Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method

Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method

In this study, the rheological behavior of MWCNT-Al2O3 (40:60)/SAE50 hybrid nano-lubricant was studied to identify the maximum drop, the maximum increase in viscosity (μnf), as well as how the parameters of temperature, ϕ and shear rate (γ˙) affect the μnf. Various methods theoretically show that th...

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Main Authors: Mohammad Hemmat Esfe, Saeed Esfandeh, Soheyl Alidoust, Davood Toghraie
Format: Article
Language:English
Published: Elsevier 2021-11-01
Series:Journal of Materials Research and Technology
Subjects:
Hybrid nano-lubricants
Viscosity
Comparative study
Rheological behavior
RSM
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785421009054
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spelling doaj-2b074a66134b4b69938dad99b3a83e952021-09-25T05:07:38ZengElsevierJournal of Materials Research and Technology2238-78542021-11-011520592074Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface methodMohammad Hemmat Esfe0Saeed Esfandeh1Soheyl Alidoust2Davood Toghraie3Department of Mechanical Engineering, Imam Hossein University, Tehran, IranDepartment of Mechanical Engineering, Imam Hossein University, Tehran, IranDepartment of Mechanical Engineering, Imam Hossein University, Tehran, Iran; School of Chemistry, Damghan University, Damghan 36716-41167, IranDepartment of Mechanical Engineering, Khomeinishahr Branch, Islamic Azad University, Khomeinishahr, Iran; Corresponding author.In this study, the rheological behavior of MWCNT-Al2O3 (40:60)/SAE50 hybrid nano-lubricant was studied to identify the maximum drop, the maximum increase in viscosity (μnf), as well as how the parameters of temperature, ϕ and shear rate (γ˙) affect the μnf. Various methods theoretically show that the nano-lubricant has a flow of pseudo-plastic non-Newtonian fluids. Statistical reports show that the highest increase and decrease in μnf of nano-lubricant compared to the base fluid in ϕ = 1%, T = 30 °C and γ=˙ 6665 s−1 (equivalent to high engine speed) and ϕ = 0.0625%, T = 25 °C and γ=˙ 3999 s−1 (equivalent to low engine speed) are occurred, which are equal to 38.76% and −5.14%, respectively. To predict the dependent variable data, a three-variable-quadratic model was presented with the RSM method with an R-Squared = 0.9997. The margin of deviation for data was determined in the range of −2.41% <MOD <3.13%. Using numerical simulation, it was found that with increasing the ϕ, the pressure drop of the flow and the applied shear stress to the wall of the pipe increase.http://www.sciencedirect.com/science/article/pii/S2238785421009054Hybrid nano-lubricantsViscosityComparative studyRheological behaviorRSM
collection DOAJ
language English
format Article
sources DOAJ
author Mohammad Hemmat Esfe
Saeed Esfandeh
Soheyl Alidoust
Davood Toghraie
spellingShingle Mohammad Hemmat Esfe
Saeed Esfandeh
Soheyl Alidoust
Davood Toghraie
Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
Journal of Materials Research and Technology
Hybrid nano-lubricants
Viscosity
Comparative study
Rheological behavior
RSM
author_facet Mohammad Hemmat Esfe
Saeed Esfandeh
Soheyl Alidoust
Davood Toghraie
author_sort Mohammad Hemmat Esfe
title Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
title_short Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
title_full Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
title_fullStr Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
title_full_unstemmed Experimental study of rheological characteristics of MWCNT-Al2O3 (40:60) / SAE50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
title_sort experimental study of rheological characteristics of mwcnt-al2o3 (40:60) / sae50 hybrid nano-lubricant to identify optimal lubrication conditions and post-processing of results using the response surface method
publisher Elsevier
series Journal of Materials Research and Technology
issn 2238-7854
publishDate 2021-11-01
description In this study, the rheological behavior of MWCNT-Al2O3 (40:60)/SAE50 hybrid nano-lubricant was studied to identify the maximum drop, the maximum increase in viscosity (μnf), as well as how the parameters of temperature, ϕ and shear rate (γ˙) affect the μnf. Various methods theoretically show that the nano-lubricant has a flow of pseudo-plastic non-Newtonian fluids. Statistical reports show that the highest increase and decrease in μnf of nano-lubricant compared to the base fluid in ϕ = 1%, T = 30 °C and γ=˙ 6665 s−1 (equivalent to high engine speed) and ϕ = 0.0625%, T = 25 °C and γ=˙ 3999 s−1 (equivalent to low engine speed) are occurred, which are equal to 38.76% and −5.14%, respectively. To predict the dependent variable data, a three-variable-quadratic model was presented with the RSM method with an R-Squared = 0.9997. The margin of deviation for data was determined in the range of −2.41% <MOD <3.13%. Using numerical simulation, it was found that with increasing the ϕ, the pressure drop of the flow and the applied shear stress to the wall of the pipe increase.
topic Hybrid nano-lubricants
Viscosity
Comparative study
Rheological behavior
RSM
url http://www.sciencedirect.com/science/article/pii/S2238785421009054
work_keys_str_mv AT mohammadhemmatesfe experimentalstudyofrheologicalcharacteristicsofmwcntal2o34060sae50hybridnanolubricanttoidentifyoptimallubricationconditionsandpostprocessingofresultsusingtheresponsesurfacemethod
AT saeedesfandeh experimentalstudyofrheologicalcharacteristicsofmwcntal2o34060sae50hybridnanolubricanttoidentifyoptimallubricationconditionsandpostprocessingofresultsusingtheresponsesurfacemethod
AT soheylalidoust experimentalstudyofrheologicalcharacteristicsofmwcntal2o34060sae50hybridnanolubricanttoidentifyoptimallubricationconditionsandpostprocessingofresultsusingtheresponsesurfacemethod
AT davoodtoghraie experimentalstudyofrheologicalcharacteristicsofmwcntal2o34060sae50hybridnanolubricanttoidentifyoptimallubricationconditionsandpostprocessingofresultsusingtheresponsesurfacemethod
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