Simultaneous measurement of velocity profile and liquid film thickness in horizontal gas-liquid slug flow by using ultrasonic Doppler method

doi:10.1016/j.cjche.2023.02.010

Abstract

Abstract: Horizontal gas-liquid two-phase flows widely exist in chemical engineering, oil/gas production and other important industrial processes. Slug flow pattern is the main form of horizontal gas-liquid flows and characterized by intermittent motion of film region and slug region. This work aims to develop the ultrasonic Doppler method to realize the simultaneous measurement of the velocity profile and liquid film thickness of slug flow. A single-frequency single-channel transducer is adopted in the design of the field-programmable gate array based ultrasonic Doppler system. A multiple echo repetition technology is used to improve the temporal-spatial resolution for the velocity profile. An experiment of horizontal gas-liquid two-phase flow is implemented in an acrylic pipe with an inner diameter of 20 mm. Considering the aerated characteristics of the liquid slug, slug flow is divided into low-aerated slug flow, high-aerated slug flow and pseudo slug flow. The temporal-spatial velocity distributions of the three kinds of slug flows are reconstructed by using the ultrasonic velocity profile measurement. The evolution characteristics of the average velocity profile in slug flows are investigated. A novel method is proposed to derive the liquid film thickness based on the instantaneous velocity profile. The liquid film thickness can be effectively measured by detecting the position and the size of the bubbles nearly below the elongated gas bubble. Compared with the time of flight method, the film thickness measured by the Doppler system shows a higher accuracy as a bubble layer occurs in the film region. The effect of the gas distribution on the film thickness is uncovered in three kinds of slug flows.

Key words: Gas-liquid flow, Complex fluids, Measurement, Ultrasonic Doppler, Velocity profile, Liquid film thickness

摘要： Horizontal gas-liquid two-phase flows widely exist in chemical engineering, oil/gas production and other important industrial processes. Slug flow pattern is the main form of horizontal gas-liquid flows and characterized by intermittent motion of film region and slug region. This work aims to develop the ultrasonic Doppler method to realize the simultaneous measurement of the velocity profile and liquid film thickness of slug flow. A single-frequency single-channel transducer is adopted in the design of the field-programmable gate array based ultrasonic Doppler system. A multiple echo repetition technology is used to improve the temporal-spatial resolution for the velocity profile. An experiment of horizontal gas-liquid two-phase flow is implemented in an acrylic pipe with an inner diameter of 20 mm. Considering the aerated characteristics of the liquid slug, slug flow is divided into low-aerated slug flow, high-aerated slug flow and pseudo slug flow. The temporal-spatial velocity distributions of the three kinds of slug flows are reconstructed by using the ultrasonic velocity profile measurement. The evolution characteristics of the average velocity profile in slug flows are investigated. A novel method is proposed to derive the liquid film thickness based on the instantaneous velocity profile. The liquid film thickness can be effectively measured by detecting the position and the size of the bubbles nearly below the elongated gas bubble. Compared with the time of flight method, the film thickness measured by the Doppler system shows a higher accuracy as a bubble layer occurs in the film region. The effect of the gas distribution on the film thickness is uncovered in three kinds of slug flows.

关键词: Gas-liquid flow, Complex fluids, Measurement, Ultrasonic Doppler, Velocity profile, Liquid film thickness

Lusheng Zhai, Bo Xu, Haiyan Xia, Ningde Jin. Simultaneous measurement of velocity profile and liquid film thickness in horizontal gas-liquid slug flow by using ultrasonic Doppler method[J]. Chinese Journal of Chemical Engineering, 2023, 58(6): 323-340.

References

[1] K.W. Xu, Y.C. Zhang, D. Liu, A.N. Azman, H.B. Kim, Slug flow development study in a horizontal pipe using particle image velocimetry, Int. J. Heat Mass Transf. 162 (2020) 120267.
[2] S. Miao, K. Hendrickson, Y.M. Liu, Slug generation processes in co-current turbulent-gas/laminar-liquid flows in horizontal channels, J. Fluid Mech. 860 (2019) 224-257.
[3] J. Leonel Gonçalves, R.A. Mazza, A transient analysis of slug flow in a horizontal pipe using slug tracking model: Void and pressure wave, Int. J. Multiph. Flow 149 (2022) 103972.
[4] M. Furuya, T. Kanai, T. Arai, H. Takiguchi, H.M. Prasser, U. Hampel, E. Schleicher, Three-dimensional velocity vector determination algorithm for individual bubble identified with Wire-Mesh Sensors, Nucl. Eng. Des. 336 (2018) 74-79.
[5] R.G. Morgan, C.N. Markides, I. Zadrazil, G.F. Hewitt, Characteristics of horizontal liquid-liquid flows in a circular pipe using simultaneous high-speed laser-induced fluorescence and particle velocimetry, Int. J. Multiph. Flow 49 (2013) 99-118.
[6] S.G. Nnabuife, P. Sharma, E. Iyore Aburime, P.L. Lokidor, A. Bello, Development of gas-liquid slug flow measurement using continuous-wave Doppler ultrasound and bandpass power spectral density, ChemEngineering 5 (1) (2021) 2.
[7] C. Tan, Y. Murai, W.L. Liu, Y. Tasaka, F. Dong, Y. Takeda, Ultrasonic Doppler technique for application to multiphase flows: A review, Int. J. Multiph. Flow 144 (2021) 103811.
[8] S. Ricci, V. Meacci, B. Birkhofer, J. Wiklund, FPGA-based system for in-line measurement of velocity profiles of fluids in industrial pipe flow, IEEE Trans. Ind. Electron. 64 (5) (2017) 3997-4005.
[9] D.W. Baker, Pulsed ultrasonic Doppler blood-flow sensing, IEEE Trans. Sonics Ultrason. 17 (3) (1970) 170-184.
[10] Y. Takeda, Velocity profile measurement by ultrasound Doppler shift method, Int. J. Heat Fluid Flow 7 (4) (1986) 313-318.
[11] Y. Takeda, Development of an ultrasound velocity profile monitor, Nucl. Eng. Des. 126 (2) (1991) 277-284.
[12] Y. Takeda, Velocity profile measurement by ultrasonic Doppler method, Exp. Therm. Fluid Sci. 10 (4) (1995) 444-453.
[13] M. Mori, Y. Takeda, T. Taishi, N. Furuichi, M. Aritomi, H. Kikura, Development of a novel flow metering system using ultrasonic velocity profile measurement, Exp. Fluids 32 (2) (2002) 153-160.
[14] Y. Takeda, Measurement of velocity profile of mercury flow by ultrasound Doppler shift method, Nucl. Technol. 79 (1) (1987) 120-124.
[15] S. Wada, H. Kikura, M. Aritomi, M. Mori, Y. Takeda, Development of pulse ultrasonic Doppler method for flow rate measurement in power plant multilines flow rate measurement on metal pipe, J. Nucl. Sci. Technol. 41 (3) (2004) 339-346.
[16] B. Birkhofer, T. Meile, G. De Cesare, S.A.K. Jeelani, E.J. Windhab, Use of gas bubbles for ultrasound Doppler flow velocity profile measurement, Flow Meas. Instrum. 52 (2016) 233-239.
[17] M. Aritomi, S.R. Zhou, M. Nakajima, Y. Takeda, M. Mori, Y. Yoshioka, Measurement system of bubbly flow using ultrasonic velocity profile monitor and video data processing unit, J. Nucl. Sci. Technol. 33 (12) (1996) 915-923.
[18] H. Nakamura, M. Kondo, Y. Kukita, Simultaneous measurement of liquid velocity and interface profiles of horizontal duct wavy flow by ultrasonic velocity profile meter, Nucl. Eng. Des. 184 (2-3) (1998) 339-348.
[19] F.C. Liang, Z.J. Fang, J. Chen, S.T. Sun, Investigating the liquid film characteristics of gas-liquid swirling flow using ultrasound Doppler velocimetry, AIChE J. 63 (6) (2017) 2348-2357.
[20] B.M. Abbagoni, H. Yeung, L.Y. Lao, Non-invasive measurement of oil-water two-phase flow in vertical pipe using ultrasonic Doppler sensor and gamma ray densitometer, Chem. Eng. Sci. 248 (2022) 117218.
[21] L.D. Fang, Y.Y. Liu, S.C. Wang, J.X. Zhao, Y. Faraj, M.Y. Tian, Z.H. Wei, Dual-modality UDV-PIV system for measurement of solid-liquid flow in sewage facilities, Flow Meas. Instrum. 82 (2021) 102063.
[22] Y. Ozaki, T. Kawaguchi, Y. Takeda, K. Hishida, M. Maeda, High time resolution ultrasonic velocity profiler, Exp. Therm. Fluid Sci. 26 (2-4) (2002) 253-258.
[23] H. Kikura, G. Yamanaka, M. Aritomi, Effect of measurement volume size on turbulent flow measurement using ultrasonic Doppler method, Exp. Fluids 36 (1) (2004) 187-196.
[24] H. Murakawa, K. Sugimoto, N. Takenaka, Effects of the number of pulse repetitions and noise on the velocity data from the ultrasonic pulsed Doppler method with different algorithms, Flow Meas. Instrum. 40 (2014) 9-18.
[25] H. Murakawa, E. Muramatsu, K. Sugimoto, N. Takenaka, N.Furuichi, A dealiasing method for use with ultrasonic pulsed Doppler in measuring velocity profiles and flow rates in pipes, Meas. Sci. Technol. 26 (8) (2015) 085301.
[26] S. Wada, N. Furuichi, T. Shimada, Development of ultrasonic pulse-train Doppler method for velocity profile and flowrate measurement, Meas. Sci. Technol. 27 (11) (2016) 115302.
[27] E. Muramatsu, H. Murakawa, K. Sugimoto, H. Asano, N. Takenaka, N. Furuichi, Multi-wave ultrasonic Doppler method for measuring high flow-rates using staggered pulse intervals, Meas. Sci. Technol. 27 (2) (2016) 025303.
[28] S.G. Nnabuife, K.E.S. Pilario, L.Y. Lao, Y. Cao, M. Shafiee, Identification of gas-liquid flow regimes using a non-intrusive Doppler ultrasonic sensor and virtual flow regime maps, Flow Meas. Instrum. 68 (2019) 101568.
[29] S.Q. Wang, K.W. Xu, H.B. Kim, Slug flow identification using ultrasound Doppler velocimetry, Int. J. Heat Mass Transf. 148 (2020) 119004.
[30] S. Godfrey Nnabuife, B.Y. Kuang, J.F. Whidborne, Z. Rana, Non-intrusive classification of gas-liquid flow regimes in an S-shaped pipeline riser using a Doppler ultrasonic sensor and deep neural networks, Chem. Eng. J. 403 (2021) 126401.
[31] W.L. Liu, C. Tan, F. Dong, Doppler spectrum analysis and flow pattern identification of oil-water two-phase flow using dual-modality sensor, Flow Meas. Instrum. 77 (2021) 101861.
[32] H. Obayashi, Y. Tasaka, S. Kon, Y. Takeda, Velocity vector profile measurement using multiple ultrasonic transducers, Flow Meas. Instrum. 19 (3-4) (2008) 189-195.
[33] S. Shwin, A. Hamdani, H. Takahashi, H. Kikura, Two-dimensional velocity measurement downstream of the double bend pipe using phased array ultrasonic velocity profiler, Adv. Exp. Mech. 3 (2018) 111-117.
[34] N. Tiwari, Y. Murai, Ultrasonic velocity profiler applied to explore viscosity-pressure fields and their coupling in inelastic shear-thinning vortex streets, Exp. Fluids 62 (9) (2021) 185.
[35] N. Tiwari, Y. Tasaka, Y. Murai, Pressure field estimation from ultrasound Doppler velocity profiler for vortex-shedding flows, Flow Meas. Instrum. 67 (2019) 23-32.
[36] J. Hitomi, S. Nomura, Y. Murai, G. De Cesare, Y. Tasaka, Y. Takeda, H.J. Park, H. Sakaguchi, Measurement of the inner structure of turbidity currents by ultrasound velocity profiling, Int. J. Multiph. Flow 136 (2021) 103540.
[37] D. Yoon, H.J. Park, T. Ihara, Development of an instantaneous velocity-vector-profile method using conventional ultrasonic transducers, Meas. Sci. Technol. 33 (3) (2022) 035301.
[38] H. Murakawa, H. Kikura, M. Aritomi, Application of ultrasonic Doppler method for bubbly flow measurement using two ultrasonic frequencies, Exp. Therm. Fluid Sci. 29 (7) (2005) 843-850.
[39] H. Murakawa, H. Kikura, M. Aritomi, Application of ultrasonic multi-wave method for two-phase bubbly and slug flows, Flow Meas. Instrum. 19 (3-4) (2008) 205-213.
[40] T.T. Nguyen, H. Kikura, H. Murakawa, N. Tsuzuki, Measurement of bubbly two-phase flow in vertical pipe using multiwave ultrasonic pulsed Dopller method and wire mesh tomography, Energy Procedia 71 (2015) 337-351.
[41] W. Wongsaroj, A. Hamdani, N. Thong-un, H. Takahashi, H. Kikura, Extended short-time Fourier transform for ultrasonic velocity profiler on two-phase bubbly flow using a single resonant frequency, Appl. Sci. 9 (1) (2018) 50.
[42] X.W. Shi, C. Tan, F. Dong, J. Escudero, Flow rate measurement of oil-gas-water wavy flow through a combined electrical and ultrasonic sensor, Chem. Eng. J. 427 (2022) 131982.
[43] L.S. Zhai, H.Y. Xia, Y.L. Wu, N.D. Jin, Gas holdup measurement of horizontal gas-liquid two-phase flows by using a novel combined ultrasonic-conductance sensor, IEEE Sens. J. 21 (24) (2021) 27590-27600.
[44] L.S. Zhai, H.Y. Xia, H.L. Xie, J. Yang, Structure detection of horizontal gas-liquid slug flow using ultrasonic transducer and conductance sensor, IEEE Trans. Instrum. Meas. 70 (2021) 1-10.
[45] O. Dinaryanto, Y.A.K. Prayitno, A.I. Majid, A.Z. Hudaya, Y.A. Nusirwan, A. Widyaparaga, Indarto, Deendarlianto, Experimental investigation on the initiation and flow development of gas-liquid slug two-phase flow in a horizontal pipe, Exp. Therm. Fluid Sci. 81 (2017) 93-108.