Transient heat transfer characteristics of air-array-jet impingement with different nozzle arrangements on high-temperature flat plate in small jet-to-plate distance

被引：0

作者：

LI Meixiang ^{[1
,2
,3
]}

ZHU Keqian ^{[1
,2
,3
]}

XIE Yu ^{[1
]}

CAI Tingting ^{[1
,2
,3
]}

YUAN Ningyi ^{[1
,2
,3
]}

DING Jianning ^{[1
,2
,3
,4
]}

机构：

[1] School of Mechanical Engineering,Changzhou University

[2] Jiangsu Collaborative Innovation Center for Photovoltaic Science and Engineering

[3] Jiangsu Province Cultivation Base for State Key Laboratory of Photovoltaic Science and Technology

[4] School of Mechanical Engineering,Jiangsu University

来源：

排灌机械工程学报 | 2020年 / 38卷 / 03期

关键词：

glass tempering; low jet-to-plate distances; array jet impingement; nozzles arrangement; transient heat transfer;

D O I：

暂无

中图分类号：

TQ171.1 [基础理论];

学科分类号：

0805 ; 080502 ;

摘要：

Numerical studies on transient heat transfer characteristics of air-array-jet impingement with a small jet-to-plate distance and a large temperature difference between nozzles and plate were presented. The dimensionless jet-to-plate distance( H/D) was 0. 2,and non-dimensional nozzle-to-nozzle spacing( S/D) was 3,4,5 and 6,respectively. It is found that the quenching time is shortened at a constant total mass flow at air jet inlet ■( ■= 218.21 kg/h),and the heat transfer uniformity is deteriorated as S/D increases. However,the adding reversed-flow nozzles can shorten the quenching time of the glass plate considerably with a modest change in the heat transfer uniformity. The results at variable ■ are the same as those at a fixed ■. Furthermore,the parity and arrangement of nozzles are also discussed,It is found that an odd number of nozzles is more beneficial for transient heat transfer. Based on these results,an appropriate proposal for ultra-thin glass tempering process is presented.

引用

页码：277 / 284

页数：8

共 26 条

[1] Numerical analysis of turbulent round jet impingement heat transfer at high temperature difference[J] . Taotao Zhou,Dong Xu,Jing Chen,Changmin Cao,Taohong Ye. &nbspApplied Thermal Engineering . 2016
[2] Numerical analysis of turbulent round jet impingement heat transfer at high temperature difference[J] . Taotao Zhou,Dong Xu,Jing Chen,Changmin Cao,Taohong Ye. &nbspApplied Thermal Engineering . 2016
[3] An in-depth analysis of conjugate heat transfer process of impingement jet[J] . Xiao Wei Zhu,Lei Zhu,Jing Quan Zhao. &nbspInternational Journal of Heat and Mass Transfer . 2017
[4] An in-depth analysis of conjugate heat transfer process of impingement jet[J] . Xiao Wei Zhu,Lei Zhu,Jing Quan Zhao. &nbspInternational Journal of Heat and Mass Transfer . 2017
[5] Effects of Jet-to-Jet Spacing and Jet Height on Heat Transfer Characteristics of an Impinging Jet Array. San J Y,Chen J J. International Journal of Heat and Mass Transfer . 2014
[6] Effects of Jet-to-Jet Spacing and Jet Height on Heat Transfer Characteristics of an Impinging Jet Array. San J Y,Chen J J. International Journal of Heat and Mass Transfer . 2014
[7] Influence of nozzle arrangement on flow and heat transfer characteristics of arrays of circular impinging jets. Makatar W H,Perapong T,Chayut N. Songklanakarin Journal of Science and Technology . 2013
[8] Influence of nozzle arrangement on flow and heat transfer characteristics of arrays of circular impinging jets. Makatar W H,Perapong T,Chayut N. Songklanakarin Journal of Science and Technology . 2013
[9] Heat transfer and hydrodynamics of free water jet impingement at low nozzle-to-plate spacings[J] . Abdullah M. Kuraan,Stefan I. Moldovan,Kyosung Choo. &nbspInternational Journal of Heat and Mass Transfer . 2017
[10] Heat transfer and hydrodynamics of free water jet impingement at low nozzle-to-plate spacings[J] . Abdullah M. Kuraan,Stefan I. Moldovan,Kyosung Choo. &nbspInternational Journal of Heat and Mass Transfer . 2017

← 1 2 3 →