Optimization and experimental analysis of sustainable solar collector efficiency under the influence of magnetic nanofluids

Abdulkader S. Hanbazazah; Abulhassan Ali; Mustafa Alsaady; Yuying Yan; Ghulam Murshid; Kuan Shiong Khoo; Muhammad Mubashir; Aymn Abdulrahman; Anas Ahmed; Abdullah Bin Mahfouz; Ahmed Alsaadi; Pau Loke Show

doi:10.1007/s13204-022-02533-3

Optimization and experimental analysis of sustainable solar collector efficiency under the influence of magnetic nanofluids

Abdulkader S. Hanbazazah, Abulhassan Ali^*, Mustafa Alsaady, Yuying Yan, Ghulam Murshid, Kuan Shiong Khoo, Muhammad Mubashir, Aymn Abdulrahman, Anas Ahmed, Abdullah Bin Mahfouz, Ahmed Alsaadi, Pau Loke Show^*

^*Corresponding author for this work

Petroleum and Chemical Engineering

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

7 Citations (Scopus)

Abstract

Fossil fuels produce harmful gases that adversely affect the environment and human health. Although some sources of energy (e.g., solar, wind, and biofuels) are clean and renewable, substantial research is required to compete with fossil fuels. Several research studies are available on parabolic trough solar collectors, but process modeling and the influence of input parameters on optimization to enhance efficiency are hardly tried. The present study involves modeling and optimization of the efficiency of novel parabolic trough solar collectors under laminar flow conditions using magnetic nanofluids (NF). The study is conducted in two steps; the first step involves developing a predictive model using Response Surface Methodology (RSM). The second step consists of calculating the optimum parameters for maximum parabolic trough solar collector efficiency. NF weight %, temperature, and magnetic flux were selected as input parameters. The developed model was further tested and validated using experimental results, and the agreement is promising with R² 0.966. Two optimization case studies were explored, focusing on the efficiency maximization of parabolic trough solar collectors. In the first case study, the constraint was set to minimize the NF wt.% while in the second case study, all the inputs were unconstrained. In the first case study, the efficiency was 61.69%, with a desirability of 0.71. In the second case study, the efficiency was increased up to 80.44% with the desirability of 1. The increase in the efficiency of the second case study is mainly due to the NF wt.% increased from 0.188 to 0.7388.

Original language	English
Pages (from-to)	3859-3870
Number of pages	12
Journal	Applied Nanoscience (Switzerland)
Volume	12
Issue number	12
DOIs	https://doi.org/10.1007/s13204-022-02533-3
Publication status	Published - Jul 12 2022

Keywords

Ferrofluids
Magnetic nanofluid
Nanofluids
Response surface methodology
Solar collector

ASJC Scopus subject areas

Biotechnology
Atomic and Molecular Physics, and Optics
Materials Science (miscellaneous)
Physical and Theoretical Chemistry
Cell Biology
Electrical and Electronic Engineering

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1007/s13204-022-02533-3

Cite this

Hanbazazah, A. S., Ali, A., Alsaady, M., Yan, Y., Murshid, G., Khoo, K. S., Mubashir, M., Abdulrahman, A., Ahmed, A., Mahfouz, A. B., Alsaadi, A., & Show, P. L. (2022). Optimization and experimental analysis of sustainable solar collector efficiency under the influence of magnetic nanofluids. Applied Nanoscience (Switzerland), 12(12), 3859-3870. https://doi.org/10.1007/s13204-022-02533-3

Hanbazazah, AS, Ali, A, Alsaady, M, Yan, Y, Murshid, G, Khoo, KS, Mubashir, M, Abdulrahman, A, Ahmed, A, Mahfouz, AB, Alsaadi, A & Show, PL 2022, 'Optimization and experimental analysis of sustainable solar collector efficiency under the influence of magnetic nanofluids', Applied Nanoscience (Switzerland), vol. 12, no. 12, pp. 3859-3870. https://doi.org/10.1007/s13204-022-02533-3

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title = "Optimization and experimental analysis of sustainable solar collector efficiency under the influence of magnetic nanofluids",

abstract = "Fossil fuels produce harmful gases that adversely affect the environment and human health. Although some sources of energy (e.g., solar, wind, and biofuels) are clean and renewable, substantial research is required to compete with fossil fuels. Several research studies are available on parabolic trough solar collectors, but process modeling and the influence of input parameters on optimization to enhance efficiency are hardly tried. The present study involves modeling and optimization of the efficiency of novel parabolic trough solar collectors under laminar flow conditions using magnetic nanofluids (NF). The study is conducted in two steps; the first step involves developing a predictive model using Response Surface Methodology (RSM). The second step consists of calculating the optimum parameters for maximum parabolic trough solar collector efficiency. NF weight %, temperature, and magnetic flux were selected as input parameters. The developed model was further tested and validated using experimental results, and the agreement is promising with R2 0.966. Two optimization case studies were explored, focusing on the efficiency maximization of parabolic trough solar collectors. In the first case study, the constraint was set to minimize the NF wt.% while in the second case study, all the inputs were unconstrained. In the first case study, the efficiency was 61.69%, with a desirability of 0.71. In the second case study, the efficiency was increased up to 80.44% with the desirability of 1. The increase in the efficiency of the second case study is mainly due to the NF wt.% increased from 0.188 to 0.7388.",

keywords = "Ferrofluids, Magnetic nanofluid, Nanofluids, Response surface methodology, Solar collector",

author = "Hanbazazah, {Abdulkader S.} and Abulhassan Ali and Mustafa Alsaady and Yuying Yan and Ghulam Murshid and Khoo, {Kuan Shiong} and Muhammad Mubashir and Aymn Abdulrahman and Anas Ahmed and Mahfouz, {Abdullah Bin} and Ahmed Alsaadi and Show, {Pau Loke}",

note = "Funding Information: This work was funded by the University of Jeddah, Jeddah, Saudi Arabia, under grant No. (UJ-02-006-ICGR). The authors, therefore, acknowledge with thanks the University of Jeddah technical and financial support. Publisher Copyright: {\textcopyright} 2022, King Abdulaziz City for Science and Technology.",

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doi = "10.1007/s13204-022-02533-3",

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AU - Hanbazazah, Abdulkader S.

AU - Ali, Abulhassan

AU - Alsaady, Mustafa

AU - Yan, Yuying

AU - Murshid, Ghulam

AU - Khoo, Kuan Shiong

AU - Mubashir, Muhammad

AU - Abdulrahman, Aymn

AU - Ahmed, Anas

AU - Mahfouz, Abdullah Bin

AU - Alsaadi, Ahmed

AU - Show, Pau Loke

N1 - Funding Information: This work was funded by the University of Jeddah, Jeddah, Saudi Arabia, under grant No. (UJ-02-006-ICGR). The authors, therefore, acknowledge with thanks the University of Jeddah technical and financial support. Publisher Copyright: © 2022, King Abdulaziz City for Science and Technology.

PY - 2022/7/12

Y1 - 2022/7/12

N2 - Fossil fuels produce harmful gases that adversely affect the environment and human health. Although some sources of energy (e.g., solar, wind, and biofuels) are clean and renewable, substantial research is required to compete with fossil fuels. Several research studies are available on parabolic trough solar collectors, but process modeling and the influence of input parameters on optimization to enhance efficiency are hardly tried. The present study involves modeling and optimization of the efficiency of novel parabolic trough solar collectors under laminar flow conditions using magnetic nanofluids (NF). The study is conducted in two steps; the first step involves developing a predictive model using Response Surface Methodology (RSM). The second step consists of calculating the optimum parameters for maximum parabolic trough solar collector efficiency. NF weight %, temperature, and magnetic flux were selected as input parameters. The developed model was further tested and validated using experimental results, and the agreement is promising with R2 0.966. Two optimization case studies were explored, focusing on the efficiency maximization of parabolic trough solar collectors. In the first case study, the constraint was set to minimize the NF wt.% while in the second case study, all the inputs were unconstrained. In the first case study, the efficiency was 61.69%, with a desirability of 0.71. In the second case study, the efficiency was increased up to 80.44% with the desirability of 1. The increase in the efficiency of the second case study is mainly due to the NF wt.% increased from 0.188 to 0.7388.

AB - Fossil fuels produce harmful gases that adversely affect the environment and human health. Although some sources of energy (e.g., solar, wind, and biofuels) are clean and renewable, substantial research is required to compete with fossil fuels. Several research studies are available on parabolic trough solar collectors, but process modeling and the influence of input parameters on optimization to enhance efficiency are hardly tried. The present study involves modeling and optimization of the efficiency of novel parabolic trough solar collectors under laminar flow conditions using magnetic nanofluids (NF). The study is conducted in two steps; the first step involves developing a predictive model using Response Surface Methodology (RSM). The second step consists of calculating the optimum parameters for maximum parabolic trough solar collector efficiency. NF weight %, temperature, and magnetic flux were selected as input parameters. The developed model was further tested and validated using experimental results, and the agreement is promising with R2 0.966. Two optimization case studies were explored, focusing on the efficiency maximization of parabolic trough solar collectors. In the first case study, the constraint was set to minimize the NF wt.% while in the second case study, all the inputs were unconstrained. In the first case study, the efficiency was 61.69%, with a desirability of 0.71. In the second case study, the efficiency was increased up to 80.44% with the desirability of 1. The increase in the efficiency of the second case study is mainly due to the NF wt.% increased from 0.188 to 0.7388.

KW - Ferrofluids

KW - Magnetic nanofluid

KW - Nanofluids

KW - Response surface methodology

KW - Solar collector

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Optimization and experimental analysis of sustainable solar collector efficiency under the influence of magnetic nanofluids

Abstract

Keywords

ASJC Scopus subject areas

UN SDGs

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