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Published: 2017-06-30
Abstract Views: 180
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DOI: https://doi.org/10.53747/jnst.v7i2.105
Issue
Vol. 7 No. 2 (2017)
Section
Articles
How to Cite
M., S., P., K., J., K., & H., K. (2017). Application of reverse osmosis at NPP and verification of the process for primary coolant treatment in temelín nuclear power. Nuclear Science and Technology, 7(2), 1-7. https://doi.org/10.53747/jnst.v7i2.105

Application of reverse osmosis at NPP and verification of the process for primary coolant treatment in temelín nuclear power

Skala M.1, Kůs P.1, Kotowski J.1, Kořenková H.1
1 Research Centre Řež, Husinec – Řež 130, CZ -250 68, Czech Republic

Main Article Content

Abstract

Drained primary coolant from nuclear power plants containing boric acid is currently treated in the system of evaporators and by ion exchangers. Reverse osmosis as an alternative process to evaporator was investigated. Using reverse osmosis, the feed primary coolant is separated into two output streams: retentate and permeate. Retentate stream consists of concentrated boric acid solution together with other components, while permeate stream consists of purified water. In the first phase of the project the reverse osmosis modules from several manufactures were tested on a batch laboratory apparatus. Certain modifications to the pH of the feed solution were needed to enable the tested membranes to concentrate the H3BO3 in the retentate stream, separate from the pure water in the permeate stream. Furthermore, the separation capability for other compounds present in primary coolant such as K, Li or NH3 were evaluated. In the final phase of the project the pilot-plant unit of reverse osmosis was tested in nuclear power plant Temelín. It was installed in the Special Purification System SVO-6 for the regeneration of boric acid. The aim of the tests performed in Temelín nuclear power plant was to verify possible use of reverse osmosis for the treatment of primary coolant.

Article Details

Keywords

Reverse osmosis, H₃BO₃, primary coolant, nuclear power plants

References

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