Numerical simulation of single-nozzle large scale spray cooling on drum wall

Numerical simulation of single-nozzle large scale spray cooling on drum wall

In this work the single-nozzle spray cooling on a large scale industry-used drum wall has been simulated by a verified numerical model. For a certain spray nozzle, the effects of four parameters, i. e. different spray pressures, different spray heights, different water temperatures, and different wa...

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Bibliographic Details
Main Authors: Chen Zuobing, Xie Qiang, Chen Gong, Yu Yongjie, Zhao Zheyu
Format: Article
Language:English
Published: VINCA Institute of Nuclear Sciences 2018-01-01
Series:Thermal Science
Subjects:
Numerical Simulation
drum wall
single-nozzle
spray cooling
large scale
Online Access:http://www.doiserbia.nb.rs/img/doi/0354-9836/2018/0354-98361700243C.pdf
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spelling doaj-dd41dc66b2e745ff87aa897c435931d32021-01-02T03:53:28ZengVINCA Institute of Nuclear SciencesThermal Science0354-98362334-71632018-01-01221 Part A35937010.2298/TSCI170920243C0354-98361700243CNumerical simulation of single-nozzle large scale spray cooling on drum wallChen Zuobing0Xie Qiang1Chen Gong2Yu Yongjie3Zhao Zheyu4Wuhan University of Technology, School of Mechanical and Electronic Engineering, Wuhan, Hubei, ChinaWuhan University of Technology, School of Mechanical and Electronic Engineering, Wuhan, Hubei, ChinaSinoma (Suzhou) Construction limited company, Kunshan, Jiangsu, ChinaWuhan University of Technology, School of Mechanical and Electronic Engineering, Wuhan, Hubei, ChinaWuhan University of Technology, School of Mechanical and Electronic Engineering, Wuhan, Hubei, ChinaIn this work the single-nozzle spray cooling on a large scale industry-used drum wall has been simulated by a verified numerical model. For a certain spray nozzle, the effects of four parameters, i. e. different spray pressures, different spray heights, different water temperatures, and different wall temperatures, on heat transfer have been analyzed. It is found that the mean heat flux distributions show concentric elliptical circles. Increasing spray pressures will enhance the cooling performance. Decreasing spray heights will improve the heat flux in direct spray areas other than whole simulated drum wall. As expected, reducing water temperature or advancing wall temperature will raise the average wall flux. Both relationships are exponential. The influencing degrees of the four parameters have been compared through Taguchi orthogonal experimental method and the result is: wall temperature > spray pressure > water temperature > spray height. The wall temperature, spray pressure, and water temperature show dominant effects except for the spray height.http://www.doiserbia.nb.rs/img/doi/0354-9836/2018/0354-98361700243C.pdfNumerical Simulationdrum wallsingle-nozzlespray coolinglarge scale
collection DOAJ
language English
format Article
sources DOAJ
author Chen Zuobing
Xie Qiang
Chen Gong
Yu Yongjie
Zhao Zheyu
spellingShingle Chen Zuobing
Xie Qiang
Chen Gong
Yu Yongjie
Zhao Zheyu
Numerical simulation of single-nozzle large scale spray cooling on drum wall
Thermal Science
Numerical Simulation
drum wall
single-nozzle
spray cooling
large scale
author_facet Chen Zuobing
Xie Qiang
Chen Gong
Yu Yongjie
Zhao Zheyu
author_sort Chen Zuobing
title Numerical simulation of single-nozzle large scale spray cooling on drum wall
title_short Numerical simulation of single-nozzle large scale spray cooling on drum wall
title_full Numerical simulation of single-nozzle large scale spray cooling on drum wall
title_fullStr Numerical simulation of single-nozzle large scale spray cooling on drum wall
title_full_unstemmed Numerical simulation of single-nozzle large scale spray cooling on drum wall
title_sort numerical simulation of single-nozzle large scale spray cooling on drum wall
publisher VINCA Institute of Nuclear Sciences
series Thermal Science
issn 0354-9836
2334-7163
publishDate 2018-01-01
description In this work the single-nozzle spray cooling on a large scale industry-used drum wall has been simulated by a verified numerical model. For a certain spray nozzle, the effects of four parameters, i. e. different spray pressures, different spray heights, different water temperatures, and different wall temperatures, on heat transfer have been analyzed. It is found that the mean heat flux distributions show concentric elliptical circles. Increasing spray pressures will enhance the cooling performance. Decreasing spray heights will improve the heat flux in direct spray areas other than whole simulated drum wall. As expected, reducing water temperature or advancing wall temperature will raise the average wall flux. Both relationships are exponential. The influencing degrees of the four parameters have been compared through Taguchi orthogonal experimental method and the result is: wall temperature > spray pressure > water temperature > spray height. The wall temperature, spray pressure, and water temperature show dominant effects except for the spray height.
topic Numerical Simulation
drum wall
single-nozzle
spray cooling
large scale
url http://www.doiserbia.nb.rs/img/doi/0354-9836/2018/0354-98361700243C.pdf
work_keys_str_mv AT chenzuobing numericalsimulationofsinglenozzlelargescalespraycoolingondrumwall
AT xieqiang numericalsimulationofsinglenozzlelargescalespraycoolingondrumwall
AT chengong numericalsimulationofsinglenozzlelargescalespraycoolingondrumwall
AT yuyongjie numericalsimulationofsinglenozzlelargescalespraycoolingondrumwall
AT zhaozheyu numericalsimulationofsinglenozzlelargescalespraycoolingondrumwall
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