop a cold trap with a large impurity capacity. It is shown on the basis of experiments that such cold traps can in principle be developed. Thermohydraulic and mass-transfer codes must be developed in order to realize this possibility.Sodium-coolant purification systems in nuclear power plants with fast reactors must provide the required purity in all operating regimes taking account of all sources of impurities and must have the capacity required to handle the impurities accumulating in the purification system (it is permissible to replace the elements of the system during purification but the number of such replacements must be minimal). When significant contamination is present (routine maintenance, refueling, and accidental contamination), their capacity must ensure that impurities will be removed from the coolant as quickly as possible before the power reaches the operating level and the accumulation of suspensions in the first loop must be prevented.At the present stage of development of nuclear power, considering that safety, cost-effectiveness, and environmental compatibility must be improved, the requirements for the equipment in a nuclear power facility have been raised. Specifically, it has been decided that all systems with radioactive sodium be placed inside the reactor tank. This limits the dimensions of the first-loop systems. Therefore, the positive experience gained in placing purification systems outside the reactor tank cannot be fully utilized.For optimization, the purification characteristics were analyzed for the first loop. The analysis is based on evaluating the possible sources of impurities: their composition, amount, and rate of flow into the coolant in all possible operating regimes of a nuclear power plant. The relationship between the first-and second-loop purification systems and their effect on the distribution of impurities and the possibility and desirability of using not only cold traps but also other methods of purification, for example, hot traps, the structural implementation of the purification system, and the operation regime were all examined.The sources of impurities in systems with sodium coolant are oxygen, hydrogen (determining amount by mass and volume), products of corrosion of the structural materials, tritium, cesium if fuel-elements become depressurized, gaseous fission prod...

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Basic models and approximation for the engineering description of the kinetics of the oxide layer of steel in a flow of heavy liquid metal coolant under various oxygen conditions

Авдеенков¹,

Achakovsky²,

Ketlerov³

et al. 2020

NUCET

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The article presents the results of corrosion processes, kinetics and changes in the oxide layer modeling using MASKA-LM software complex. The complex is intended for a numerical simulation of three-dimensional non-stationary processes of mass transfer and interaction of impurity components in a heavy liquid metal coolant (HLMC: lead, lead-bismuth). The software complex is based on the numerical solution of coupled three-dimensional equations of hydrodynamics, heat transfer, formation and convective-diffusive transport of chemically interacting components of impurities. Examples of calculations of mass transfer processes and interaction of impurity components in HLMC, formation of protective oxide films on the surfaces of steels are given to justify the coolant technology.

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The calculational modeling of impurity mass transfer in NPP circuits with liquid metal coolant

Alexeev¹,

Kozlov²,

Kumaev³

et al. 2008

J. Phys.: Conf. Ser.

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Calculation of Impurity Mass Transfer in Cold Traps with Sodium Cooling

et al. 2015

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V.Ya. Kumaev

Sodium coolant purification systems for a nuclear power station equipped with a BN-1200 reactor

Studies validating a sodium purification system for fast reactors

Basic models and approximation for the engineering description of the kinetics of the oxide layer of steel in a flow of heavy liquid metal coolant under various oxygen conditions

The calculational modeling of impurity mass transfer in NPP circuits with liquid metal coolant

Calculation of Impurity Mass Transfer in Cold Traps with Sodium Cooling

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