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Journals & Magazines >IEEE Transactions on Instrume... >Volume: 68 Issue: 9

A New Contactless Bubble/Slug Velocity Measurement Method of Gas–Liquid Two-Phase Flow in Small Channels

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Junchao Huang; Bixia Sheng; Haifeng Ji; Zhiyao Huang; Baoliang Wang; Haiqing Li
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Abstract:

A new contactless bubble/slug velocity measurement method of the gas-liquid two-phase flow in small channels is proposed by extending the contactless conductivity detecti...Show More

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Abstract:

A new contactless bubble/slug velocity measurement method of the gas-liquid two-phase flow in small channels is proposed by extending the contactless conductivity detection technique to the contactless impedance detection (CID) technique. Two kinds of CID sensors with different constructions (tubular construction and radial construction) are developed to obtain the total impedance information (the real part, the imaginary part, and the amplitude) of the gas-liquid two-phase flow. Two bubble/slug velocity measurement systems with different constructions, the tubular three-electrode velocity measurement system and the radial four-electrode velocity measurement system, are developed. With the obtained total impedance information, three initial estimation values of the bubble/slug velocity are determined by the principle of the cross correlation velocity measurement. Then, with the real-time flow pattern identification result implemented by the fuzzy C-means, a corresponding velocity measurement model [which is the linear combination of the three initial estimation values of the bubble/slug velocity and is developed by the penalty function method and the Davidon-Fletcher-Powell algorithm] is applied to obtain the final bubble/slug velocity. Two groups of the bubble/slug velocity measurement system prototypes with three different inner diameters are developed. The bubble/slug velocity measurement experiments are carried out. The experimental results show that the proposed method is effective. For the two bubble/slug velocity measurement systems with different constructions, the maximum relative errors of the bubble/slug velocity measurement are all less than 4.5%. The research results also indicate that making full use of the total impedance information is an effective approach to improve the accuracy of the velocity measurement.
Published in: IEEE Transactions on Instrumentation and Measurement ( Volume: 68, Issue: 9, September 2019)
Page(s): 3253 - 3267
Date of Publication: 13 November 2018

ISSN Information:

DOI: 10.1109/TIM.2018.2877825

Funding Agency:

References is not available for this document.
Contents

I. Introduction

Gas–liquid two-phase flow is an important kind of multiphase flows [1]–[6]. In the past decades, due to the advantages of high mass and heat transfer performance of small channels, the studies and applications of the gas–liquid two-phase flow in small channels have received more and more attention in many industrial fields, such as chemical engineering, pharmacy engineering, energy engineering, and environment engineering [4]–[13].

Select All
1.
G. F. Hewitt, Measurement of Two Phase Flow Parameters, New York, NY, USA:Academic, 1978.
Google Scholar
2.
G. Hetsroni, Handbook of Multiphase Systems, New York, NY, USA:McGraw-Hill, 1982.
Google Scholar
3.
G. Falcone and G. F. Hewitt, Multiphase Flow Metering, Oxford, U.K.:Elsevier, 2010.
Google Scholar
4.
C. T. Crowe, Multiphase Flow Handbook, Boca Raton, FL, USA:CRC Press, 2005.
CrossRef Google Scholar
5.
S. Haase, "Characterisation of gas-liquid two-phase flow in minichannels with co-flowing fluid injection inside the channel part I: Unified mapping of flow regimes", Int. J. Multiphase Flow, vol. 87, pp. 197-211, Dec. 2016.
CrossRef Google Scholar
6.
H. Ide, A. Kariyasaki and T. Fukano, "Fundamental data on the gas–liquid two-phase flow in minichannels", Int. J. Therm. Sci., vol. 46, no. 6, pp. 519-530, Jun. 2007.
CrossRef Google Scholar
7.
S. Kandlikar, Heat Transfer and Fluid Flow in Minichannels and Microchannels, Oxford, U.K.:Elsevier, 2005.
Google Scholar
8.
S. Arunaganesan, J. Adhavan, S. Arunkumar and M. Venkatesan, "Laser-based measurement of gas–liquid two-phase flows in micro and mini channels using multiple photodiode arrangement", Chem. Eng. Commun., vol. 204, no. 3, pp. 337-347, 2017.
CrossRef Google Scholar
9.
C. W. Fernandes, M. D. Bellar and M. M. Werneck, "Cross-correlation-based optical flowmeter", IEEE Trans. Instrum. Meas., vol. 59, no. 4, pp. 840-846, Apr. 2010.
View Article
Google Scholar
10.
R. Revellin, B. Agostini, T. Ursenbacher and J. R. Thome, "Experimental investigation of velocity and length of elongated bubbles for flow of R-134a in a 0.5 mm microchannel", Exp. Therm. Fluid Sci., vol. 32, no. 3, pp. 870-881, Jan. 2008.
CrossRef Google Scholar
11.
W. Kracht and J. A. Finch, "Effect of frother on initial bubble shape and velocity", Int. J. Mineral Process., vol. 94, no. 3, pp. 115-120, Apr. 2010.
CrossRef Google Scholar
12.
H. Ji, H. Li, Z. Huang, B. Wang and H. Li, "Measurement of gas-liquid two-phase flow in micro-pipes by a capacitance sensor", Sensors, vol. 14, no. 12, pp. 22431-22446, Dec. 2014.
CrossRef Google Scholar
13.
J. Huang, H. Ji, Z. Huang, B. Wang and H. Li, "A new contactless method for velocity measurement of bubble and slug in millimeter-scale pipelines", IEEE Access, vol. 5, pp. 12168-12175, 2017.
View Article
Google Scholar
14.
X. Dong, C. Tan and F. Dong, "Gas–liquid two-phase flow velocity measurement with continuous wave ultrasonic Doppler and conductance sensor", IEEE Trans. Instrum. Meas., vol. 66, no. 11, pp. 3064-3076, Nov. 2017.
View Article
Google Scholar
15.
G. Lucas, X. Zhao and S. Pradhan, "Optimisation of four-sensor probes for measuring bubble velocity components in bubbly air–water and oil–water flows", Flow Meas. Instrum., vol. 22, no. 1, pp. 50-63, Mar. 2011.
CrossRef Google Scholar
16.
M. Bressani and R. A. Mazza, "Two-phase slug flow through an upward vertical to horizontal transition", Exp. Therm. Fluid Sci., vol. 91, pp. 245-255, Feb. 2018.
CrossRef Google Scholar
17.
B. Wang, Y. Zhou, H. Ji, Z. Huang and H. Li, " Measurement of bubble velocity using capacitively coupled contactless conductivity detection ( text{C}^{4}text{D} ) technique ", Particuology, vol. 11, no. 2, pp. 198-203, Apr. 2013.
CrossRef Google Scholar
18.
P. Kubáň and P. C. Hauser, "Contactless conductivity detection for analytical techniques—Developments from 2012to 2014", Electrophoresis, vol. 36, no. 1, pp. 195-211, Aug. 2015.
CrossRef Google Scholar
19.
P. Kubáň and P. C. Hauser, "Contactless conductivity detection for analytical techniques—Developments from 2012 to 2014", Electrophoresis, vol. 38, no. 1, pp. 114-195, Jan. 2017.
CrossRef Google Scholar
20.
A. J. Zemann, E. Schnell, D. Volgger and G. K. Bonn, "Contactless conductivity detection for capillary electrophoresis", Anal. Chem., vol. 70, no. 3, pp. 563-567, 1998.
CrossRef Google Scholar
21.
J. A. F. da Silva and C. L. do Lago, "An oscillometric detector for capillary electrophoresis", Anal. Chem., vol. 70, no. 20, pp. 4339-4343, 1998.
CrossRef Google Scholar
22.
P. Valiorgue, S. N. Ritchey, J. A. Weibel and S. V. Garimella, "Design of a non-intrusive electrical impedance-based void fraction sensor for microchannel two-phase flows", Meas. Sci. Technol., vol. 25, no. 9, pp. 095301-095311, Sep. 2014.
CrossRef Google Scholar
23.
S. L. Ceccio and D. L. George, "A review of electrical impedance techniques for the measurement of multiphase flows", J. Fluids Eng., vol. 118, no. 2, pp. 391-399, Jun. 1996.
CrossRef Google Scholar
24.
B. P. Cahill, R. Land, T. Nacke, M. Min and D. Beckmann, "Contactless sensing of the conductivity of aqueous droplets in segmented flow", Sens. Actuators B Chem., vol. 159, no. 1, pp. 286-293, Nov. 2011.
CrossRef Google Scholar
25.
H. Ji, Y. Chang, Z. Huang, B. Wang and H. Li, "Voidage measurement of gas–liquid two-phase flow based on capacitively coupled contactless conductivity detection", Flow Meas. Instrum., vol. 40, pp. 199-205, Dec. 2014.
CrossRef Google Scholar
26.
L. Wang, Z. Huang, B. Wang, H. Ji and H. Li, "Flow pattern identification of gas–liquid two-phase flow based on capacitively coupled contactless conductivity detection", IEEE Trans. Instrum. Meas., vol. 61, no. 5, pp. 1466-1475, May 2012.
View Article
Google Scholar
27.
H. Ji, Y. Chang, Z. Huang, B. Wang and H. Li, "A new contactless impedance sensor for void fraction measurement of gas–liquid two-phase flow", Meas. Sci. Technol., vol. 27, no. 12, pp. 124001-124010, Dec. 2016.
CrossRef Google Scholar
28.
S. Paranjape, S. N. Ritchey and S. V. Garimella, "Electrical impedance-based void fraction measurement and flow regime identification in microchannel flows under adiabatic conditions", Int. J. Multiphase Flow, vol. 42, pp. 175-183, Jun. 2012.
CrossRef Google Scholar
29.
M. Wang, W. Yin and N. Holliday, "A highly adaptive electrical impedance sensing system for flow measurement", Meas. Sci. Technol., vol. 13, no. 12, pp. 1884-1889, Dec. 2002.
CrossRef Google Scholar
30.
M. S. Beck and A. Plaskowski, Cross Correlation Flowmeters-Their Design and Application, Bristoln, U.K.:Adam Hilger, 1987.
Google Scholar
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