基于流量振荡的窄矩形通道内临界热通量机理模型

Mechanism model of critical heat flux in narrow rectangular channel based on flow oscillations

在线阅读下载PDF

导出

摘要设备最大运行功率受临界热通量(CHF)限制,而流量振荡会导致沸腾危机早发,此时的临界热通量称为PM-CHF。为了研究流量振荡条件下窄矩形通道内的临界热通量,进行单侧加热窄矩形通道内竖直向上流动条件下沸腾危机可视化实验,实验工质为去离子水,质量流速范围为350~2000 kg/(m^(2)·s),窄缝宽度范围为1~5 mm,系统压力范围为1~4 MPa。结果显示,在窄矩形通道中CHF随质量流速的增加而线性增加。当流速较小时会发生流量振荡,振荡周期约为0.1 s。流量振荡继而导致沸腾危机早发,其流型表现为弹状流-搅混流。此外,针对本实验观察到的流量振荡和窄矩形通道内气泡动力学特性,从流量振荡的角度进行理论分析与推导,建立窄矩形通道内由于流动失稳引起的PM-CHF机理模型,预测误差在30%以内。 The maximum operating power of the device is limited by the critical heat flux(CHF), however, the flow oscillation can cause premature critical heat flux(called PM-CHF) and reduce the stable operating range. In order to study the critical heat flux in a narrow rectangular channel under flow oscillation conditions, this paper conducted experiments to visualize the boiling crisis in a narrow rectangular channel under vertical upward flow condition with deionized water as the working medium, with mass flux range of 350—2000 kg/(m^(2)·s), narrow gap size range of 1—5 mm, and system pressure range of 1—4 MPa. The results show that CHF increases linearly with increasing mass flow rate in the narrow rectangular channel. The flow oscillation occurs when the mass flux is small, and the oscillation period is about 0.1 s. The flow oscillation leads to the early onset of boiling crisis, during which the flow pattern is slug-churn flow. Based on the flow oscillation and the bubble dynamics characteristics in the narrow rectangular channel, the theoretical analysis and derivation are carried out from the perspective of flow oscillation.In results, a PM-CHF mechanism model is established, and the error is within 30%.

作者闫美月邓坚潘良明马在勇李想邓杰文何清澈 YAN Meiyue;DENG Jian;PAN Liangming;MA Zaiyong;LI Xiang;DENG Jiewen;HE Qingche(Key Laboratory of Low-grade Energy Utilization Technologies and Systems,Ministry of Education,Chongqing University,Chongqing 400044,China;Science and Technology on Reactor System Design Technology Laboratory,Nuclear Power Institute of China,Chengdu 610041,Sichuan,China)

机构地区重庆大学低品位能源利用技术及系统教育部重点实验室中国核动力研究设计院反应堆系统设计技术重点实验室

出处《化工学报》 EI CAS CSCD 北大核心 2022年第7期2962-2970,共9页 CIESC Journal

基金国家重点研发计划项目(02120023710003) 重庆市研究生科研创新项目(CYB21023)。

关键词窄矩形通道 PM-CHF 两相流流域气泡 narrow rectangular channel PM-CHF two-phase flow flow regime bubble

分类号 TL334 [核科学技术—核技术及应用]

作者简介第一作者:闫美月(1993-),女,博士研究生,yanmeiyue@cqu.edu.cn;通信作者:潘良明(1970-),男,博士,教授,cneng@cqu.edu.cn。

引文网络
相关文献

参考文献2

1盛程,周涛,张蕾,肖泽军,黄彦平.窄矩形通道自然循环流动停滞与临界热流密度研究[J].核科学与工程,2013,33(1):65-75. 被引量：4
2陈娟,周涛,齐实,马栋梁,肖泽军.矩形通道自然循环流动不稳定性实验研究[J].核动力工程,2017,38(2):51-55. 被引量：6

二级参考文献20

1谭思超,庞凤阁,高璞珍.自然循环过冷沸腾流动不稳定性实验研究[J].核动力工程,2006,27(1):18-21. 被引量：6
2王艳林,黄彦平,卢冬华.矩形窄缝通道流动不稳定起始现象实验研究[J].核动力工程,2007,28(2):28-32. 被引量：7
3欧阳首承.走进非规则[M].北京:气象出版社,2002..
4Wu Zan,Li Wei.A new predictive tool for saturatedcritical heat flux in micro/mini-channels:Effect of theheated length-to-diameter ratio[J].InternationalJournal of Heat and Mass Transfer,2011,54(13/14):2880-2889.
5Hsieh S S,Lin C Y.Correlation of critical heat flux andtwo-phase friction factor for subcooled convective boilingin structured surface microchannels[J].InternationalJournal of Heat and Mass Transfer,2012,55(1/3):32-42.
6Sudo Y,Kaminaga M.Critical heat flux at high velocitychannel flow with high subcooling[J].NuclearEngineering Design,1998,187(2):215-227.
7Du D X,Tian W X,Su G H,et al.Theoretical studyon the characteristics of critical heat flux in verticalnarrow rectangular channels[J].Applied ThermalEngineering,2012,36(1):21-31.
8Jones R C,Judd R L.An investigation of dryout/rewetting in subcooled two-phase flow boiling[J].International Journal of Heat and Mass Transfer,2003,46(17):3143-3152.
9Okawa T,Goto T,Yamagoe Y.Liquid film behavior inannular two-phase flow under flow oscillation conditions[J].International Journal of Heat and Mass Transfer,2010,53(5/6):962-971.
10Park H S,Choi K Y,Cho S,et al.Experimentalinvestigations on the heat transfer characteristics in anatural circulation loop for an integral type reactor[J].International Communications in Heat and MassTransfer,2011,38(9):1232-1238.

共引文献8

1盛程.自然循环CHF影响因素的灰色关联度分析[J].山东电力技术,2015,42(2):15-17.
2盛程.自然循环欠热沸腾起始点发生的混沌特性分析[J].黑龙江电力,2015,37(2):126-129.
3周涛,齐实,宋明强,陈柏旭,黄彦平,肖泽军.窄矩形通道内低压两相自然循环流量漂移实验研究[J].核动力工程,2016,37(4):1-5. 被引量：2
4张文超,焦琦,周云龙,杨美,金光远,杜利鹏.矩形通道内低压自然循环压降型脉动及其复合型脉动可视化研究[J].化工学报,2018,69(6):2455-2462.
5周涛,朱亮宇,陈杰,张家磊,黄彦平.自然循环参数稳态变化计算研究[J].华电技术,2019,41(1):9-12. 被引量：1
6陈楹,阮琳,曾向君.表贴式自循环蒸发冷却系统流动不稳定性实验平台设计[J].科学技术与工程,2020,20(13):5123-5128. 被引量：2
7胡钰文,闫晓,宫厚军,王艳林,周磊.耦合传热并联矩形通道流动不稳定性数值研究[J].清华大学学报（自然科学版）,2023,63(8):1257-1263.
8郝承明,徐慧天,喻巧,曲自信,夏军宝,孙冠宇,张皓,颉利东,王艺.一回路自然循环优化研究[J].应用科技,2024,51(4):36-42.

1刘正阳,付婷,曾良才,伍妮妮,马世泽.微沟槽铜板沸腾换热特性实验研究[J].武汉科技大学学报,2022,45(4):263-271. 被引量：2
2钟达文,史昊鹏,孟继安,秦天骄,张显,刘赟.加热面朝下的池沸腾汽泡动态行为研究[J].原子能科学技术,2020,54(10):1795-1800. 被引量：1

化工学报

2022年第7期

浏览历史

内容加载中请稍等...

基于流量振荡的窄矩形通道内临界热通量机理模型

参考文献2

二级参考文献20

共引文献8

相关作者

相关机构

相关主题

浏览历史