SPIDER dedicated cooling plant has to remove up to 10 MW thermal power from in-vessel components and auxiliary systems. The circuit is characterized by three main heat transfer systems: primary, secondary and tertiary systems. The primary system is made of four circuits, with only three operating so far, these are called PC01, PC02 and PC03. These three circuits respectively cool SPIDER power supplies and the beam source components using ultrapure water. During 2019 SPIDER experimental campaigns, it was observed that electrical resistivity of water degraded considerably and more quickly (~25 MOhm cm h- 1 in PC01) than estimated by design. To overcome this issue, water had to be restored very frequently to maintain the desired characteristics and avoid possible detrimental leakage currents throughout the circuit. The reason for this severe water degradation has to be better understood before issues such as abrupt failures may arise. This work presents a preliminary analysis of the two main circuits (PC01 and PC02) where an estimation of water degradation induced by general corrosion of stainless steels and copper components was made. This preliminary estimation showed that PC01 could be more prone to general corrosion than PC02; however, the rate of water conductivity increase was 5.3 times smaller than that observed during experiments in 2019 and 2020.
Investigation of corrosion-erosion phenomena in the primary cooling system of SPIDER
Cavallini C.; Dalla Palma M.; Fellin F.; Gasparrini C.; Tinti P.; Zamengo A.; Zaupa M.
Journal:
Fusion engineering and design 166 pp. 112271-1 - 112271-4
Year:
2021
ISTP Authors: Mauro Dalla Palma
Keywords: Corrosion-erosion phenomena, Heat transfer systems, Drying system, Ultrapure water, Water electrical conductivity, Water electrical resistivity, ITER, SPIDER, Neutral beam injectors, Cooling circuits
Research Activitie: JOURNAL ARTICLES
ID | 444838 |
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DOI | 10.1016/j.fusengdes.2021.112271 |
PRODUCT TYPE | Journal Article |
LAST UPDATE | 2022-02-11T11:53:31Z |