STRUCTURE OF AIR WATER BUBBLY FLOW IN A VERTICAL PIPE .2. VOID FRACTION, BUBBLE VELOCITY AND BUBBLE-SIZE DISTRIBUTION

被引:166
作者
LIU, TJ [1 ]
BANKOFF, SG [1 ]
机构
[1] NORTHWESTERN UNIV,DEPT CHEM ENGN,EVANSTON,IL 60208
来源
INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER | 1993年 / 36卷 / 04期
基金
美国国家科学基金会;
关键词
D O I
10.1016/S0017-9310(05)80290-X
中图分类号
O414.1 [热力学];
学科分类号
摘要
In a companion paper (Liu and Bankoff. Int. J. Heat Mass Transfer 36, 1049-1060 (1993)) measurements were presented of liquid-phase velocity and turbulence properties in air-water bubbly upflow under a range of flow conditions. In this paper measurements of the radial profiles of void fraction, bubble velocity and bubbly size, using a miniature dual-sensor resistivity probe, under the same conditions are presented. A new digital processing method, based on threshold combinations of level and slope, was developed for phase identification by the resistivity probe. Local mean bubble sizes ranged from 2 to 4 mm. The profiles of void fraction, bubble frequency and bubble size are found to show distinct peaks near the wall, becoming flat at the core. Experimental findings and parametric trends based on the effects of superficial velocities of both phases are summarized and discussed.
引用
收藏
页码:1061 / 1072
页数:12
相关论文
共 50 条
[31]   Air bubble entrainment in open channels: Flow structure and bubble size distributions [J].
Chanson, H .
INTERNATIONAL JOURNAL OF MULTIPHASE FLOW, 1997, 23 (01) :193-203
[32]   Measuring void fraction in vertical air-water bubbly flow using echo intensity and visualization techniques [J].
Na, Geoseong ;
Park, Ji-Hwan ;
Jo, Hongrae ;
Jo, Daeseong .
PROGRESS IN NUCLEAR ENERGY, 2021, 136
[33]   Experimental investigation on void fraction radial distribution for bubbly flow in vertical circular tube [J].
Xing, Dian-Chuan ;
Sun, Li-Cheng ;
Yan, Chang-Qi ;
Tian, Dao-Gui .
Yuanzineng Kexue Jishu/Atomic Energy Science and Technology, 2013, 47 (02) :233-237
[34]   A probability model for predicting the bubble size distribution in fully developed bubble flow in vertical pipes [J].
Liu, Haixiao ;
Tian, Tao ;
Kang, Rong .
INTERNATIONAL COMMUNICATIONS IN HEAT AND MASS TRANSFER, 2021, 120
[35]   Monitoring of Void Fraction and Bubble Size in Narrow-Channel Bubbly-Flows Using Ultrasonic Pulses With a Super Bubble-Resonant Frequency [J].
Park, Hyun Jin ;
Akasaka, Shintaro ;
Tasaka, Yuji ;
Murai, Yuichi .
IEEE SENSORS JOURNAL, 2021, 21 (01) :273-283
[36]   INVESTIGATION OF 3-PHASE FLUIDIZED SYSTEMS .2. THE EFFECT OF DISTRIBUTOR TYPE AND FLOW CONDITIONS ON THE PARAMETERS OF BUBBLE-SIZE DISTRIBUTION [J].
SISAK, C ;
ORMOS, Z .
HUNGARIAN JOURNAL OF INDUSTRIAL CHEMISTRY, 1985, 13 (04) :503-519
[37]   Measurement of Void Fraction by Using Electrical Capacitance Sensor and Differential Pressure in Air-Water Bubble Flow [J].
Shafquet, Areeba ;
Ismail, I. .
2012 4TH INTERNATIONAL CONFERENCE ON INTELLIGENT AND ADVANCED SYSTEMS (ICIAS), VOLS 1-2, 2012, :576-581
[38]   Gas liquid flow of sub-millimeter bubbles at low void fractions: Experimental study of bubble size distribution and void fraction [J].
Evgenidis, Sotiris P. ;
Karapantsios, Thodoris D. .
INTERNATIONAL JOURNAL OF HEAT AND FLUID FLOW, 2018, 71 :353-365
[39]   Air-water properties of unsteady breaking bore part 2: Void fraction and bubble statistics [J].
Shi, Rui ;
Wuthrich, Davide ;
Chanson, Hubert .
INTERNATIONAL JOURNAL OF MULTIPHASE FLOW, 2023, 159
[40]   Bubble size distribution for bubbly-to-slug transition flow in narrow rectangular channel [J].
Zhang, Muhao ;
Mi, Tao ;
Huang, Tao ;
Deng, Jian ;
He, Qingche ;
Gu, Zhixing ;
Zhang, Luteng ;
Ding, Shuhua ;
Pan, Liangming .
NUCLEAR ENGINEERING AND DESIGN, 2022, 391
12345