The University of Southampton
×
Filter your search:
University of Southampton Institutional Repository

A platinum-coated staggered reactor to intensify lean hydrogen/air combustion: a large eddy simulation study

A platinum-coated staggered reactor to intensify lean hydrogen/air combustion: a large eddy simulation study
A platinum-coated staggered reactor to intensify lean hydrogen/air combustion: a large eddy simulation study
Catalytic-aided combustion has been proven effective for premixed hydrogen/air mixtures, particularly under lean to ultra-lean conditions. However, minimising the required catalyst sets a significant challenge because noble metals with high catalytic activity are rare and expensive. Therefore, this study aims to intensify the catalytic combustion process by investigating a non-planar reactor comprising an array of platinum-coated half- and full-cylinders through large eddy simulation. A premixed mixture with a fuel-lean equivalence ratio of 0.15 and an incoming Reynolds number of 3500 based on hydraulic diameter is used. For comparison, a planar reactor without cylinders is also studied under the same operating conditions and with the same amount of platinum-coated surface area. The simulation employs the turbulent kinetic energy sub-grid model and the eddy dissipation concept to model the turbulent catalytic reacting flow. The discrete ordinate model is used to account for radiation heat transfer in the catalytic process. Numerical simulations are validated against experimental results prior to analysis. The findings indicate that the placement of cylinders along the reactor length enhances convective mass transfer and intensifies catalytic combustion, resulting in effective combustion over a smaller catalytic surface. Compared to planar models, non-planar reactors demonstrate a much better H2 conversion efficiency throughout the reactor length, saving nearly 62.5 % of the catalyst.
0016-2361
Mondal, Md Nur Alam
2038cb40-725f-4fe5-ab53-01f0fa3c2259
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Jackson, S. David
5af45717-677e-4143-a7fc-31401b163442
Paul, Manosh C.
fbb523c5-ff1d-4609-8327-0175d3c9e5b3
Mondal, Md Nur Alam
2038cb40-725f-4fe5-ab53-01f0fa3c2259
Karimi, Nader
620646d6-27c9-4e1e-948f-f23e4a1e773a
Jackson, S. David
5af45717-677e-4143-a7fc-31401b163442
Paul, Manosh C.
fbb523c5-ff1d-4609-8327-0175d3c9e5b3

Mondal, Md Nur Alam, Karimi, Nader, Jackson, S. David and Paul, Manosh C. (2025) A platinum-coated staggered reactor to intensify lean hydrogen/air combustion: a large eddy simulation study. Fuel, 381 (Pt. B), [133386]. (doi:10.1016/j.fuel.2024.133386).

Record type: Article

Abstract

Catalytic-aided combustion has been proven effective for premixed hydrogen/air mixtures, particularly under lean to ultra-lean conditions. However, minimising the required catalyst sets a significant challenge because noble metals with high catalytic activity are rare and expensive. Therefore, this study aims to intensify the catalytic combustion process by investigating a non-planar reactor comprising an array of platinum-coated half- and full-cylinders through large eddy simulation. A premixed mixture with a fuel-lean equivalence ratio of 0.15 and an incoming Reynolds number of 3500 based on hydraulic diameter is used. For comparison, a planar reactor without cylinders is also studied under the same operating conditions and with the same amount of platinum-coated surface area. The simulation employs the turbulent kinetic energy sub-grid model and the eddy dissipation concept to model the turbulent catalytic reacting flow. The discrete ordinate model is used to account for radiation heat transfer in the catalytic process. Numerical simulations are validated against experimental results prior to analysis. The findings indicate that the placement of cylinders along the reactor length enhances convective mass transfer and intensifies catalytic combustion, resulting in effective combustion over a smaller catalytic surface. Compared to planar models, non-planar reactors demonstrate a much better H2 conversion efficiency throughout the reactor length, saving nearly 62.5 % of the catalyst.

Text
1-s2.0-S0016236124025353-main - Version of Record
Available under License Creative Commons Attribution.
Download (8MB)

More information

Accepted/In Press date: 5 October 2024
e-pub ahead of print date: 9 October 2024
Published date: 1 February 2025

Identifiers

Local EPrints ID: 510009
URI: http://eprints.soton.ac.uk/id/eprint/510009
DOI: doi:10.1016/j.fuel.2024.133386
ISSN: 0016-2361
PURE UUID: 4d2d581b-5bdd-45ae-ad9d-031f48793d12
ORCID for Nader Karimi: ORCID iD orcid.org/0000-0002-4559-6245

Catalogue record

Date deposited: 13 Mar 2026 17:38
Last modified: 14 Mar 2026 03:30

Export record

Altmetrics

Contributors

Author: Md Nur Alam Mondal
Author: Nader Karimi ORCID iD
Author: S. David Jackson
Author: Manosh C. Paul

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Library staff additional information
Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×