Development and validation of CFD model for catalytic recombiner against experimental results

[Display omitted] •CFD model of PCRD needed to resolve flow fields & concentrations in closed geometry.•Reaction kinetics of each catalyst is different & is based on its type & morphology.•Kinetics of indigenous PCRD catalyst approximated as single step Arrhenius equation.•Based on this...

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Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2021-03, Vol.407, p.127216, Article 127216
Main Authors: Shukla, Vikram, Tyagi, Deepak, Gera, Bhuvaneshwar, Varma, Salil, Ganju, Sunil, Maheshwari, N.K.
Format: Article
Language:English
Subjects:
Computational fluid dynamics
Experimental validation
Hydrogen mitigation
Model development
Nuclear power plants
Reaction kinetics
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Summary:[Display omitted] •CFD model of PCRD needed to resolve flow fields & concentrations in closed geometry.•Reaction kinetics of each catalyst is different & is based on its type & morphology.•Kinetics of indigenous PCRD catalyst approximated as single step Arrhenius equation.•Based on this kinetics, a 3 D CFD model for the in house PCRD has been developed.•The CFD model for PCRD was then validated successfully against experimental results. The damage caused to the containment of a nuclear reactor because of generation of hydrogen and its subsequent combustion has been evident in the few major nuclear accidents witnessed by the world so far. Deployment of Passive Catalytic Recombiner Devices (PCRDs) is being widely used to mitigate the hydrogen risk. Experimental and numerical studies are underway around the world to characterise such recombiner devices. CFD studies involving PCRDs are important to spatially and temporally resolve flow fields and hydrogen concentrations inside reactor containment. In the present work, the reaction kinetics evolved earlier for a catalyst device developed in-house has been empirically approximated as a single step Arrhenius equation. This kinetics has been implemented as a CFD based PCRD model. The detailed model resolves individual catalyst plates and simulates the surface reaction occurring at the fluid–solid interface along with conjugate heat transfer, thermal radiation and buoyancy induced turbulent flows inside the multi-species gas mixture. Simulation results of the model have been compared against in-house experimental data. The validated CFD model will be a useful tool for accurate quantitative prediction of specific PCRD performance inside closed geometries.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2020.127216