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Biomass Conversion and Biorefinery

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12.05.2017 | Original Article

The impact of sorbent geometry on the sulphur adsorption under supercritical water conditions: a numerical study

verfasst von: Florentina Maxim, Bojan Niceno, Andrea Testino, Christian Ludwig

Erschienen in: Biomass Conversion and Biorefinery | Ausgabe 4/2017

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Abstract

A numerical model to show the impact of the adsorption bed geometry on the desulfurization process of wet biomass under supercritical water (SCW) gasification process has been developed. Three different geometries, straight channels (pipe), sharp-edged channels (sharp) and packed bed of particles (pebbles) have been considered for the sorbent bed. The influence of the flow patterns on the sulphur distribution inside the bed and on the saturation of the sorbent has been analysed. The results show that, when the flow is unidirectional with a parabolic profile, as in the pipe geometry, the adsorption process can be explained based on the 1D plug-flow model. In the case of more complex flow structures, when torus-shaped vortices appeared in the sharp or pebbles geometries, the 3D flow effects should be considered. The present work might provide useful information for the evaluation of sulphur sorption under SCW conditions. The models obtained by computational fluid dynamic, which are under experimental validation using neutron imaging, will help for the sorbent design and production by 3D printing techniques, which represent an advanced engineered tool to improve the process efficiency and sorbent material selection.

Vorheriger Artikel Assessment of agricultural crops and natural vegetation in Scotland for energy production by anaerobic digestion and hydrothermal liquefaction

Nächster Artikel Gasification characteristics of histidine and 4-methylimidazole under supercritical water conditions

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Peng G (2015) Methane production from microalgae via continuous catalytic supercritical water gasification: development of catalysts and sulfur removal techniques. EPFL thesis No. 6740, 2015.

Peng G, Ludwig C, Vogel F Catalytic supercritical water gasification: interaction of sulfur with ZnO and the ruthenium catalyst. Appl Catal B Environ. doi:10.1016/j.apcatb. 2016.09.011

Bagnoud-Velasquez M, Brandenberger M, Vogel F, Ludwig C (2014) Continuous catalytic hydrothermal gasification of algal biomass and case study on toxicity of aluminum as a step toward effluents recycling. Catal Today 223:35–43. doi:10.1016/j.cattod. 2013.12.001 CrossRef

Waldner MH, Vogel F (2005) Renewable production of methane from woody biomass by catalytic hydrothermal gasification. Ind Eng Chem Res 44(13):4543–4551. doi:10.1021/ie050161h CrossRef

Qingxia Z (2009) The use of microalgae for energy and biofuel (biodiesel) production and CO2 fixation – phase 3: characterization of biomass feedstock. Project ENAC final report. EPFL, Lausanne

Huang HY, Long RQ, Yang RT (2001) A highly sulfur resistant Pt-Rh/TiO2/Al2O3 storage catalyst for NOx reduction under lean-rich cycles. Applied Catalysis B-Environmental 33(2):127–136. doi:10.1016/s0926-3373(01)00176-x CrossRef

Navarro RM, Pawelec B, Trejo JM, Mariscal R, Fierro JLG (2000) Hydrogenation of aromatics on sulfur-resistant PtPd bimetallic catalysts. J Catal 189(1):184–194. doi:10.1006/jcat. 1999.2693 CrossRef

Dreher M, Steib M, Nachtegaal M, Wambach J, Vogel F (2014) On-stream regeneration of a sulfur-poisoned ruthenium-carbon catalyst under hydrothermal gasification conditions. ChemCatChem 6(2):626–633. doi:10.1002/cctc. 201300791 CrossRef

Ahmed I, Jhung SH (2016) Adsorptive desulfurization and denitrogenation using metal-organic frameworks. J Hazard Mater 301:259–276. doi:10.1016/j.jhazmat. 2015.08.045 CrossRef

10.

Kaufman Rechulski MD (2012) Catalysts for high temperature gas cleaning in the production of synthetic natural gas from biomass. EPF Lausanne, PhD Thesis no. 5484.

11.

Elseviers WF, Verelst H (1999) Transition metal oxides for hot gas desulphurisation. Fuel 78(5):601–612. doi:10.1016/s0016-2361(98)00185-9 CrossRef

12.

Ates A, Azimi G, Choi K-H, Green WH, Timko MT (2014) The role of catalyst in supercritical water desulfurization. Appl Catal B Environ 147(0):144–155. doi:10.1016/j.apcatb. 2013.08.018 CrossRef

13.

Yang H, Cahela DR, Tatarchuk BJ (2008) A study of kinetic effects due to using microfibrous entrapped zinc oxide sorbents for hydrogen sulfide removal. Chem Eng Sci 63(10):2707–2716. doi:10.1016/j.ces. 2008.02.025 CrossRef

14.

White FM (1999) Fluid mechanics. McGraw-Hill series in mechanical engineering, 4th edn. WCB McGraw-Hill, Boston

15.

Cybulksi A (1998) Structured catalysts and reactors. Chemical industries, vol vol 71. Basel etc., Dekker, New York

16.

Schildhauer TJ, Newson E, Wokaun A (2009) Closed cross flow structures—improving the heat transfer in fixed bed reactors by enforcing radial convection. Chem Eng Process 48(1):321–328. doi:10.1016/j.cep. 2008.04.009 CrossRef

17.

Ferziger JH, Peri CM (2002) Computational methods for fluid dynamics, 3rd, rev. edn. Springer, Berlin

18.

Guardo A, Coussirat M, Recasens F, Larrayoz MA, Escaler X (2006) CFD study on particle-to-fluid heat transfer in fixed bed reactors: convective heat transfer at low and high pressure. Chem Eng Sci 61(13):4341–4353. doi:10.1016/j.ces. 2006.02.011 CrossRef

19.

Guardo A, Coussirat M, Recasens F, Larrayoz MA, Escaler X (2007) CFD studies on particle-to-fluid mass and heat transfer in packed beds: free convection effects in supercritical fluids. Chem Eng Sci 62(18–20):5503–5511. doi:10.1016/j.ces. 2007.02.040 CrossRef

20.

Augier F, Laroche C, Brehon E (2008) Application of computational fluid dynamics to fixed bed adsorption calculations: effect of hydrodynamics at laboratory and industrial scale. Sep Purif Technol 63(2):466–474. doi:10.1016/j.seppur. 2008.06.007 CrossRef

21.

Duggirala RK, Roy CJ, Dhage P, Tatarchuk BJ (2015) Joint numerical-experimental investigation of enhanced chemical reactivity in microfibrous materials for desulfurization. Journal of Fluids Engineering-Transactions of the Asme 137(3). doi:10.1115/1.4028602

22.

Verbruggen SW, Keulemans M, van Walsem J, Tytgat T, Lenaerts S, Denys S (2016) CFD modeling of transient adsorption/desorption behavior in a gas phase photocatalytic fiber reactor. Chem Eng J 292:42–50. doi:10.1016/j.cej. 2016.02.014 CrossRef

23.

Marocco L, Mora A (2013) CFD modeling of the dry-sorbent-injection process for flue gas desulfurization using hydrated lime. Sep Purif Technol 108:205–214. doi:10.1016/j.seppur. 2013.02.012 CrossRef

24.

Thomas WJ, Crittenden B (1998) 5 - Processes and cycles. In: Thomas WJ, Crittenden B (eds) Adsorption Technology & Design. Butterworth-Heinemann, Oxford, pp 96–134. Doi: 10.1016/B978-075061959-2/50006-9

25.

Walton MS (1960) Molecular diffusion rates in supercritical water vapor estimated from viscosity data. Am J Sci 258(6):385–401. doi:10.2475/ajs. 258.6.385 CrossRef

26.

Taylor LT (1996) Supercritical fluid extraction. Wiley, New York etc

27.

Thomas WJ, Crittenden B (1998) 4 - Rates of adsorption of gases and vapours by porous media. In: Thomas WJ, Crittenden B (eds) Adsorption Technology & Design. Butterworth-Heinemann, Oxford, pp 66–95. doi: 10.1016/B978-075061959-2/50005-7

28.

Foo KY, Hameed BH (2010) Insights into the modeling of adsorption isotherm systems. Chem Eng J 156(1):2–10. doi:10.1016/j.cej. 2009.09.013 CrossRef

Titel: The impact of sorbent geometry on the sulphur adsorption under supercritical water conditions: a numerical study
verfasst von: Florentina Maxim
Bojan Niceno
Andrea Testino
Christian Ludwig
Publikationsdatum: 12.05.2017
Verlag: Springer Berlin Heidelberg
Erschienen in: Biomass Conversion and Biorefinery / Ausgabe 4/2017
Print ISSN: 2190-6815
Elektronische ISSN: 2190-6823
DOI: https://doi.org/10.1007/s13399-017-0265-7

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