Thermal and Hydraulic Performances of Carbon and Metallic Oxides-Based Nanomaterials

Haitham Abdulmohsin Afan; Mohammed Suleman Aldlemy; Ali M. Ahmed; Ali H. Jawad; Maryam H. Naser; Raad Z. Homod; Zainab Haider Mussa; Adnan Hashim Abdulkadhim; Miklas Scholz; Zaher Mundher Yaseen

doi:10.3390/nano12091545

Thermal and Hydraulic Performances of Carbon and Metallic Oxides-Based Nanomaterials

Haitham Abdulmohsin Afan
, Mohammed Suleman Aldlemy
, Ali M. Ahmed
, Ali H. Jawad
, Maryam H. Naser
, Raad Z. Homod
, Zainab Haider Mussa
, Adnan Hashim Abdulkadhim
, Miklas Scholz^*
, Zaher Mundher Yaseen^*

^*Corresponding author for this work

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

3 Scopus citations

Abstract

For companies, notably in the realms of energy and power supply, the essential requirement for highly efficient thermal transport solutions has become a serious concern. Current research highlighted the use of metallic oxides and carbon-based nanofluids as heat transfer fluids. This work examined two carbon forms (PEG@GNPs & PEG@TGr) and two types of metallic oxides (Al2O3 & SiO2) in a square heated pipe in the mass fraction of 0.1 wt.%. Laboratory conditions were as follows: 6401 ≤ Re ≤ 11,907 and wall heat flux = 11,205 W/m2. The effective thermal–physical and heat transfer properties were assessed for fully developed turbulent fluid flow at 20–60 °C. The thermal and hydraulic performances of nanofluids were rated in terms of pumping power, performance index (PI), and performance evaluation criteria (PEC). The heat transfer coefficients of the nanofluids improved the most: PEG@GNPs = 44.4%, PEG@TGr = 41.2%, Al2O3 = 22.5%, and SiO2 = 24%. Meanwhile, the highest augmentation in the Nu of the nanofluids was as follows: PEG@GNPs = 35%, PEG@TGr = 30.1%, Al2O3 = 20.6%, and SiO2 = 21.9%. The pressure loss and friction factor increased the highest, by 20.8–23.7% and 3.57–3.85%, respectively. In the end, the general performance of nanofluids has shown that they would be a good alternative to the traditional working fluids in heat transfer requests.

Original language	English
Article number	1545
Journal	Nanomaterials
Volume	12
Issue number	9
DOIs	https://doi.org/10.3390/nano12091545
State	Published - 1 May 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2022 by the authors. Licensee MDPI, Basel, Switzerland.

Keywords

carbon nanostructures
convective heat transfer
metallic oxides
thermophysical properties
turbulent flow

ASJC Scopus subject areas

General Chemical Engineering
General Materials Science

Access to Document

10.3390/nano12091545

Cite this

@article{15f46de6858b48158b9b9c9a8dc12011,

title = "Thermal and Hydraulic Performances of Carbon and Metallic Oxides-Based Nanomaterials",

abstract = "For companies, notably in the realms of energy and power supply, the essential requirement for highly efficient thermal transport solutions has become a serious concern. Current research highlighted the use of metallic oxides and carbon-based nanofluids as heat transfer fluids. This work examined two carbon forms (PEG@GNPs \& PEG@TGr) and two types of metallic oxides (Al2O3 \& SiO2) in a square heated pipe in the mass fraction of 0.1 wt.\%. Laboratory conditions were as follows: 6401 ≤ Re ≤ 11,907 and wall heat flux = 11,205 W/m2. The effective thermal–physical and heat transfer properties were assessed for fully developed turbulent fluid flow at 20–60 °C. The thermal and hydraulic performances of nanofluids were rated in terms of pumping power, performance index (PI), and performance evaluation criteria (PEC). The heat transfer coefficients of the nanofluids improved the most: PEG@GNPs = 44.4\%, PEG@TGr = 41.2\%, Al2O3 = 22.5\%, and SiO2 = 24\%. Meanwhile, the highest augmentation in the Nu of the nanofluids was as follows: PEG@GNPs = 35\%, PEG@TGr = 30.1\%, Al2O3 = 20.6\%, and SiO2 = 21.9\%. The pressure loss and friction factor increased the highest, by 20.8–23.7\% and 3.57–3.85\%, respectively. In the end, the general performance of nanofluids has shown that they would be a good alternative to the traditional working fluids in heat transfer requests.",

keywords = "carbon nanostructures, convective heat transfer, metallic oxides, thermophysical properties, turbulent flow",

author = "Afan, \{Haitham Abdulmohsin\} and Aldlemy, \{Mohammed Suleman\} and Ahmed, \{Ali M.\} and Jawad, \{Ali H.\} and Naser, \{Maryam H.\} and Homod, \{Raad Z.\} and Mussa, \{Zainab Haider\} and Abdulkadhim, \{Adnan Hashim\} and Miklas Scholz and Yaseen, \{Zaher Mundher\}",

note = "Publisher Copyright: {\textcopyright} 2022 by the authors. Licensee MDPI, Basel, Switzerland.",

year = "2022",

month = may,

day = "1",

doi = "10.3390/nano12091545",

language = "English",

volume = "12",

journal = "Nanomaterials",

issn = "2079-4991",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "9",

}

TY - JOUR

T1 - Thermal and Hydraulic Performances of Carbon and Metallic Oxides-Based Nanomaterials

AU - Afan, Haitham Abdulmohsin

AU - Aldlemy, Mohammed Suleman

AU - Ahmed, Ali M.

AU - Jawad, Ali H.

AU - Naser, Maryam H.

AU - Homod, Raad Z.

AU - Mussa, Zainab Haider

AU - Abdulkadhim, Adnan Hashim

AU - Scholz, Miklas

AU - Yaseen, Zaher Mundher

PY - 2022/5/1

Y1 - 2022/5/1

N2 - For companies, notably in the realms of energy and power supply, the essential requirement for highly efficient thermal transport solutions has become a serious concern. Current research highlighted the use of metallic oxides and carbon-based nanofluids as heat transfer fluids. This work examined two carbon forms (PEG@GNPs & PEG@TGr) and two types of metallic oxides (Al2O3 & SiO2) in a square heated pipe in the mass fraction of 0.1 wt.%. Laboratory conditions were as follows: 6401 ≤ Re ≤ 11,907 and wall heat flux = 11,205 W/m2. The effective thermal–physical and heat transfer properties were assessed for fully developed turbulent fluid flow at 20–60 °C. The thermal and hydraulic performances of nanofluids were rated in terms of pumping power, performance index (PI), and performance evaluation criteria (PEC). The heat transfer coefficients of the nanofluids improved the most: PEG@GNPs = 44.4%, PEG@TGr = 41.2%, Al2O3 = 22.5%, and SiO2 = 24%. Meanwhile, the highest augmentation in the Nu of the nanofluids was as follows: PEG@GNPs = 35%, PEG@TGr = 30.1%, Al2O3 = 20.6%, and SiO2 = 21.9%. The pressure loss and friction factor increased the highest, by 20.8–23.7% and 3.57–3.85%, respectively. In the end, the general performance of nanofluids has shown that they would be a good alternative to the traditional working fluids in heat transfer requests.

AB - For companies, notably in the realms of energy and power supply, the essential requirement for highly efficient thermal transport solutions has become a serious concern. Current research highlighted the use of metallic oxides and carbon-based nanofluids as heat transfer fluids. This work examined two carbon forms (PEG@GNPs & PEG@TGr) and two types of metallic oxides (Al2O3 & SiO2) in a square heated pipe in the mass fraction of 0.1 wt.%. Laboratory conditions were as follows: 6401 ≤ Re ≤ 11,907 and wall heat flux = 11,205 W/m2. The effective thermal–physical and heat transfer properties were assessed for fully developed turbulent fluid flow at 20–60 °C. The thermal and hydraulic performances of nanofluids were rated in terms of pumping power, performance index (PI), and performance evaluation criteria (PEC). The heat transfer coefficients of the nanofluids improved the most: PEG@GNPs = 44.4%, PEG@TGr = 41.2%, Al2O3 = 22.5%, and SiO2 = 24%. Meanwhile, the highest augmentation in the Nu of the nanofluids was as follows: PEG@GNPs = 35%, PEG@TGr = 30.1%, Al2O3 = 20.6%, and SiO2 = 21.9%. The pressure loss and friction factor increased the highest, by 20.8–23.7% and 3.57–3.85%, respectively. In the end, the general performance of nanofluids has shown that they would be a good alternative to the traditional working fluids in heat transfer requests.

KW - carbon nanostructures

KW - convective heat transfer

KW - metallic oxides

KW - thermophysical properties

KW - turbulent flow

UR - https://www.scopus.com/pages/publications/85130841256

U2 - 10.3390/nano12091545

DO - 10.3390/nano12091545

M3 - Article

AN - SCOPUS:85130841256

SN - 2079-4991

VL - 12

JO - Nanomaterials

JF - Nanomaterials

IS - 9

M1 - 1545

ER -

Thermal and Hydraulic Performances of Carbon and Metallic Oxides-Based Nanomaterials

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

Fingerprint

Cite this