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@ARTICLE{Reinecke:6798,
author = {Reinecke, E.-A. and Bentaib, A. and Kelm, S. and Jahn, W.
and Meynet, N. and Caroli, C.},
title = {{O}pen issues in the applicability of recombiner
experiments and modeling to reactor simulations},
journal = {Progress in nuclear energy},
volume = {52},
issn = {0149-1970},
address = {Amsterdam [u.a.]},
publisher = {Elsevier Science},
reportid = {PreJuSER-6798},
pages = {136 - 147},
year = {2010},
note = {Record converted from VDB: 12.11.2012},
abstract = {In the case of a severe accident in light-water reactors, a
large amount of hydrogen could be generated from the
reaction between steam and zirconium at high fuel clad
temperature and also from reactions of molten core debris
with concrete. The hydrogen generated will be released into
the containment atmosphere, and mixed with air and steam
possibly creating local flammable conditions. In order to
prevent loads resulting from a possible hydrogen combustion,
French and German reactor containments are equipped with
passive autocatalytic recombiners (PARs), which recombine
hydrogen with oxygen even at concentrations below the lower
flammability limit. In common PAR designs, catalytic
materials (platinum and palladium on ceramic washcoat) are
housed in a metallic structure whose purpose is to optimise
the circulation of gases in contact with the
catalyst.Numerous tests have been conducted in the past to
investigate PAR behaviour in situations representative of
severe accidents (Battelle Model Containment in Germany,
H2PAR and KALI-H2 in France, AECL Whiteshell Laboratories in
Canada, etc.). Furthermore, these tests demonstrated that,
provided special care is paid to the design and construction
of the catalysts, catalyst poisoning by materials such as
carbon monoxide, iodine and aerosols present in the
containment atmosphere will not fundamentally reduce the
effectiveness of the PARs.Some of the above-mentioned tests
also show that PARs could ignite the flammable gas mixture
at elevated hydrogen concentrations. These experimental
results need however to be corroborated by more detailed
experiments and by refined modelling of phenomena occurring
in PARs. In order to better characterise the PAR-induced
ignition risk, a series of dedicated experiments has started
at the REKO-3 facility located in Forschungszentrum Julich.
In parallel, a refined modelling of the recombiners has been
developed by IRSN and will be used to gain insights into the
phenomena occurring at the PAR catalyst plates.Furthermore,
previous tests indicated that the position of the
recombiners could have an impact on their overall
efficiency. The installation of PARs in the reactor building
is influenced by geometric and operational constraints. To
this end, numerical models were developed from the
experimental data for codes like COCOSYS or ASTEC in order
to optimise the PAR location and to assess the efficiency of
PAR implementation in different scenarios. However, these
models are usually simple (black-box type) and based on the
manufacturer's correlation to calculate the hydrogen
depletion rate. Recently, enhanced CFD models have been
developed at IRSN and Julich in order to take into account
phenomena such as the PAR location effect, gas mixture
ignition induced by PARs, and the oxygen starvation effect.
A new specifically instrumented facility is also under
construction at Julich to investigate these phenomena in
more detail. (C) 2009 Elsevier Ltd. All rights reserved.},
keywords = {J (WoSType)},
cin = {IEF-6},
ddc = {620},
cid = {I:(DE-Juel1)VDB814},
pnm = {Nukleare Sicherheitsforschung},
pid = {G:(DE-Juel1)FUEK404},
shelfmark = {Nuclear Science $\&$ Technology},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000273244600014},
doi = {10.1016/j.pnucene.2009.09.010},
url = {https://juser.fz-juelich.de/record/6798},
}
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