Fluidization dynamic characteristics of carbon nanotube particles in a tapered fluidized bed

doi:10.1016/j.cjche.2021.03.006

Abstract

Abstract: In this work, a tapered fluidized bed (TFB) without a distributor for fluidizing carbon nanotube (CNT) was applied for improving the dead zone, blockage, and fracture of distributor, which occurred in actual production. Experiments were performed under different superficial gas velocities, static bed heights, CNT agglomerate size, and positions of pressure probe. To obtain multi-perspective and multi-scale understanding of fluidization dynamics of gas–CNT flow in the TFB without a distributor, the standard deviation, skewness, kurtosis, wavelet decompositions and homogeneous index analysis methods were adopted. Some noticeable phenomena were observed. Particle movements including inter-particle, gas–particle and particle–wall dominate dynamic characteristics. The amplitudes of pressure fluctuations of coarse agglomerated multi-walled CNT were more sensitive to the gas velocity than that of fine agglomerated multi-walled CNT. The sensitively of energy contribution of the meso- and macro-structures was that the sensitivity of the measured position was less than the sensitivity of the energy contribution by the changes of particle size, and the sensitivity of the energy contribution by the changes of particle size was less than the energy contribution by the changes of gas velocity. The fluidization quality of coarse agglomerated multi-walled CNT was better than that of fine agglomerated multi-walled CNT, which was verified by the skewness and wavelet analysis.

Key words: Tapered fluidized bed, Gas–CNT flow, Pressure fluctuation, Wavelet, Homogeneous index, Carbon nanotubes

摘要： In this work, a tapered fluidized bed (TFB) without a distributor for fluidizing carbon nanotube (CNT) was applied for improving the dead zone, blockage, and fracture of distributor, which occurred in actual production. Experiments were performed under different superficial gas velocities, static bed heights, CNT agglomerate size, and positions of pressure probe. To obtain multi-perspective and multi-scale understanding of fluidization dynamics of gas–CNT flow in the TFB without a distributor, the standard deviation, skewness, kurtosis, wavelet decompositions and homogeneous index analysis methods were adopted. Some noticeable phenomena were observed. Particle movements including inter-particle, gas–particle and particle–wall dominate dynamic characteristics. The amplitudes of pressure fluctuations of coarse agglomerated multi-walled CNT were more sensitive to the gas velocity than that of fine agglomerated multi-walled CNT. The sensitively of energy contribution of the meso- and macro-structures was that the sensitivity of the measured position was less than the sensitivity of the energy contribution by the changes of particle size, and the sensitivity of the energy contribution by the changes of particle size was less than the energy contribution by the changes of gas velocity. The fluidization quality of coarse agglomerated multi-walled CNT was better than that of fine agglomerated multi-walled CNT, which was verified by the skewness and wavelet analysis.

关键词: Tapered fluidized bed, Gas–CNT flow, Pressure fluctuation, Wavelet, Homogeneous index, Carbon nanotubes

Wenjuan Bai, Dianming Chu, Yan He. Fluidization dynamic characteristics of carbon nanotube particles in a tapered fluidized bed[J]. Chinese Journal of Chemical Engineering, 2022, 44(4): 321-331.

Wenjuan Bai, Dianming Chu, Yan He. Fluidization dynamic characteristics of carbon nanotube particles in a tapered fluidized bed[J]. 中国化学工程学报, 2022, 44(4): 321-331.

References

[1] H.J. Dai, Carbon nanotubes:Synthesis, integration, and properties, Acc. Chem. Res. 35 (12) (2002) 1035-1044
[2] S.I. Cha, K.T. Kim, K.H. Lee, C.B. Mo, Y.J. Jeong, S.H. Hong, Mechanical and electrical properties of cross-linked carbon nanotubes, Carbon 46 (3) (2008) 482-488
[3] S. Bhowmick, S. Ozden, R.A. Bizão, L.D. Machado, S.A.S. Asif, N.M. Pugno, D.S. Galvão, C.S. Tiwary, P.M. Ajayan, High temperature quasistatic and dynamic mechanical behavior of interconnected 3D carbon nanotube structures, Carbon 142 (2019) 291-299
[4] 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
[5] H. Yu, Q.F. Zhang, F. Wei, W.Z. Qian, G.H. Luo, Agglomerated CNTs synthesized in a fluidized bed reactor:Agglomerate structure and formation mechanism, Carbon 41 (14) (2003) 2855-2863
[6] Y. Wang, F. Wei, G.S. Gu, H. Yu, Agglomerated carbon nanotubes and its mass production in a fluidized-bed reactor, Phys. B:Condens. Matter 323 (1-4) (2002) 327-329
[7] Y. Wang, F. Wei, G.H. Luo, H. Yu, G.S. Gu, The large-scale production of carbon nanotubes in a nano-agglomerate fluidized-bed reactor, Chem. Phys. Lett. 364 (5-6) (2002) 568-572
[8] H. Dashtian, M. Sahimi, Analysis of pressure fluctuations in fluidized beds. III. The significance of the cross correlations, Chem. Eng. Sci. 101 (2013) 390-400
[9] J. Xiang, Q.H. Li, A.Y. Wang, Y.G. Zhang, Mathematical analysis of characteristic pressure fluctuations in a bubbling fluidized bed, Powder Technol. 333 (2018) 167-179
[10] 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
[11] C. Huang, Y. Wang, F. Wei, Solids mixing behavior in a nano-agglomerate fluidized bed, Powder Technol. 182 (3) (2008) 334-341
[12] D. Escudero, T.J. Heindel, Bed height and material density effects on fluidized bed hydrodynamics, Chem. Eng. Sci. 66 (16) (2011) 3648-3655
[13] Z.G. Zhao, J.W. Zhang, G.Y. Zhang, X. Zeng, X.X. Liu, G.W. Xu, Hydrodynamic characterization of a tapered gas-solid bed without a gas distributor, Powder Technol. 256 (2014) 300-309
[14] N.P. Franka, T.J. Heindel, Local time-averaged gas holdup in a fluidized bed with side air injection using X-ray computed tomography, Powder Technol. 193 (1) (2009) 69-78
[15] J. Wiens, T. Pugsley, Tomographic imaging of a conical fluidized bed of dry pharmaceutical granule, Powder Technol. 169 (1) (2006) 49-59
[16] H.T. Bi, A critical review of the complex pressure fluctuation phenomenon in gas-solids fluidized beds, Chem. Eng. Sci. 62 (13) (2007) 3473-3493
[17] A.J. Croxford, M.A. Gilbertson, Pressure fluctuations in bubbling gas-fluidized beds, Chem. Eng. Sci. 66 (16) (2011) 3569-3578
[18] Y.M. Chen, C. J.Lim, J.R. Grace, J.Y. Zhang, Y.C. Zhao, C.G. Zheng, Characterization of pressure fluctuations from a gas-solid fluidized bed by structure density function analysis, Chem. Eng. Sci. 129 (2015) 156-167
[19] J. Xiang, Q.H. Li, Z.C. Tan, Y.G. Zhang, Characterization of the flow in a gas-solid bubbling fluidized bed by pressure fluctuation, Chem. Eng. Sci. 174 (2017) 93-103
[20] S. Sasic, B. Leckner, F. Johnsson, Parametric modelling of time series of pressure fluctuations in gas-solid fluidized beds, Chem. Eng. Sci. 60 (18) (2005) 5069-5077
[21] F. Johnsson, R.C. Zijerveld, J.C. Schouten, C.M. van den Bleek, B. Leckner, Characterization of fluidization regimes by time-series analysis of pressure fluctuations, Int. J. Multiph. Flow 26 (4) (2000) 663-715
[22] C.A.S. Felipe, S.C.S. Rocha, Prediction of minimum fluidization velocity of gas-solid fluidized beds by pressure fluctuation measurements-Analysis of the standard deviation methodology, Powder Technol. 174 (3) (2007) 104-113
[23] H. Bi, A.H. Chen, Pressure fluctuations in gas-solids fluidized beds, China Particuology 1 (4) (2003) 139-144
[24] E. Ramirez, C.E.A. Finney, S. Pannala, C.S. Daw, J. Halow, Q.G. Xiong, Computational study of the bubbling-to-slugging transition in a laboratory-scale fluidized bed, Chem. Eng. J. 308 (2017) 544-556
[25] S.H. Lee, S.D. Kim, S.H. Park, Statistical and deterministic chaos analysis of pressure fluctuations in a fluidized bed of polymer powders, Korean J. Chem. Eng. 19 (6) (2002) 1020-1025
[26] T.Y. Yang, L.P. Leu, Study of transition velocities from bubbling to turbulent fluidization by statistic and wavelet multi-resolution analysis on absolute pressure fluctuations, Chem. Eng. Sci. 63 (7) (2008) 1950-1970
[27] T. Zhao, K. Liu, J.E. Choi, Y.H. Cui, M. Takei, D.H. Doh, Wavelet analysis of the particle distribution in a down-flow fluidized bed based on electrical capacitance tomography images, Powder Technol. 211 (2-3) (2011) 264-274
[28] J.Y. Sun, Y. Yan, Characterization of flow intermittency and coherent structures in a gas-solid circulating fluidized bed through electrostatic sensing, Ind. Eng. Chem. Res. 55 (46) (2016) 12133-12148
[29] S. Wu, F.Y. Meng, Y.Q. He, Scale resolution of fiber optical signals in circulating fluidized bed, Chem. Eng. Sci. 182 (2018) 162-170
[30] G.P. Wu, Y. He, L. Luo, W. Chen, Dynamic characterizations of gas-solid flow in a novel multistage fluidized bed via nonlinear analyses, Chem. Eng. J. 359 (2019) 1013-1023
[31] H.W. Jiang, H.W. Chen, J.Q. Gao, J.F. Lu, Y. Wang, C.P. Wang, Characterization of gas-solid fluidization in fluidized beds with different particle size distributions by analyzing pressure fluctuations in wind caps, Chem. Eng. J. 352 (2018) 923-939
[32] G.B. Zhao, Y.R. Yang, Multiscale resolution of fluidized-bed pressure fluctuations, AIChE J. 49 (4) (2003) 869-882
[33] B.Y. Wu, A. Kantzas, C.T. Bellehumeur, Z.X. He, S. Kryuchkov, Multiresolution analysis of pressure fluctuations in a gas-solids fluidized bed:Application to glass beads and polyethylene powder systems, Chem. Eng. J. 131 (1-3) (2007) 23-33
[34] C.D. Si, J. Zhou, Q.J. Guo, Characterization of pressure fluctuation signals in an acoustic bubbling fluidized bed, J. Taiwan Inst. Chem. Eng. 42 (6) (2011) 929-936
[35] S.G. Mallat, A theory for multiresolution signal decomposition:the wavelet representation, IEEE Trans. Pattern Anal. Mach. Intell. 11 (7) (1989) 674-693
[36] M.C. Shou, L.P. Leu, Energy of power spectral density function and wavelet analysis of absolute pressure fluctuation measurements in fluidized beds, Chem. Eng. Res. Des. 83 (5) (2005) 478-491
[37] Q.J. Guo, G.X. Yue, T. Suda, J. Sato, Flow characteristics in a bubbling fluidized bed at elevated temperature, Chem. Eng. Process.:Process. Intensif. 42 (6) (2003) 439-447
[38] H.J. Sun, C.B. Hu, Y.H. Xu, Pressure fluctuations analysis on the powder fluidization performance at different pressure, Int. J. Multiph. Flow 116 (2019) 176-184
[39] Y.F. Zhou, L. Yang, Y.J. Lu, X.Y. Hu, X. Luo, H.B. Chen, Flow regime identification in gas-solid two-phase fluidization via acoustic emission technique, Chem. Eng. J. 334 (2018) 1484-1492
[40] T.Y. Yang, L.P. Leu, Multiresolution analysis on identification and dynamics of clusters in a circulating fluidized bed, AIChE J. 55 (3) (2009) 612-629
[41] C. Sobrino, S. Sánchez-Delgado, N. García-Hernando, M. de Vega, Standard deviation of absolute and differential pressure fluctuations in fluidized beds of group B particles, Chem. Eng. Res. Des. 86 (11) (2008) 1236-1242
[42] H.T. Bi, N. Ellis, I.A. Abba, J.R. Grace, A state-of-the-art review of gas-solid turbulent fluidization, Chem. Eng. Sci. 55 (21) (2000) 4789-4825
[43] P.H. Westfall, Kurtosis as peakedness, 1905-2014.R.I.P, Am. Stat. 68 (3) (2014) 191-195.
[44] H.R. Norouzi, M. Tahmasebpoor, R. Zarghami, N. Mostoufi, Multi-scale analysis of flow structures in fluidized beds with immersed tubes, Particuology 21 (2015) 99-106
[45] S.M. Okhovat-Alavian, J. Behin, N. Mostoufi, Investigating the flow structures in semi-cylindrical bubbling fluidized bed using pressure fluctuation signals, Adv. Powder Technol. 30 (6) (2019) 1247-1256