Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction

The energy crises in the worldwide have been encouraging the researchers to look for new methods which increase of thermal performance. One of common technique to improve efficiency of energy system equipment is by changing the design configuration of channel and conventional fluid such as nanofluid...

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Main Author: Abdulrazzaq, Tuqa
Format: Thesis
Language:English
Published: 2015
Online Access:http://psasir.upm.edu.my/id/eprint/65485/1/FK%202015%20145IR.pdf
http://psasir.upm.edu.my/id/eprint/65485/
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Institution: Universiti Putra Malaysia
Language: English
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spelling my.upm.eprints.654852018-09-19T08:36:54Z http://psasir.upm.edu.my/id/eprint/65485/ Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction Abdulrazzaq, Tuqa The energy crises in the worldwide have been encouraging the researchers to look for new methods which increase of thermal performance. One of common technique to improve efficiency of energy system equipment is by changing the design configuration of channel and conventional fluid such as nanofluids. Enhancements of heat transfer and nanofluid flows through an annular channel with abrupt contraction are numerically and experimentally investigate. The finite volume method in three dimensional domains with an SST K-ω model is use in simulation. Aluminum oxide and titanium oxide (Al2O3, TiO2) nanoparticles with volume fractions varied from 0.5% to 2% have been use. Reynolds number range varying between 10000 and 40000 and contraction ratios from 1 to 2 at heat flux varied from 1000 W/m2 to 6000 W/m2 were apply. In order to validate numerical results Al2O3 water based nanofluid was use in experimental study. The outer cylinder of the entrance pipe had a constant diameter while the outer cylinder of the exit pipe had different diameters to generate the contraction. Both the entrance and exit pipe were heated under uniform heat flux and the overall length of the inner cylinder were unheated and has constant diameter. The results showed that the maximum heat transfer coefficient was about 194.7% in an annular pipe with contraction ratio of 2 compared with a straight pipe, due to the generated recirculation flow zone that begins after the separation point of the wall. It was observed that by increasing nanoparticle volume fraction for all type of nanofluids, enhances the heat transfer coefficient due to augmented heat transport by nanoparticles in base fluid which raises the convection heat transfer where were about 26.9 % ( Al2O3) and 5.5% (TiO2). Also the effect of Reynolds number on the increase of surface heat transfer coefficient noted. Recirculation regions appeared to increase with increasing step height and Reynolds number. Also pressure drop observed decreases and increases before and after the step due to recirculation flow. The maximum pressure drop were about 7.5% (Al2O3) and 5.9% (TiO2) nanofluid compared with pure water at contraction ratio of 2 and Reynolds number of 40000. Additional investigations have been done in this research in order to clarify the effect of separation flow on augmentation of heat transfer and pressure drop. Heat transfer and turbulent fluid flow over double forward-facing step or through annular pipe with sudden contraction were performed numerically. Same findings have been observed in those studies where increase of thermal performance and pressure drop with increases Reynolds number and step heights. 2015-03 Thesis NonPeerReviewed text en http://psasir.upm.edu.my/id/eprint/65485/1/FK%202015%20145IR.pdf Abdulrazzaq, Tuqa (2015) Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction. PhD thesis, Universiti Putra Malaysia.
institution Universiti Putra Malaysia
building UPM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Putra Malaysia
content_source UPM Institutional Repository
url_provider http://psasir.upm.edu.my/
language English
description The energy crises in the worldwide have been encouraging the researchers to look for new methods which increase of thermal performance. One of common technique to improve efficiency of energy system equipment is by changing the design configuration of channel and conventional fluid such as nanofluids. Enhancements of heat transfer and nanofluid flows through an annular channel with abrupt contraction are numerically and experimentally investigate. The finite volume method in three dimensional domains with an SST K-ω model is use in simulation. Aluminum oxide and titanium oxide (Al2O3, TiO2) nanoparticles with volume fractions varied from 0.5% to 2% have been use. Reynolds number range varying between 10000 and 40000 and contraction ratios from 1 to 2 at heat flux varied from 1000 W/m2 to 6000 W/m2 were apply. In order to validate numerical results Al2O3 water based nanofluid was use in experimental study. The outer cylinder of the entrance pipe had a constant diameter while the outer cylinder of the exit pipe had different diameters to generate the contraction. Both the entrance and exit pipe were heated under uniform heat flux and the overall length of the inner cylinder were unheated and has constant diameter. The results showed that the maximum heat transfer coefficient was about 194.7% in an annular pipe with contraction ratio of 2 compared with a straight pipe, due to the generated recirculation flow zone that begins after the separation point of the wall. It was observed that by increasing nanoparticle volume fraction for all type of nanofluids, enhances the heat transfer coefficient due to augmented heat transport by nanoparticles in base fluid which raises the convection heat transfer where were about 26.9 % ( Al2O3) and 5.5% (TiO2). Also the effect of Reynolds number on the increase of surface heat transfer coefficient noted. Recirculation regions appeared to increase with increasing step height and Reynolds number. Also pressure drop observed decreases and increases before and after the step due to recirculation flow. The maximum pressure drop were about 7.5% (Al2O3) and 5.9% (TiO2) nanofluid compared with pure water at contraction ratio of 2 and Reynolds number of 40000. Additional investigations have been done in this research in order to clarify the effect of separation flow on augmentation of heat transfer and pressure drop. Heat transfer and turbulent fluid flow over double forward-facing step or through annular pipe with sudden contraction were performed numerically. Same findings have been observed in those studies where increase of thermal performance and pressure drop with increases Reynolds number and step heights.
format Thesis
author Abdulrazzaq, Tuqa
spellingShingle Abdulrazzaq, Tuqa
Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
author_facet Abdulrazzaq, Tuqa
author_sort Abdulrazzaq, Tuqa
title Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
title_short Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
title_full Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
title_fullStr Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
title_full_unstemmed Numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
title_sort numerical and experimental analysis of heat transfer and nanofluid flow through an annular pipe with abrupt contraction
publishDate 2015
url http://psasir.upm.edu.my/id/eprint/65485/1/FK%202015%20145IR.pdf
http://psasir.upm.edu.my/id/eprint/65485/
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