Void Fraction Measurement in Oil-Gas Transportation Pipeline Using an Improved Electrical Capacitance Tomography System

• TRANSPORT PHENOMENA & FLUID MECHANICS • Previous Articles Next Articles

Void Fraction Measurement in Oil-Gas Transportation Pipeline Using an Improved Electrical Capacitance Tomography System

NIU Gang; JIA Zhihai; WANG Jing

School of Mechanical Engineering, Shanghai Jiaotong University, Shanghai 200030, China

Received:1900-01-01 Revised:1900-01-01 Online:2004-08-28 Published:2004-08-28
Contact: NIU Gang

用改进ECT技术测定油气两相流中空泡分数的测量研究

牛刚; 贾志海; 王经

School of Mechanical Engineering, Shanghai Jiaotong University, Shanghai 200030, China

通讯作者: 牛刚

Abstract

Abstract: To measure the void fraction online in oil-gas pipeline, an improved electrical capacitance tomography (ECT) system has been designed. The capacitance sensor with new structure has twelve internal electrodes and overcomes the influence of the pipe wall. The data collection system is improved by using high performance IC (integrated circuit). Static tests of bubble flow, stratified flow and annular flow regime are carried out. Measurements are taken on bubble flow, stratified flow and slug flow. Results show that the new ECT system performs well on void fraction measurement of bubble flow and stratified flow, but the error of measurement for slug flow is more than 10%.

Key words: electrical capacitance tomography, void fraction, measurement, oil-gas transportation

摘要： To measure the void fraction online in oil-gas pipeline, an improved electrical capacitance tomography (ECT) system has been designed. The capacitance sensor with new structure has twelve internal electrodes and overcomes the influence of the pipe wall. The data collection system is improved by using high performance IC (integrated circuit). Static tests of bubble flow, stratified flow and annular flow regime are carried out. Measurements are taken on bubble flow, stratified flow and slug flow. Results show that the new ECT system performs well on void fraction measurement of bubble flow and stratified flow, but the error of measurement for slug flow is more than 10%.

关键词: 空隙组分;测量方法;油气运输系统;油管;电容;ECT

NIU Gang, JIA Zhihai, WANG Jing. Void Fraction Measurement in Oil-Gas Transportation Pipeline Using an Improved Electrical Capacitance Tomography System[J]. .

牛刚,贾志海,王经. 用改进ECT技术测定油气两相流中空泡分数的测量研究[J]. CIESC Journal.

[1]	Xianheng YI, Wu ZHOU, Xiaoshu CAI, Tianyi CAI. Measurable range of nanoparticle concentration using optical fiber backward dynamic light scattering [J]. CIESC Journal, 2023, 74(8): 3320-3328.
[2]	Qichao LIU, Yunlong ZHOU, Cong CHEN. Analysis and calculation of void fraction of gas-liquid two-phase flow in vertical riser under fluctuating vibration [J]. CIESC Journal, 2023, 74(6): 2391-2403.
[3]	Junxian CHEN, Zhongli JI, Yu ZHAO, Qian ZHANG, Yan ZHOU, Meng LIU, Zhen LIU. Study on online detection method of particulate matter in natural gas pipeline based on microwave technology [J]. CIESC Journal, 2023, 74(3): 1042-1053.
[4]	Yongqian WANG, Ping WANG, Kang CHENG, Chenlin MAO, Wenfeng LIU, Zhicheng YIN, Antonio Ferrante. Stability and NO production of lean premixed ammonia/methane turbulent swirling flame [J]. CIESC Journal, 2022, 73(9): 4087-4094.
[5]	Biqiang LIU, Haishan CAO. Adsorption measurement method based on flow calibration and its error analysis [J]. CIESC Journal, 2022, 73(4): 1597-1605.
[6]	Wenjie LAN, Xiaojie HU, Dizong CAI. Determination of interaction force between droplet and solid surface using droplet probe [J]. CIESC Journal, 2022, 73(3): 1119-1126.
[7]	Yukun SUN, Tao YANG, Jiangtao WU. Measurement of vapor-liquid equilibrium for R32+R1234yf+R1234ze(E) [J]. CIESC Journal, 2022, 73(3): 1063-1071.
[8]	Jiaqing ZHANG, Zhaohui LIU, Yu LI, Chenyang SONG. Viscosity measurements and prediction model construction for liquid JP-10 at high-temperature conditions [J]. CIESC Journal, 2022, 73(1): 153-161.
[9]	Teng WANG, Qincheng BI, Miao GUI, Zhaohui LIU. Experimental study on void fraction distribution in liquid slug of vertical upward slug flow [J]. CIESC Journal, 2021, 72(9): 4584-4593.
[10]	HUANG Zhengliang, WANG Chao, GUO Yanni, YANG Yao, SUN Jingyuan, WANG Jingdai, YANG Yongrong. Investigation of secondary flow in helical coils based on residence time distribution [J]. CIESC Journal, 2021, 72(2): 921-927.
[11]	WANG Kai, DU Wenli, LONG Jian. Online adaptive wavelength selection method and its application in gasoline blending process [J]. CIESC Journal, 2021, 72(2): 1059-1066.
[12]	Jiyizhe ZHANG, Yundong WANG, Weiyang FEI. A states-of-the-art review on research progresses and prospects of liquid-liquid extraction columns [J]. CIESC Journal, 2021, 72(12): 6016-6029.
[13]	Chengzhi HUANG,Haibo TANG,Tian GU,Yugang ZHAO. Characterizing the temperature profile near contact lines of an evaporating sessile drop [J]. CIESC Journal, 2021, 72(10): 5142-5149.
[14]	Shaozhi ZHANG, Yang LI, Yiyang XU, Youming ZHENG, Tian LUAN, Heng LU. Freeze-drying monitoring technology of cultural relics based on infrared temperature measurement [J]. CIESC Journal, 2020, 71(S1): 245-251.
[15]	Lulu SHI. Research of multi-stage temperature control system in large-sized aircraft cabin zone [J]. CIESC Journal, 2020, 71(S1): 322-327.