Pretest in forced circulation molten salt heat transfer loop: Studies with thermia‐B

Molten salts have potential application as an efficient heat transfer medium in a primary and secondary heat exchanger in high temperature next‐generation nuclear power plant. Thermal hydraulic studies are vital for reliable and cost‐effective design of the nuclear power plant. Therefore heat transf...

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Bibliographic Details
Published in:Heat transfer, Asian research Asian research, 2019-12, Vol.48 (8), p.4354-4372
Main Authors: Gajbhiye, Bhavesh D., C. S., Sona, Mathpati, Channamallikarjun S., Patwardhan, Ashwin W., Borgohain, Ananta, Maheshwari, Naresh K.
Format: Article
Language:English
Subjects:
Convective heat transfer
Fluid dynamics
Fluid flow
Heat exchangers
Heat transfer
High temperature
Hydraulics
molten salt heat transfer loop
Molten salts
Nuclear electric power generation
Nuclear power plants
Nusselt number
Prandtl number
Reynolds number
thermic fluid
turbulent flow
wall heat flux
Working fluids
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Summary:Molten salts have potential application as an efficient heat transfer medium in a primary and secondary heat exchanger in high temperature next‐generation nuclear power plant. Thermal hydraulic studies are vital for reliable and cost‐effective design of the nuclear power plant. Therefore heat transfer study of molten salts will play a vital role in this area. In this work, an experimental system was designed to study thermal hydraulics of the molten salt system up to 700°C. This work describes the pretest results of the experimental facility for extremely corrosive molten fluoride salts with a simulant thermia‐B as the working fluid. In the present work, the details of the system are discussed and thermal‐hydraulic data for heat transfer fluid thermia‐B has been presented. Experiments were carried out at Reynolds number in the range of 4500 to 40 500 and Prandtl number in the range of 34 to 144. Effect of Reynolds number, melting tank temperature, and heat input to test section on forced convective heat transfer was studied under turbulent conditions. Comparison of the experimental data with different empirical correlations has been presented.
ISSN:1099-2871
1523-1496
DOI:10.1002/htj.21596