Your search keyword '"Borda, Gilles"' showing total 8 results

1. Simulation of liquid–liquid interfaces in porous media

Author

García, Edder J., Boulet, Pascal, Denoyel, Renaud, Anquetil, Jérôme, Borda, Gilles, and Kuchta, Bogdan

Published

2016

2. Innovative Precipitation in Emulsion Process: Toward a Non-nuclear Industrial Application

Author

Ollivier, Marion, Flouret, Julie, Borda, Gilles, and Charton, Sophie

Published

2016

3. Actinides oxalate precipitation in emulsion modeling: From the drop scale to the industrial process

Author

Charton, Sophie, Kacem, Amine, Amokrane, Abdenour, Borda, Gilles, Puel, François, and Klein, Jean-Paul

Published

2013

4. Axial dispersion in pulsed disk and doughnut columns: A unified law

Author

Charton, Sophie, Duhamet, Jean, Borda, Gilles, and Ode, Denis

Published

2012

5. Use of a pulsed column contactor as a continuous oxalate precipitation reactor

Author

Borda, Gilles, Brackx, Emmanuelle, Boisset, Laurence, Duhamet, Jean, and Ode, Denis

Published

2011

6. Formalization of the kinetics for autocatalytic dissolutions. Focus on the dissolution of uranium dioxide in nitric medium

Author

Charlier Florence, Canion Delphine, Gravinese Anthony, Magnaldo Alastair, Lalleman Sophie, Borda Gilles, and Schaer Éric

Subjects

Nuclear engineering. Atomic power, TK9001-9401

Abstract

Uranium dioxide dissolution in nitric acid is a complex reaction. On the one hand, the dissolution produces nitrous oxides (NOX), which makes it a triphasic reaction. On the other hand, one of the products accelerates the kinetic rate; the reaction is hence called autocatalytic. The kinetics for these kinds of reactions need to be formalized in order to optimize and design innovative dissolution reactors. In this work, the kinetics rates have been measured by optical microscopy using a single particle approach. The advantages of this analytical technique are an easier management of species transport in solution and a precise following of the dissolution rate. The global rate is well described by a mechanism considering two steps: a non-catalyzed reaction, where the catalyst concentration has no influence on the dissolution rate, and a catalyzed reaction. The mass transfer rate of the catalyst was quantified in order to discriminate when the reaction was influenced by catalyst accumulated in the boundary layer or uncatalyzed. This first approximation described well the sigmoid dissolution curve profile. Moreover, experiments showed that solutions filled with catalyst proved to lose reactivity over time. Results pointed out that the higher the liquid-gas exchanges, the faster the kinetic rate decreases with time. Thus, it was demonstrated, for the first time, that there is a link between catalyst and nitrous oxides. The outcome of this study leads to new ways for improving the design of dissolvers. Gas-liquid exchanges are indeed a lever to impact dissolution rates. Temperature and catalyst concentration can be optimized to reduce residence times in dissolvers.

Published

2017

7. Modélisation de la dissolution de l'UO$_2$ en milieu nitrique, vers un modèle macroscopique des réacteurs de dissolution

Author

Charlier, Florence, Canion, Delphine, MARC, Philippe, Magnaldo, Alastair, Lalleman, Sophie, Borda, Gilles, Schaer, Eric, amplexor, amplexor, Département RadioChimie et Procédés (DRCP), CEA-Direction des Energies (ex-Direction de l'Energie Nucléaire) (CEA-DES (ex-DEN)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Département de Technologies du Cycle du combustible (DTEC), Laboratoire Réactions et Génie des Procédés (LRGP), Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), EFCE (European Federation of Chemical Engineering) & ESBES (European Society of Biochemical Engineering Sciences) & SFGP (Société Française de Génie des Procédés), Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Faculté des Sciences et Technologies [Université de Lorraine] (FST ), and Université de Lorraine (UL)

Subjects

[CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistry, [PHYS.NUCL] Physics [physics]/Nuclear Theory [nucl-th], [CHIM.GENI]Chemical Sciences/Chemical engineering, [PHYS.NUCL]Physics [physics]/Nuclear Theory [nucl-th], [PHYS.NEXP] Physics [physics]/Nuclear Experiment [nucl-ex], [CHIM]Chemical Sciences, [CHIM.CATA]Chemical Sciences/Catalysis, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], [CHIM.RADIO]Chemical Sciences/Radiochemistry

Abstract

International audience; Dissolution is a key step in several industrial processes. It is especially a milestone of the head-end of manyhydrometallurgical processes. For example, in recycling of spent nuclear fuel, the solubilization of the chemical elementsis essential before performing the liquid-liquid extraction steps to separate reusable material and final waste. One of themost complex scenarios is that of heterogeneous autocatalytic reactions. Today, there are few satisfying models forthese cases due to a lack of comprehension of their mechanisms.We focus here on the dissolution of uranium dioxide in nitric medium. In order to propose optimized processes fordissolution, this study aims at better understanding the chemical, physico-chemical and hydrodynamic phenomena ofsuch reactions. This study is also part of a modeling approach aiming, on one hand, at expressing the intrinsic reactionrates and describing the physico-chemical phenomena at interfaces and, on the other hand, at developing a generalmodel for dissolution reactors.Optical microscopy observation confirmed the highly autocatalytic nature of the reaction and led to measurements, forthe very first time, of "true" chemical kinetics of the reaction. The acid attack of sintering-manufactured solids occursthrough preferential attack sites. It develops cracks in the solids that can lead to their cleavage. This inhomogeneousattack is made possible by the establishment of bubbling in the cracks which allows periodic renewal of the reagents andthus maintains the reaction within the cracks. This point is a key component of the mechanism: a strong link among thedevelopment of cracks, bubbling through the cracks, and overall dissolution kinetics is demonstrated in this work.A model coupling material balance to the structural evolution of the solid and liquid phase compositions, and taking intoaccount the interfacial transport is proposed. The simulations based on this model are close to the experimentalobservations, and allow to replicate the effect of various reaction parameters for the very first time, such as the reductionof overall kinetics when turbulence increases.

Published

2017

8. Modelling of Autocatalytic Heterogeneous Dissolution Reactions. Application to Uranium Dioxide Dissolution.

Author

Lalleman, Sophie, Charlier, Florence, Marc, Philippe, Magnaldo, Alastair, Borda, Gilles, and Schaer, Eric

Subjects

AUTOCATALYSIS, HETEROGENEOUS catalysis, DISSOLUTION (Chemistry), URANIUM oxides, REACTOR fuel reprocessing

Abstract

This study deals with the modelling of uranium dioxide dissolution in nitric medium, which is a key step at the head-end of nuclear fuel reprocessing. This particular dissolution is triphasic (involving solid uranium dioxide, liquid nitric acid and gaseous nitrogen oxide products), and autocatalytic (accelerated by an unidentified reaction product), so that numerous coupled phenomena must be taken into account for a better understanding, modelling and optimization of dissolution reactors. The kinetic parameters were determined for both the catalyzed and non-catalyzed reactions. The kinetic study was realized thanks to a single particle approach and the reaction rates were measured by optical microscopy, thanks to a specific lab-scale device which ensures the absence of any external limitation. Gas-liquid exchanges were shown to have a great impact on the catalyst concentration in the reactor, and evidence of a volume reaction between the dissolution gases (nitrogen oxides) and the catalyst were found. The kinetics of this reaction was estimated from the experimental results. A model was then developed to describe and simulate these phenomena: it takes into account species transport between the particles surface and the bulk media, UO2 dissolution kinetics, the reaction between the dissolution gases and the catalyst, as well as the transport of these gases to the liquidgas interface. It was shown to be in good agreement with experimental results, at both microscopic and macroscopic scales. Dissolution modelling has now to be upgraded by integrating fragmentation and bubbling models. [ABSTRACT FROM AUTHOR]

Published

2019