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Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)

This research aims to simulate the influences of flow parameters such as particles size, stream velocities, and outlet reducer diameter on the erosion rate for a reducer in light crude oil (C19H30)-solid (sand) flow system. A commercially accessible ANSYS Fluent 2020 R1 (Academic Version)-computatio...

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Main Authors:	Khirham, M. R., Supee, Aizuddin, Md. Kasmani, R., Mohamed Rashid, N., Sidek, A., Haladin, N. B., Zakaria, Z.
Format:	Article
Language:	English
Published:	ARQII Publication 2021
Subjects:	Q Science (General) TP Chemical technology
Online Access:	http://eprints.utm.my/id/eprint/97308/1/AizuddinSupee2021_SimulationofErosionRateinaReducer.pdf http://eprints.utm.my/id/eprint/97308/ https://arqiipubl.com/ojs/index.php/AMS_Journal/article/view/293
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id	my.utm.97308
record_format	eprints
spelling	my.utm.973082022-09-28T07:55:27Z http://eprints.utm.my/id/eprint/97308/ Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD) Khirham, M. R. Supee, Aizuddin Md. Kasmani, R. Mohamed Rashid, N. Sidek, A. Haladin, N. B. Zakaria, Z. Q Science (General) TP Chemical technology This research aims to simulate the influences of flow parameters such as particles size, stream velocities, and outlet reducer diameter on the erosion rate for a reducer in light crude oil (C19H30)-solid (sand) flow system. A commercially accessible ANSYS Fluent 2020 R1 (Academic Version)-computational fluid dynamics (CFD) was applied to numerically simulate the erosion rate in the reducer. Three separate models were used in the CFD approach called as a continuous flow modelling, Lagrangian particle tracking, and empirical erosion equation. The simulated parameters covered 100 - 500 μm particles size, 3 - 7 m/s stream velocities and 0.0762 - 0.1778 m outlet reducer diameter. It was found that the maximum erosion rate increased with the increasing size of the particles and stream velocities and decreased with the increasing of the outlet reducer diameter. For all the simulated parameters, the location of maximum erosion rate was found to be at the outlet location of the reducer except for the reducer with the diameter larger than 0.1270 m whereby it is located at the inlet location of reducer. ARQII Publication 2021 Article PeerReviewed application/pdf en http://eprints.utm.my/id/eprint/97308/1/AizuddinSupee2021_SimulationofErosionRateinaReducer.pdf Khirham, M. R. and Supee, Aizuddin and Md. Kasmani, R. and Mohamed Rashid, N. and Sidek, A. and Haladin, N. B. and Zakaria, Z. (2021) Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD). Applications of Modelling and Simulation, 5 (NA). pp. 156-165. ISSN 2600-8084 https://arqiipubl.com/ojs/index.php/AMS_Journal/article/view/293 NA
institution	Universiti Teknologi Malaysia
building	UTM Library
collection	Institutional Repository
continent	Asia
country	Malaysia
content_provider	Universiti Teknologi Malaysia
content_source	UTM Institutional Repository
url_provider	http://eprints.utm.my/
language	English
topic	Q Science (General) TP Chemical technology
spellingShingle	Q Science (General) TP Chemical technology Khirham, M. R. Supee, Aizuddin Md. Kasmani, R. Mohamed Rashid, N. Sidek, A. Haladin, N. B. Zakaria, Z. Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)
description	This research aims to simulate the influences of flow parameters such as particles size, stream velocities, and outlet reducer diameter on the erosion rate for a reducer in light crude oil (C19H30)-solid (sand) flow system. A commercially accessible ANSYS Fluent 2020 R1 (Academic Version)-computational fluid dynamics (CFD) was applied to numerically simulate the erosion rate in the reducer. Three separate models were used in the CFD approach called as a continuous flow modelling, Lagrangian particle tracking, and empirical erosion equation. The simulated parameters covered 100 - 500 μm particles size, 3 - 7 m/s stream velocities and 0.0762 - 0.1778 m outlet reducer diameter. It was found that the maximum erosion rate increased with the increasing size of the particles and stream velocities and decreased with the increasing of the outlet reducer diameter. For all the simulated parameters, the location of maximum erosion rate was found to be at the outlet location of the reducer except for the reducer with the diameter larger than 0.1270 m whereby it is located at the inlet location of reducer.
format	Article
author	Khirham, M. R. Supee, Aizuddin Md. Kasmani, R. Mohamed Rashid, N. Sidek, A. Haladin, N. B. Zakaria, Z.
author_facet	Khirham, M. R. Supee, Aizuddin Md. Kasmani, R. Mohamed Rashid, N. Sidek, A. Haladin, N. B. Zakaria, Z.
author_sort	Khirham, M. R.
title	Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)
title_short	Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)
title_full	Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)
title_fullStr	Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)
title_full_unstemmed	Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)
title_sort	simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (cfd)
publisher	ARQII Publication
publishDate	2021
url	http://eprints.utm.my/id/eprint/97308/1/AizuddinSupee2021_SimulationofErosionRateinaReducer.pdf http://eprints.utm.my/id/eprint/97308/ https://arqiipubl.com/ojs/index.php/AMS_Journal/article/view/293
_version_	1745562365309485056
score	13.189025

Simulation of erosion rate in a reducer for liquid-solid flow system using computational fluid dynamics (CFD)

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