Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids
Heat exchangers with unique specifications are administered in the food industry, which has expanded its sphere of influence even to the automotive industry due to this feature. It has been used for convenient maintenance and much easier cleaning. In this study, two different nanomaterials, such as...
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Hindawi Limited
2021
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oai:doaj.org-article:efb3485a901d4949aa4d5f446f463c582021-11-08T02:37:01ZUse of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids1687-412910.1155/2021/3250058https://doaj.org/article/efb3485a901d4949aa4d5f446f463c582021-01-01T00:00:00Zhttp://dx.doi.org/10.1155/2021/3250058https://doaj.org/toc/1687-4129Heat exchangers with unique specifications are administered in the food industry, which has expanded its sphere of influence even to the automotive industry due to this feature. It has been used for convenient maintenance and much easier cleaning. In this study, two different nanomaterials, such as Cu-based nanoparticles and an organic nanoparticle of Chloro-difluoromethane (R22), were used as nanofluids to enhance the efficiency of heat transfer in a turbulator. It is simulated by computational fluid dynamics software (Ansys-Fluent) to evaluate the Nusselt number versus Reynolds number for different variables. These variables are diameter ratio, torsion pitch ratio, and two different nanofluids through the shell tube heat exchanger. It is evident that for higher diameter ratios, the Nusselt number has been increased significantly in higher Reynolds numbers as the heat transfer has been increased in turbulators. For organic fluids (R22), the Nusselt number has been increased significantly in higher Reynolds numbers as the heat transfer has been increased in turbulators due to the proximity of heat transfer charges. At higher torsion pitch ratios, the Nusselt number has been increased significantly in the higher Reynolds number as the heat transfer has been increased in turbulators, especially in higher velocities and pipe turbulence torsions.Supat ChupraditAbduladheem Turki JalilYulianna EninaDmitriy A. NeganovMuataz S. AlhassanSurendar AravindhanAfshin DavarpanahHindawi LimitedarticleTechnology (General)T1-995ENJournal of Nanomaterials, Vol 2021 (2021) |
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DOAJ |
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DOAJ |
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EN |
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Technology (General) T1-995 |
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Technology (General) T1-995 Supat Chupradit Abduladheem Turki Jalil Yulianna Enina Dmitriy A. Neganov Muataz S. Alhassan Surendar Aravindhan Afshin Davarpanah Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids |
| description |
Heat exchangers with unique specifications are administered in the food industry, which has expanded its sphere of influence even to the automotive industry due to this feature. It has been used for convenient maintenance and much easier cleaning. In this study, two different nanomaterials, such as Cu-based nanoparticles and an organic nanoparticle of Chloro-difluoromethane (R22), were used as nanofluids to enhance the efficiency of heat transfer in a turbulator. It is simulated by computational fluid dynamics software (Ansys-Fluent) to evaluate the Nusselt number versus Reynolds number for different variables. These variables are diameter ratio, torsion pitch ratio, and two different nanofluids through the shell tube heat exchanger. It is evident that for higher diameter ratios, the Nusselt number has been increased significantly in higher Reynolds numbers as the heat transfer has been increased in turbulators. For organic fluids (R22), the Nusselt number has been increased significantly in higher Reynolds numbers as the heat transfer has been increased in turbulators due to the proximity of heat transfer charges. At higher torsion pitch ratios, the Nusselt number has been increased significantly in the higher Reynolds number as the heat transfer has been increased in turbulators, especially in higher velocities and pipe turbulence torsions. |
| format |
article |
| author |
Supat Chupradit Abduladheem Turki Jalil Yulianna Enina Dmitriy A. Neganov Muataz S. Alhassan Surendar Aravindhan Afshin Davarpanah |
| author_facet |
Supat Chupradit Abduladheem Turki Jalil Yulianna Enina Dmitriy A. Neganov Muataz S. Alhassan Surendar Aravindhan Afshin Davarpanah |
| author_sort |
Supat Chupradit |
| title |
Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids |
| title_short |
Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids |
| title_full |
Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids |
| title_fullStr |
Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids |
| title_full_unstemmed |
Use of Organic and Copper-Based Nanoparticles on the Turbulator Installment in a Shell Tube Heat Exchanger: A CFD-Based Simulation Approach by Using Nanofluids |
| title_sort |
use of organic and copper-based nanoparticles on the turbulator installment in a shell tube heat exchanger: a cfd-based simulation approach by using nanofluids |
| publisher |
Hindawi Limited |
| publishDate |
2021 |
| url |
https://doaj.org/article/efb3485a901d4949aa4d5f446f463c58 |
| work_keys_str_mv |
AT supatchupradit useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids AT abduladheemturkijalil useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids AT yuliannaenina useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids AT dmitriyaneganov useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids AT muatazsalhassan useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids AT surendararavindhan useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids AT afshindavarpanah useoforganicandcopperbasednanoparticlesontheturbulatorinstallmentinashelltubeheatexchangeracfdbasedsimulationapproachbyusingnanofluids |
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