Abstract
The aim of this experimental investigation is to obtain information on the temperature fields and heat transfer coefficients during flow of liquid-metal coolant in models simulating an elementary cell in the core of a liquid heavy metal cooled fast-neutron reactor. Two design versions for spacing fuel rods in the reactor core were considered. In the first version, the fuel rods were spaced apart from one another using helical wire wound on the fuel rod external surface, and in the second version spacer grids were used for the same purpose. The experiments were carried out on the mercury loop available at the Moscow Power Engineering Institute National Research University’s Chair of Engineering Thermal Physics. Two experimental sections simulating an elementary cell for each of the fuel rod spacing versions were fabricated. The temperature fields were investigated using a dedicated hinged probe that allows temperature to be measured at any point of the studied channel cross section. The heat-transfer coefficients were determined using the wall temperature values obtained at the moment when the probe thermocouple tail end touched the channel wall. Such method of determining the wall temperature makes it possible to alleviate errors that are unavoidable in case of measuring the wall temperature using thermocouples placed in slots milled in the wall. In carrying out the experiments, an automated system of scientific research was applied, which allows a large body of data to be obtained within a short period of time. The experimental investigations in the first test section were carried out at Re = 8700, and in the second one, at five values of Reynolds number. Information about temperature fields was obtained by statistically processing the array of sampled probe thermocouple indications at 300 points in the experimental channel cross section. Reach material has been obtained for verifying the codes used for calculating velocity and temperature fields in channels with an intricately shaped cross section simulating the flow pass sections for liquid-metal coolants cooling the core of nuclear reactors.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
A. A. Goverdovskii, S. G. Kalyakin, and V. I. Rachkov, “The alternative strategies of the development of the nuclear power industry in the 21st century,” Therm. Eng. 61 (5), 319 (2014).
A. G. Glazkov, V. N. Leonov, V. V. Orlov, A. G. SilaNovitskii, V. S. Smirnov, A. I. Filin, and V. S. Tsikunov, “The BREST reactor and the in-plant nuclear fuel cycle,” At. Energiya 103 (1), 15–21 (2007).
A. V. Lopatkin, V. V. Orlov, I. B. Lukasevich, I. V. Zaiko, and I. Kh. Ganev, “The capacities of the BREST reactors and the transmutation fuel cycle under the conditions of implementing the modern plans for developing the nuclear power industry,” At. Energiya 103 (1), 21–28 (2007).
V. I. Rachkov, M. N. Arnol’dov, A. D. Efanov, S. G. Kalyakin, F. A. Kozlov, N. I. Loginov, Yu. I. Orlov, and A. P. Sorokin, “Use of liquid metals in nuclear and thermonuclear engineering, and in other innovative technologies,” Therm. Eng. 61 (5), 337 (2014). DOI: 10.1134/S0040363614050087.
A Handbook on Thermal–Hydraulic Calculations in Nuclear Power Engineering, Ed. by P. L. Kirillov (IzdAT, Moscow, 2014) [in Russian].
Author information
Authors and Affiliations
Corresponding author
Additional information
Original Russian Text © I.A. Belyaev, L.G. Genin, S.G. Krylov, A.O. Novikov, N.G. Razuvanov, V.G. Sviridov, 2015, published in Teploenergetika.
Rights and permissions
About this article
Cite this article
Belyaev, I.A., Genin, L.G., Krylov, S.G. et al. Experimental investigations of heat transfer and temperature fields in models simulating fuel assemblies used in the core of a nuclear reactor with a liquid heavy-metal coolant. Therm. Eng. 62, 645–651 (2015). https://doi.org/10.1134/S0040601515090025
Published:
Issue Date:
DOI: https://doi.org/10.1134/S0040601515090025