水平宏管中饱和液氮在负表压下的流动沸腾

IF 5 2区 工程技术 Q1 ENGINEERING, MECHANICAL
Yuan Gao , Yulong Li , Zuoxia Wang , Enze Ma , Heng Yu
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引用次数: 0

摘要

本研究探讨了饱和液氮在内径为 10 毫米的水平宏管内的流动沸腾,重点是负表压的影响。实验的入口压力范围为 -79.9 至 -50.2 kPa,质量通量范围为 29.7 至 108.8 kg/(m2-s),热通量范围为 0 至 28.64 kW/m2。调查研究了两相流动模式、流动沸腾不稳定性和传热特性。将传热系数(HTC)数据与现有的四种相关性预测进行了比较,并提出了一种新的相关性。顶壁和底壁的温度分布均匀,表明环形流动普遍存在。由于液-汽密度比升高导致汽相和液相之间的速度差增大,压力降低支持形成稳定的环形流动。在入口附近的不稳定环形流以及环形流过渡到雾气和蒸汽流的间歇性干燥区,可以观察到热振荡。降低压力和增加质量通量都能最大限度地减少重力效应和提高流动惯性,从而减少热振荡。由于液滴夹带流速增加,压力降低会导致干燥型临界热通量(CHF)降低。对流蒸发被认为是主要的传热机制,在高质量通量条件下,核沸腾变得明显。压力的降低和质量通量的增加都能通过抑制热振荡和增强液汽界面的蒸发来促进流动沸腾传热。在选定的相关性中,Shah 相关性的预测精度最高,平均相对误差为 28.87%。新提出的增强因子类型模型相关性显示出更高的预测精度,平均相对误差为 14.18%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Flow boiling of saturated liquid nitrogen in a horizontal macro-tube under negative gauge pressure
This study explores the flow boiling of saturated liquid nitrogen within a 10 mm inner diameter horizontal macro-tube, focusing on the impact of negative gauge pressure. The experiments cover a range of inlet pressure from -79.9 to -50.2 kPa, mass flux from 29.7 to 108.8 kg/(m2·s), and heat flux from 0 to 28.64 kW/m2. The investigation examines two-phase flow patterns, flow boiling instabilities, and heat transfer characteristics. Heat transfer coefficient (HTC) data are compared with predictions from four existing correlations, and a novel correlation is proposed. A uniform temperature distribution across the top and bottom walls suggests a prevalence of annular flow. Decreased pressure supports the formation of stable annular flow due to increased velocity difference between vapor and liquid phases resulting from the heightened liquid-vapor density ratio. Thermal oscillations are observed in the unstable annular flow near the inlet and in the intermittent dry-out region where the annular flow transitions to mist and vapor flow. Both pressure reduction and mass flux increase reduce thermal oscillations by minimizing gravitational effects and enhancing flow inertia. A decrease in pressure results in a reduced dry-out type critical heat flux (CHF) due to increased droplet entrainment flow rate. Convective evaporation is identified as the primary heat transfer mechanism, with nucleate boiling becoming apparent at high mass flux conditions. Decrease in pressure and the increase in mass flux both facilitate flow boiling heat transfer by suppressing thermal oscillations and enhancing evaporation at the liquid-vapor interface. Among the selected correlations, the Shah correlation demonstrates the highest prediction accuracy with a mean relative error (MRE) of 28.87 %. The newly proposed enhancement factor type model correlation shows even higher prediction accuracy with an MRE of 14.18 %.
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来源期刊
CiteScore
10.30
自引率
13.50%
发文量
1319
审稿时长
41 days
期刊介绍: International Journal of Heat and Mass Transfer is the vehicle for the exchange of basic ideas in heat and mass transfer between research workers and engineers throughout the world. It focuses on both analytical and experimental research, with an emphasis on contributions which increase the basic understanding of transfer processes and their application to engineering problems. Topics include: -New methods of measuring and/or correlating transport-property data -Energy engineering -Environmental applications of heat and/or mass transfer
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