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Multi-Purpose Hydrogen Isotopes Separation Plant Design

H.A. Boniface, N.V. Gnanapragasam, D.K. Ryland, S. Suppiah, I. Castillo

Fusion Science and Technology / Volume 67 / Number 2 / March 2015 / Pages 258-261

Proceedings of TRITIUM 2013 / dx.doi.org/10.13182/FST14-T5

First Online Publication:January 14, 2015
Updated:February 27, 2015

There is a potential interest at CRL to detritiate moderately tritiated light water and to reclaim tritiated, downgraded heavy water. With only a few limitations, a single CECE process configuration can be designed to remove tritium from heavy water or light water and upgrade heavy water. Such a design would have some restrictions on the nature of the feed-stock and tritium product, but could produce essentially tritium-free light or heavy water that is chemically pure. The extracted tritium is produced as a small quantity of tritiated heavy water. The overall plant capacity is fixed by the total amount of electrolysis and volume of catalyst. In this proposal, with 60 kA of electrolysis a throughput of 15 kg·h−1 light water for detritiation, about 4 kg·h−1 of heavy water for detritiation and about 27 kg·h−1 of 98% heavy water for upgrading can be processed. Such a plant requires about 1,000 L of AECL isotope exchange catalyst. The general design features and details of this multi-purpose CECE process are described in this paper, based on some practical choices of design criteria. In addition, we outline the small differences that must be accommodated and some compromises that must be made to make the plant capable of such flexible operation.