Study for nanomaterial transportation within the channel with apply of complicated turbulator

Pengfei Wang; Xiuhui Diao; Mahmoud M. Selim

doi:10.1142/S0217984922500932

Study for nanomaterial transportation within the channel with apply of complicated turbulator

Pengfei Wang
, Xiuhui Diao
, Mahmoud M. Selim

Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

Hybrid nanomaterial exergy drop and thermal manners were examined in this work with involving the porous media in middle part of the pipe. Moreover, to augment the rotational velocity, disturber device was applied in test section. The two sections near the entrance and outlet were in absence of disturber and porous zone because of importance of shun of backflow and reach of fully developed condition. Laminar flow with assume of homogeneous mixture for hybrid nanomaterial (Al2O3 + MWCNT and water) results in final model with involving the non-Darcy approach for permeable media. Finite volume approach was applied for achieving the outputs which are exergy loss (Xd) and hydrothermal behavior. Use of additives results in lower Xd more than 7.7% when Re = 10 Da = 1e2. With growth of Re, the Xd declines around a bit greater than 19%. Utilizing higher permeability allows the hybrid nanofluid moves quicker and exergy loss augments less than 10.5%.

Original language	English
Article number	2250093
Journal	Modern Physics Letters B
Volume	36
Issue number	20
DOIs	https://doi.org/10.1142/S0217984922500932
State	Published - 20 Jul 2022

Keywords

Disturber device
hybrid nanomaterial
laminar flow
numerical method
permeability

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10.1142/S0217984922500932

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title = "Study for nanomaterial transportation within the channel with apply of complicated turbulator",

abstract = "Hybrid nanomaterial exergy drop and thermal manners were examined in this work with involving the porous media in middle part of the pipe. Moreover, to augment the rotational velocity, disturber device was applied in test section. The two sections near the entrance and outlet were in absence of disturber and porous zone because of importance of shun of backflow and reach of fully developed condition. Laminar flow with assume of homogeneous mixture for hybrid nanomaterial (Al2O3 + MWCNT and water) results in final model with involving the non-Darcy approach for permeable media. Finite volume approach was applied for achieving the outputs which are exergy loss (Xd) and hydrothermal behavior. Use of additives results in lower Xd more than 7.7\% when Re = 10 Da = 1e2. With growth of Re, the Xd declines around a bit greater than 19\%. Utilizing higher permeability allows the hybrid nanofluid moves quicker and exergy loss augments less than 10.5\%.",

keywords = "Disturber device, hybrid nanomaterial, laminar flow, numerical method, permeability",

author = "Pengfei Wang and Xiuhui Diao and Selim, \{Mahmoud M.\}",

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T1 - Study for nanomaterial transportation within the channel with apply of complicated turbulator

AU - Wang, Pengfei

AU - Diao, Xiuhui

AU - Selim, Mahmoud M.

N1 - Publisher Copyright: © World Scientific Publishing Company.

PY - 2022/7/20

Y1 - 2022/7/20

N2 - Hybrid nanomaterial exergy drop and thermal manners were examined in this work with involving the porous media in middle part of the pipe. Moreover, to augment the rotational velocity, disturber device was applied in test section. The two sections near the entrance and outlet were in absence of disturber and porous zone because of importance of shun of backflow and reach of fully developed condition. Laminar flow with assume of homogeneous mixture for hybrid nanomaterial (Al2O3 + MWCNT and water) results in final model with involving the non-Darcy approach for permeable media. Finite volume approach was applied for achieving the outputs which are exergy loss (Xd) and hydrothermal behavior. Use of additives results in lower Xd more than 7.7% when Re = 10 Da = 1e2. With growth of Re, the Xd declines around a bit greater than 19%. Utilizing higher permeability allows the hybrid nanofluid moves quicker and exergy loss augments less than 10.5%.

AB - Hybrid nanomaterial exergy drop and thermal manners were examined in this work with involving the porous media in middle part of the pipe. Moreover, to augment the rotational velocity, disturber device was applied in test section. The two sections near the entrance and outlet were in absence of disturber and porous zone because of importance of shun of backflow and reach of fully developed condition. Laminar flow with assume of homogeneous mixture for hybrid nanomaterial (Al2O3 + MWCNT and water) results in final model with involving the non-Darcy approach for permeable media. Finite volume approach was applied for achieving the outputs which are exergy loss (Xd) and hydrothermal behavior. Use of additives results in lower Xd more than 7.7% when Re = 10 Da = 1e2. With growth of Re, the Xd declines around a bit greater than 19%. Utilizing higher permeability allows the hybrid nanofluid moves quicker and exergy loss augments less than 10.5%.

KW - Disturber device

KW - hybrid nanomaterial

KW - laminar flow

KW - numerical method

KW - permeability

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JO - Modern Physics Letters B

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ER -

Study for nanomaterial transportation within the channel with apply of complicated turbulator

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Keywords

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