The motion mechanism and characteristic of bubble in a pseudo-2D tapered fluidized bed

doi:10.1016/j.cjche.2021.06.024

Abstract

Abstract: The different carbon nanotube (CNT) particles (^@A and ^@V) were bed materials in the pseudo-2D tapered fluidized bed (TFB) with/without a distributor. A detailed investigation of the motion mechanism of bubbles was carried out. The high-speed photography and image analysis techniques were used to study bubble characteristic and mixing behavior in the tapered angle of TFB without a distributor. The fractal analysis method was used to analyze the degree of particles movement. Results showed that an S-shaped motion trajectory of bubbles was captured in the bed of ^@V particles. The population of observational bubbles in the bed of ^@V particles was more than that of ^@A particles, and the bubble size was smaller in the bed of ^@V particles than that of ^@A particles. The motion mechanism of bubbles had been shown to be related to bed materials and initial bed height in terms of analysis and comparison of bubble diameter, bubble aspect ratio and bubble shape factor. Importantly, compared to the TFB with a distributor, the TFB without a distributor had been proved to be beneficial to the CNT fluidization according to the study of bubble characteristic and the degree of the particle movement. Additionally, it was found that the mixing behavior of ^@V particles was better than ^@A particles in the tapered angle of TFB without a distributor.

Key words: Tapered fluidized bed, Carbon nanotube, Bubble characteristic, Image processing technique, Fractal analysis

摘要： The different carbon nanotube (CNT) particles (^@A and ^@V) were bed materials in the pseudo-2D tapered fluidized bed (TFB) with/without a distributor. A detailed investigation of the motion mechanism of bubbles was carried out. The high-speed photography and image analysis techniques were used to study bubble characteristic and mixing behavior in the tapered angle of TFB without a distributor. The fractal analysis method was used to analyze the degree of particles movement. Results showed that an S-shaped motion trajectory of bubbles was captured in the bed of ^@V particles. The population of observational bubbles in the bed of ^@V particles was more than that of ^@A particles, and the bubble size was smaller in the bed of ^@V particles than that of ^@A particles. The motion mechanism of bubbles had been shown to be related to bed materials and initial bed height in terms of analysis and comparison of bubble diameter, bubble aspect ratio and bubble shape factor. Importantly, compared to the TFB with a distributor, the TFB without a distributor had been proved to be beneficial to the CNT fluidization according to the study of bubble characteristic and the degree of the particle movement. Additionally, it was found that the mixing behavior of ^@V particles was better than ^@A particles in the tapered angle of TFB without a distributor.

关键词: Tapered fluidized bed, Carbon nanotube, Bubble characteristic, Image processing technique, Fractal analysis

Wenjuan Bai, Dianming Chu, Kuanxin Tang, Lei Geng, Yan Li, Yan He. The motion mechanism and characteristic of bubble in a pseudo-2D tapered fluidized bed[J]. Chinese Journal of Chemical Engineering, 2022, 46(6): 255-270.

Wenjuan Bai, Dianming Chu, Kuanxin Tang, Lei Geng, Yan Li, Yan He. The motion mechanism and characteristic of bubble in a pseudo-2D tapered fluidized bed[J]. 中国化学工程学报, 2022, 46(6): 255-270.

References

[1] L. Gan, X.F. Lu, Q.H. Wang, Experimental and theoretical study on hydrodynamic characteristics of tapered fluidized beds, Adv. Powder Technol. 25 (3) (2014) 824-831
[2] Y.M. Peng, L.T. Fan, Hydrodynamic characteristics of fluidization in liquid-solid tapered beds, Chem. Eng. Sci. 52 (14) (1997) 2277-2290
[3] D.C. Sau, S. Mohanty, K.C. Biswal, Minimum fluidization velocities and maximum bed pressure drops for gas-solid tapered fluidized beds, Chem. Eng. J. 132 (1-3) (2007) 151-157
[4] W.J. Bai, D.M. Chu, F. Wang, Y. He, Research on fluidization performance of different tapered fluidized bed reactors for fluidizing carbon nanotubes, Ind. Eng. Chem. Res. 59 (25) (2020) 11893-11904
[5] Z. Zou, W.M. Liu, D. Yan, Z.H. Xie, H.Z. Li, Q.S. Zhu, S.Y. He, CFD simulations of tapered bubbling/turbulent fluidized beds with/without gas distributor based on the structure-based drag model, Chem. Eng. Sci. 202 (2019) 157-168
[6] D.C. Sau, S. Mohanty, K.C. Biswal, Prediction of critical fluidization velocity and maximum bed pressure drop for binary mixture of regular particles in gas-solid tapered fluidized beds, Chem. Eng. Process.:Process. Intensif. 47 (12) (2008) 2114-2120
[7] M.H. Khani, Models for prediction of hydrodynamic characteristics of gas-solid tapered and mini-tapered fluidized beds, Powder Technol. 205 (1-3) (2011) 224-230
[8] C.D. Scott, C.W. Hancher, Use of a tapered fluidized bed as a continuous bioreactor, Biotechnol. Bioeng. 18 (10) (1976) 1393-1403
[9] C.S. Wu, J.S. Huang, R. Ohara, Hydrodynamics of tapered anaerobic fluidized beds for metabolic gas production, Chem. Eng. J. 148 (2-3) (2009) 279-289
[10] F. Wei, Q. Zhang, W.Z. Qian, H. Yu, Y. Wang, G.H. Luo, G.H. Xu, D.Z. Wang, The mass production of carbon nanotubes using a nano-agglomerate fluidized bed reactor:A multiscale space-time analysis, Powder Technol. 183 (1) (2008) 10-20
[11] Zhang Q, Huang JQ, Zhao MQ, Qian WZ, Wei F, Carbon nanotube mass production:Principles and processes, ChemSusChem 4 (7) (2011) 864-889
[12] K.A. Shah, B.A. Tali, Synthesis of carbon nanotubes by catalytic chemical vapour deposition:A review on carbon sources, catalysts and substrates, Mater. Sci. Semicond. Process. 41 (2016) 67-82
[13] H. Yu, Q.F. Zhang, G.S. Gu, Y. Wang, G.H. Luo, F. Wei, Hydrodynamics and gas mixing in a carbon nanotube agglomerate fluidized bed, AIChE J. 52 (12) (2006) 4110-4123
[14] P. Mahanandia, V.P. Arya, K.K. Nanda, P.V. Bhotla, S.V. Subramanyam, Preparation temperature effect on the synthesis of various carbon nanostructures, Mater. Sci. Eng.:B 164 (3) (2009) 140-150
[15] N. Yang, S.K. Youn, C.E. Frouzakis, H.G. Park, An effect of gas-phase reactions on the vertically aligned CNT growth by temperature gradient chemical vapor deposition, Carbon 130 (2018) 607-613
[16] S.W. Jeong, J. Kim, D.H. Lee, Effect of operating variables on synthesis of multi-walled carbon nanotubes in fluidized beds, Chem. Eng. Sci. 134 (2015) 496-503
[17] S.W. Jeong, J.H. Lee, J. Kim, D.H. Lee, Fluidization behaviors of different types of multi-walled carbon nanotubes in gas-solid fluidized beds, J. Ind. Eng. Chem. 35 (2016) 217-223
[18] Antonio Busciglio, Giuseppa Vella, Giorgio Micale. Analysis of the bubbling behaviour of 2D gas solid fluidized beds Part I.Digital image analysis technique. Chem. Eng. J. 140 (1/3) (2008) 398-413
[19] C. Sobrino, A. Acosta-Iborra, D. Santana, M. de Vega, Bubble characteristics in a bubbling fluidized bed with a rotating distributor, Int. J. Multiph. Flow 35 (10) (2009) 970-976
[20] C.N. Lim, M.A. Gilbertson, A.J.L. Harrison, Bubble distribution and behaviour in bubbling fluidised beds, Chem. Eng. Sci. 62 (1-2) (2007) 56-69
[21] T.W. Asegehegn, M. Schreiber, H.J. Krautz, Investigation of bubble behavior in fluidized beds with and without immersed horizontal tubes using a digital image analysis technique, Powder Technol. 210 (3) (2011) 248-260
[22] G.R. Caicedo, J.J.P. Marqués, M.G. Ruız, J.G. Soler, A study on the behaviour of bubbles of a 2D gas-solid fluidized bed using digital image analysis, Chem. Eng. Process.:Process. Intensif. 42 (1) (2003) 9-14
[23] P.P. Wang, J.J. Cilliers, S.J. Neethling, P.R. Brito-Parada, The behavior of rising bubbles covered by particles, Chem. Eng. J. 365 (2019) 111-120
[24] J.X. Zhu, Development of particle test system based on imaging processing technique and study on mixing characteristic of particles in pipe fluidized bed, Ph. D. Thesis, Zhejiang Univ., China, 2004
[25] H.B. Xu, W.Q. Zhong, Y.J. Shao, A.B. Yu, Experimental study on mixing behaviors of wet particles in a bubbling fluidized bed, Powder Technol. 340 (2018) 26-33
[26] D. Santana, S. Nauri, A. Acosta, N. García, A. Macías-Machín, Initial particle velocity spatial distribution from 2-D erupting bubbles in fluidized beds, Powder Technol. 150 (1) (2005) 1-8
[27] T. Akiyama, T. Iguchi, K. Aoki, K. Nishimoto, A fractal analysis of solids mixing in two-dimensional vibrating particle beds, Powder Technol. 97 (1) (1998) 63-71
[28] R.R. Filgueira, L.L. Fournier, C.I. Cerisola, P. Gelati, M.G. García, Particle-size distribution in soils:A critical study of the fractal model validation, Geoderma 134 (3-4) (2006) 327-334
[29] M. Tanaka, M. Komagata, M. Tsukada, H. Kamiya, Fractal analysis of the influence of surface roughness of toner particles on their flow properties and adhesion behavior, Powder Technol. 186 (1) (2008) 1-8
[30] Y. Tatek, S. Stoll, L. Ouali, E. Pefferkorn, Structure and cohesion of weakly agglomerated fractal systems, Powder Technol. 143-144 (2004) 117-129
[31] W.J. Bai, D.M. Chu, Y. He, Bubble characteristic of carbon nanotubes growth process in a tapered fluidized bed reactor without a distributor, Chem. Eng. J. 407 (2021) 126792
[32] A. Widyatama, O. Dinaryanto, Indarto, Deendarlianto, The development of image processing technique to study the interfacial behavior of air-water slug two-phase flow in horizontal pipes, Flow Meas. Instrum. 59 (2018) 168-180
[33] T.W. Asegehegn, M. Schreiber, H.J. Krautz, Influence of two- and three-dimensional simulations on bubble behavior in gas-solid fluidized beds with and without immersed horizontal tubes, Powder Technol. 219 (2012) 9-19
[34] P. Chakrawarty, G. Bhatnagar, Image thresholding based on local activity feature matrix, Optik 127 (20) (2016) 9037-9045
[35] B. Mandelbrot, The Fractal Geometry of the Nature. Shanghai Far East Publishers, Shanghai, 1998
[36] X.F. Fan, Z.F. Yang, D.J. Parker, B. Armstrong, Prediction of bubble behaviour in fluidised beds based on solid motion and flow structure, Chem. Eng. J. 140 (1-3) (2008) 358-369
[37] J.R. Grace, D. Harrison, The distribution of bubbles within a gas-fluidized bed, Inst. Chem. Eng. Symp. Ser. 30 (1969) 105-125
[38] R.C. Darton, R.D. LaNauze, J.F. Davidson, D. Harrison, Bubble growth due to coalescence in fluidised beds, Trans. Inst. Chem. Eng, 55 (1977) 274-280
[39] S. Cooper, C.J. Coronella, CFD simulations of particle mixing in a binary fluidized bed, Powder Technol. 151 (1-3) (2005) 27-36
[40] A. Busciglio, G. Vella, G. Micale, L. Rizzuti, Experimental analysis of bubble size distributions in 2D gas fluidized beds, Chem. Eng. Sci. 65 (16) (2010) 4782-4791
[41] C.X. Zhang, P.L. Li, C. Lei, W.Z. Qian, F. Wei, Experimental study of non-uniform bubble growth in deep fluidized beds, Chem. Eng. Sci. 176 (2018) 515-523
[42] C.X. Zhang, W.Z. Qian, F. Wei, Instability of uniform fluidization, Chem. Eng. Sci. 173 (2017) 187-195
[43] Y. Luo, Z.X. Ma, Q.X. Huang, J.X. Zhu, F. Wang, J.Q. Zhu, J.H. Yan, M.J. Ni, Analysis of the Relationship between the Fractal Dimension of Fluidized Bed Images and Particle Movement Degree, Power System Engineering, 20(5) (2004) 20-23