发表论文详情
(A) HDCFB (High-Density Circulating Fluidized Bed), plus Scale-up and Ozone Study under HDCFB:
1 Jeremiah JM, Manyele SV, Temu AK and Zhu J-X, “Mapping the Wall-Region Dynamics of High-Flux Gas-Solid Riser Using Scaling Regions from the Solid Concentration Time Series”, Eng., 11(1), 74-92, 2019.
2 Wang C-X, Zhu J-X, Lan X-Y, Gao J-S and Barghi S, “Radial Solids Flow Structure in High Flux Gas-Solids Circulating Fluidized Bed Downers”, Powder Technol., 301, 848-857, 2016.
3 Wang C-X and Zhu J-X, “Development in the Understanding of Gas-Solid Contract Efficiency in the Circulating Fluidized Bed Riser Reactor: A Review”, Chinese J. of Chem. Eng., 24(1), 53-62, 2016.
4 Kong L, Zhu J-X and Zhang C, “Numerical Simulation of Catalytic Ozone Decomposition Reaction in a Gas-Solids Circulating Fluidized Bed Riser”, Chem. Eng. & Tech., Accepted.
5 Wang C-X, Wang G, Li C-Y, Barghi S and Zhu J-X, “Catalytic Ozone Decomposition in a High Density Circulating Fluidized Bed Riser”, Ind. & Eng. Chem. Res., 53, 6613-6623, 2014.
6 Wang C-X, Zhu J-X, Li C-Y and Barghi S, “Detailed Measurements of Particle Velocity and Solids Flux in a High Density Circulating Fluidized Bed Riser”, Chem. Eng. Sci., 114(26), 9-20, 2014.
7 Wang C-X, Zhu J-X, Barghi S and Li C, “Axial and Radial Development of Solids Holdup in a High Flux/Density Gas-Solids Circulating Fluidized Bed”, Chem. Eng. Sci., 108(28), 233-243, 2014.
8 Kong, L, Zhu J-X and Zhang C, “Catalytic Ozone Decomposition in a Gas-Solids Circulating Fluidized-Bed Riser”, Chem. Eng. Technol., 37(3), 435-444, 2014.
9 Li D-B, Ray A, Ray M and Zhu J-X, “Catalytic Reaction in a Circulating Fluidized Bed Riser: Ozone Decomposition”, Powder Tech.”, 242, 65-73, July, 2013.
10 Li D-B, Ray A, Ray M and Zhu J-X, “Rotational Asymmetry of Reactant Concentration and its Evolution in a Circulating Fluidized Bed Riser”, Particuology, 10(5), 573-581, 2012.
11 Zhu J-X and Wang C-X, “Overview on the Development of Fluid Catalytic Cracking Technology”, Chem. Tech., 221(8), 98-125, 2011 (Review)
12 Yan A-J, Huang W-X and Zhu J-X, “The Influence of Distributor Structure on the Solids Distribution and Flow Development in Circulating Fluidized Beds”, Can. J. Chem. Eng., 86(6), 1023-1031, 2008.
13 Manyele1 S V, Zhu J-X, Khayat R E and Pärssinen J H, “Analysis of the Chaotic Dynamics of a High-Flux CFB Riser Using Solids Concentration Measurements”, Particuologoy, 4(3-4), 136-146, 2006.
14 Yan A-J and Zhu J-X, “Scale-Up Effect of Riser Reactors - Particle Velocity and Flow Development”, AIChE J., 51(11), 2956-2964, 2005.
15 Yan A-J, Ball J S and Zhu J-X, “Scale-up Effect of Riser Reactors (3) - Axial and Radial Solids Flux Distribution and Flow Development”, Chem. Eng. J., 109(1-3), 97-106, 2005.
16 Yan A-J and Zhu J-X, “Scale-Up Effect of Riser Reactors (1) - Axial and Radial Solids Concentration Distribution and Flow Development”, Ind. Eng. Chem. Res., 43(18), 5810-5819, 2004.
17 Yan A-J, Zhu J-X, Remize P-J and Bordas A, “The Effect of Solids Inventory and other Factors on the Axial Solids Holdup Profiles in a Twin-Riser System”, Chem. Eng. & Technol., 27(4), 429-434, 2004.
18 Yan A-J, Pärssinen J H and Zhu J-X, “Flow Properties in the Entrance and Exit Regions of a High-Flux Circulating Fluidized Bed Riser”, Powder Technol., 131(3), 256-263, 2003.
19 Manyele S V, Khayat R E and Zhu J-X, “Investigation of the Dynamics of a High-Flux CFB Riser Using Chaos Analysis of Pressure Fluctuations”, Chem. Eng. & Technol., 25(8), 1-10, 2002.
20 Manyele S V, Pärssinen J H and Zhu J-X, “Characterizing Particle Aggregates in a High-Density and High-Flux CFB Riser”, Chem. Eng. J., 88(2), 151-161, 2002.
21 Pärssinen J H and Zhu J-X, “Axial and Radial Solids Distribution in a Long and High-Flux CFB Riser”, AIChE J., 47(10), 2197-2205, 2001.
22 Pärssinen J H and Zhu J-X, “Particle Velocity and Flow Development in a Long and High-Flux Circulating Fluidized Bed Riser”, Chem. Eng. Sci., 56(18), 5295-5303, 2001.
23 Issangya A S, Grace J R, Bai D-R and Zhu J-X, “Radial Voidage Variation in CFB Risers”, Can. J. Chem. Eng., 79(2), 279-286, 2001.
24 Issangya A S, Grace J R, Bai D-R and Zhu J-X, “Further Measurements of Flow Dynamics in a High-Density Circulating Fluidized Bed Riser”, Powder Technol., 111(1-2), 104-113, 2000.
25 Grace J R, Issangya A S, Bai D-R, Bi H-T and Zhu J-X, “Situating the High-Density Circulating Fluidized Bed”, AIChE J., 45(10), 2108-2116, 1999.
26 Issangya A S, Bai D-R, Bi H-T, Lim K S, Zhu J-X and Grace J R, “Suspension Densities in a High-Density Circulating Fluidized Bed Riser”, Chem. Eng. Sci., 54(22), 5451-5460, 1999.
27 Bai D-R, Issangya A S, Zhu J-X and Grace J R, “Analysis of the Overall Pressure Balance around a High-Density Circulating Fluidized Bed”, Ind. Eng. Chem. Res., 36(9), 3898-3903, 1997.
28 Issangya A S, Bai D, Grace J R, Lim K S and Zhu J-X, “Flow Behavior in the Riser of a High-Density Circulating Fluidized Bed”, AIChE Symp. Ser., 93(317), 25-30, 1997.
29 Zhu J-X and Bi H-T, “Distinctions between Low Density and High Density Circulating Fluidized Beds”, Can. J. Chem. Eng., 73(5), 644-649, 1995. (Review)
30 Bi H-T and Zhu J-X, “Static Instability Analysis of Circulating Fluidized Beds and Concept of High Density Risers”, AIChE J., 39(8), 1272-1280, 1993.
(B) GSCFB (Gas-Solid Circulating Fluidized Bed) – Fundamentals:
31 Wu C-Z, Zhu J-X, Yin X-L, Zhou Z-Q, Ma L-L and Wang C, "A Device and Method for Measuring the Solids Circulation Rate inside Circulating Fluidized Beds", Chinese Patent, ZL2008-1019,8396.X, December 29, 2010.
32 Gu L-L Gu, Zhang Y-W and Zhu J-X, “Wavelet De-noising and Nonlinear Analysis of Solids Concentration Signal in Circulating Fluidized Bed Riser”, Particuology, 2019. (In Press)
33 An Z-Q, Zhu J-X, “Correlating the Apparent Viscosity with Gas-Solid Suspension Flow in Straight Pipelines”, Powder Technol., 345(1), 346-351, 2019.
34 Yang J-S and Zhu J-X, “Cluster Identification Using Image Processing”, Particuology, 23, 16-24, 2015.
35 Yang J-S and Zhu J-X, “An Alternative Method to Quantify Solids Phase Separation in a Narrow Rectangular CFB Riser”, Procedia Eng., 102, 1064-1072, 2015.
36 Yang J-S and Zhu J-X, “Visualization of Solids Phase Separation in a Rectangular CFB Riser Using a Novel Image Calibration Method”, Powder Technol., 273, 76-82, 2015.
37 Yang J-S and Zhu J-X, “An Alternative Method for Mapping Solids Holdup in a Narrow Rectangular CFB Riser through Image Calibration”, Can. J. of Chem. Eng., 92(12), 2202-2210, 2014.
38 Yang J-S and Zhu J-X, “A Novel Method Based on Image Processing to Visualize Clusters in a Rectangular Circulating Fluidized Bed Riser”, Powder Technol., 254, 407-415, 2014.
39 Xu, J and Zhu J-X, “A New Method for the Determination of Cluster Velocity and Size in a Circulating Fluidized Bed”, I&ECR, 51(4), 2143-2151, 2011.
40 Xu J and Zhu J-X, “Visualization of Particle Aggregation and Effects of Particle Properties on Cluster Characteristics in a CFB Riser”, Chem. Eng. J., 168(1), 376-389, 2011.
41 Xu J and Zhu J-X, “Effects of Particle Properties on Flow Structure in a 2-D Circulating Fluidized Bed: Solids Concentration Distribution and Flow Development”, Chem. Eng. Sci., 66(21), 5064-5076, 2011,
42 Xu J, Zhu J-X, “Experimental Study on Solids Concentration Distribution in a Two-dimensional Circulating Fluidized Bed” Chem. Eng. Sci. , 65(20), 5447-5454, 2010.
43 Wang C, Zhuo Z-Q, Yin X-L, Ma L-L, Wu C-Z, Xie J-J, Miao Q and Zhu J-X, “Study of Hydrodynamic Characteristics of Sawdust in a Circulating Fluidized Bed”, J Solar Energy, 31(4), 501-506, 2010.
44 Ye S, Qi X-B and Zhu J-X, “Direct Measurements of Instantaneous Solids Flux in a CFB Riser Using a Novel Multifunctional Optical Fiber Probe”, Chem. Eng. & Technol., 32(4), 580-589, 2009.
45 Huang W-X, Chu H-B, Li M, Li L-H and Zhu J-X, “Drag Coefficient in Gas-Solid Two Phase Flow of CFB Riser”, J. of Sichuan University, 40(2), 53-57, 2008.
46 Qi X-B, Zhu J and Huang W-X, “Hydrodynamic Similarity in Circulating Fluidized Bed Risers”, Chem. Eng. Sci., 63(23), 5613-5625, 2008.
47 Qi X-B, Huang W-X and Zhu J-X, “Comparative Study of Flow Structure in Circulating Fluidized Bed Risers with FCC and Sand Particles”, Chem. Eng. & Technol., 31(4), 542-553, 2008. (
48 Huang W-X, Yan A and Zhu J-X, “Hydrodynamics and Flow Development in a 15.1 m Circulating Fluidized Bed Riser”, Chem. Eng. & Technol., 30(4), 460-466, 2007.
49 Chen P, Zhao Z-L, Yin X-L, Wu C-Z, Chen Y and Zhu J-X. “The Flow Characteristics of Sawdust Particulate in Circulating Fluidized Bed with a Loop Seal”, J Solar Energy, 27(10), 1037-1042, 2006.
50 Huang W-X, Zhu J-X and Pärssinen J H, “Comprehensive Study on the Solids Acceleration Length in a Long CFB Riser”, Chem. Eng. & Technol., 29(10), 1197-1204, 2006. (157)
51 Li Y, Zhang C and Zhu J-X, “Gas-Solids Flow Behavior with a Gas Velocity close to Zero”, Particuologoy, 7(3), 357-360, 2006.
52 Qi X-B, Huang W-X, Zhu J-X, Shi Y-F. “Combination Effect of Nozzle Gas Distributor and Particle Properties on Gas-Solid Flow Behaviors in CFB Risers”, J. Chem. Eng. Chinese Univ., 20(3), 325-330, 2006.
53 Wu B-Y, Briens L and Zhu J-X, “Multi-scale Flow Behavior in Gas-solids Two-phase Flow Systems”, Chem. Eng. J., 117(3), 187-195, 2006.
54 Qi X-B, Huang W-X, Zhu J-X and Shi Y-F, “Similarity of Gas-Solid Two-Phase Flow Behavior in CFB Riser.” J. Chem. Ind. Eng., 56(11), 2096-2101, 2005.
55 Qi X-B, Zeng T, Huang W-X, Zhu J-X and Shi Y-F, “Experimental Study of Solids Holdups Inside Particle Clusters in CFB Risers.” J. Sichuan Univ., 37(5), 46-50, 2005.
56 Lin H-B, Huang W-X, Qi X-B, Shi Y-F and Zhu J-X, “Axial Distributions of Averaged Solids Holdups for Coarse Particles in CFB Riser.” J. Chem. Eng. Chinese Univ., 19(3), 327-331, 2005.
57 Huang W-X, Yan A-J and Zhu J-X, “Axial Solids Distribution and Flow Development in the Risers of Circulating Fluidized Beds with Different Heights", J. Chin. Inst. Chem. Engrs., 36(1), 17-24, 2005.
58 Duan X-P, Qi X-B, Huang W-X, Lin H-B and Zhu J-X. “Investigation on Local Solid Concentration of Coarse Particles in Circulating Fluidized Bed Risers”. J. Sichuan Univ., 36(2), 46-50, 2004. (119)
59 Ma L-P, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Study on Reducing Noise of Pressure Fluctuation Signal in Circulating Fluidized Bed”, Chem. Eng., 32(1), 28-33, 2004.
60 Ma L-P, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Embedding Window and its Application in the Analysis of Fluctuation Signal in Circulating Fluidized Bed”, J. Kunming Univ. Sci. and Technol., 28(5), 119-123, 2003. (
61 Ma L-P, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Analysis of Pressure Fluctuation Signals in a Circulating Fluidized Bed”, J. Chem. Ind. Eng., 54(5), 619-624, 2003.
62 Qi X-B, Huang W-X, Pan Y-L, Zhu J-X and Shi Y-F, “Studies on the Solids Holdups and the Core-Annulus Structure in a Long CFB Riser”, J. Sichuan Univ., 35(1), 43-47, 2003.
63 Li X-X, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Prediction of Solids Holdup Time Series of a Gas-Solid Circulating Fluidized Bed”, Chinese J. Process Eng., 3(1), 8-13, 2003.
64 Huang W-X, Qi X-B, Pan Y-L, Zhu J-X and Shi Y-F, “Local Solid-Particle Concentration and Flow Development in a Long CFB Riser”, J. Chem. Eng. Chinese Univ., 16(6), 626-631, 2002.
65 Ma L-P, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Embedding Window Reconstruction and its Application in Chaotic Analysis of Circulating Fluidized Beds”, Chem. Reaction Eng. Technol., 18(4), 368-372, 2002.
66 Ma L-P, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Multifractal Measure Analysis of Solids Hold-Up Fluctuation Signal in Circulating Fluidized Bed”, J. Chem. Eng. Chinese Univ., 16(5), 496-502, 2002.
67 Zhou W-W, Shi Y-F, Huang W-X, Yu H-R and Zhu J-X, “Nonlinear Analysis of Pressure Fluctuations Time Series in Gas-Solid Circulating Fluidized Bed”, Petroleum Technol. & Appl., 20(2), 83-87, 2002.
68 Qi X-B, Huang W-X, Zhu J-X and Shi Y-F, "Radial Distribution and Axial Development of Particle Velocities in a Long CFB Riser ", J. Chem. Eng. Chinese Univ., 16(2), 168-173, 2002.
69 Hong J and Zhu J-X “Effect of Pipe Orientation on Dense-Phase Transport (II): Inclined Upward and Downward Flows”, Chem. Eng. Commun., 189(4), 489-509, 2002.
70 Duan W-F, Zhang J-N, Huang W-X, Shi Y-F and Zhu J-X, “Improvement to the Derivative Reconstruction Method and its Application in Circulating Fluidized Beds”, Chem. Reaction Eng. Technol., 17(4), 376-380, 2001.
71 Duan W-F, Zhang J-N, Huang W-X, Shi Y-F and Zhu J-X, “Study on the Derivative Reconstruction Method (for CFB)”, J. Sichuan Univ., 33(5), 102-106, 2001.
72 Huang W-X, Shi Y-F and Zhu J-X, “Investigation on Solids Holdups of FCC Particles in a 16m High CFB Riser”, Petrochemical Technol., 30(7), 534-537, 2001.
73 Huang W-X, Shi Y-F and Zhu J-X, “Solids Holdups of Gas-Solid Two-Phase Upward Flow in Fully Developed Region of CFB Riser ”, J. Chem. Ind. Eng., 52(11), 963-968, 2001.
74 Huang W-X, Shi Y-F and Zhu J-X, “Pressure Gradients and Flow Behaviors in a 16m High Gas-Solid Riser of CFB”, J. Chem. Eng. Chinese Univ., 15(2), 109-114, 2001.
75 Huang W-X, Xiao Z-Y, Shi Y-F and Zhu J-X, “Acceleration Behaviors of Particles in Gas-Solid Two-Phase Upward Flow”, Chem. Reaction Eng. Technol., 17(2), 101-106, 2001.
76 Zhu J-X and Manyele S V, “Radial Nonuniformity Index (RNI) in Fluidized Beds and Other Multiphase Flow Systems”, Can. J. Chem. Eng., 79(2), 203-213, 2001.
77 Zhu J-X, Li G-Z, Qin S-Z, Li F-Y, Zhang H and Yang Y-L, “Direct Measurements of Particle Velocities in Gas-Solids Suspension Flow Using a Novel Five-Fiber Optical Probe”, Powder Technol., 115(2), 184-192, 2001.
78 Huang W-X and Zhu J-X, “An Experimental Investigation on Solid Acceleration Length in the Riser of a Long Circulating Fluidized Bed”, Chinese J. Chem. Eng., 9(1), 70-76, 2001.
79 Wang F-J, Zhu J-X and Beeckmans J M, “Pressure Gradient and Particle Adhesion in the Pneumatic Transport of Cohesive Fine Powders”, Int. J. Multiphase Flow, 26(1), 245-265, 2000.
80 Liu J-Z, Grace J R, Bi H-T, Morikawa H and Zhu J-X, “Gas Dispersion in Fast Fluidization and Dense Suspension Upflow”, Chem. Eng. Sci., 54(22), 5441-5449, 1999.
81 Bu J-J and Zhu J-X, “Influence of Ring-Type Internals on Axial Pressure Distribution in Circulating Fluidized Bed”, Can. J. Chem. Eng., 77(1), 26-34, 1999.
82 Zhang H, Johnston P J, Zhu J-X, de Lasa HI and Bergougnou M A, “A Novel Calibration Procedure for a Fiber Optic Concentration Probe, Powder Technol., 100(2-3), 260-272, 1998.
83 Zhu J-X, Salah M and Zhou Y-M, “Radial and Axial Voidage Distributions in Circulating Fluidized Bed with Ring-Type Internals”, J. Chem. Eng. Jpn., 30(5), 928-937, 1997.
84 Hong J and Zhu J-X, “Effect of Pipe Orientation on Dense-Phase Transport I: Critical Angle in Inclined Upflow”, Powder Technol., 91(2), 115-122, 1997.
85 Beeckmans J M, Usta B and Zhu J-X, “Effect of Tap Spacing on Observed Differential Pressure Fluctuations in a Pneumatic Transport Line”, Can. J. Chem. Eng., 74(6), 834-839, 1996.
86 Lockhart C, Zhu J-X, Brereton C M H, Lim C J and Grace J R, “Local Heat Transfer, Solids Concentration and Erosion around Membrane Tubes in a Cold Model Circulating Fluidized Bed”, Int. J. Heat Mass Tran., 38(13), 2403-2410, 1995.
87 Brereton C M H, Lim C J, Grace J R, Luckos A and Zhu J-X, “Pitch and Coke Combustion in a Circulating Fluidized Bed”, Fuel, 74(10), 1415-1423, 1995.
88 Zhou J, Grace J R, Qin S, Brereton C, Lim C J and Zhu J-X, “Voidage Profiles in a Circulating Fluidized Bed of Square Cross-Section”, Chem. Eng. Sci., 49(19), 3217-3226, 1994.
89 Bi H-T, Grace J R and Zhu J-X, “Types of Choking in Vertical Pneumatic Systems”, Int. J. Multiphase Flow, 19(6), 1077-1092, 1993.
90 Yang Y-L, Jin J, Yu Z-Q, Zhu J-X and Bi H-T, “Local Slip Behaviours in the Circulating Fluidized Bed”, AIChE Symp. Ser., 89(296), 81-90, 1993.
91 Bai D-R, Jin Y, Yu Z-Q and Zhu J-X, “The Axial Distribution of the Cross-Sectionally Averaged Voidage in Fast Fluidized Beds”, Powder Technol., 71(1), 51-58, 1992.
(C) Downer Reactors:
92 Wang C-X, Zhu J-X, Lan X-Y and Gao J-S, “Research Progress of Solids Holdup Increase and Solids Distribution Enhancement in Downer Reactors”, J. Chem. Ind. Eng., 66(8), 2810-2816, 2015.
93 Wang C-X, Zhu J-X and Li C, “Axial Solids Flow Structure in a High Density Gas-Solids Circulating Fluidized Bed Downer”, Powder Technol., 272, 153-164, 2015.
94 Wang C-X, Li C-Y and Zhu J-X, “A Comparison of Flow Development in High Density Gas-Solids Circulating Fluidized Bed Downer and Riser Reactors”, AIChE J., 61(4), 1172-1183, 2015.
95 Wang C-X, Zhu J-X and Barghi S, “Performance Evaluation of High Density Riser and Downer: Experimental Study Using Ozone Decomposition”, Chem. Eng. J., 262, 478-489, 2014.
96 Wang C-X, Barghi S and Zhu J-X, “Hydrodynamics and Reactor Performance Evaluation of a High Flux Circulating Fluidized Bed Downer: Experimental Study”, AIChE J., 60(10), 3412-3423, October, 2014.
97 Li D-B, Ray M, Ray A and Zhu J-X, “A Comparative Study on Hydrodynamics of Circulating Fluidized Bed Riser and Downer”, Powder Technol., 247, 235-259, 2013.
98 Li D-B, Zhu J-X, Ray M B and Ray A K “Catalytic Reaction in a Circulating Fluidized Bed Downer: Ozone Decomposition”, Chem. Eng. Sci., 66(20), 4615-4623, 2011.
99 Manyele S V, Zhu J-X and Zhang H, “Characterizing Cluster in Dynamic Co-current Downflow CFB Using Optical Fiber Probe”, Chem. Industry and Eng. Society of China, 61(7), 1753-1769, 2010.
100 Cheng Y, Wu C N, Zhu J-X, Wei F and Jin Y, “Downer Reactor: from Fundamental Study to Industrial Application”, Powder Technol., 183(3), 364-384, 2008. (Review)
101 Qi X-B, Zhang H and Zhu J-X, “Friction between Gas-Solid Flow and Circulating Fluidized Bed Downer Wall”, Chem. Eng. J., 142(3), 318-326, 2008.
102 Qi X-B, Zhang H and Zhu J-X, “Solids Concentration in the Fully Developed Region of Circulating Fluidized Bed Downers”, Powder Technol., 183(3), 417-425, 2008.
103 Wu B-Y, Zhu J-X, Briens L and Zhang H, “Flow Dynamics in a Four-inch Downer Using Solids Concentration Measurements”, Powder Technol., 178(4), 187-193, 2007.
104 Qi X-B, Zhang H, Huang W-X and Zhu J-X. “Solids Concentrations in the Fully Developed Zone of CFB Downers”. J. Chem. Eng. Chinese Univ., 21(4), 621-626, 2007.
105 Wu B-Y, Zhu J-X and Briens L, “A Comparison of Flow Dynamics and Flow Structure in a Riser and a Downer”, Chem. Eng. & Technol., 30(4), 448-459, 2007. (163)
106 Luo B-L, Yan D, Ma Y-L, Barghi S and Zhu J-X, “Characteristics of Gas-Solid Mass Transfer in a Cocurrent Downflow Circulating Fluidized Bed Reactor”, Chem. Eng. J., 132(1-3), 9-15, 2007.
107 Zhang H and Zhu J-X, “Gas-Solids Flow Behavior with a Gas Velocity close to Zero”, Particuologoy, 4(3-4), 167-177, 2006.
108 Manyele S V, Zhu J-X and Zhang H, “Analysis of the Microscopic Flow Structure of a CFB Downer Reactor Using Solids Concentration Signals”, Int. J. Chem. Reaction Eng., A55, 1-17, 2003.
109 Bolkan Y, Berruti F, Zhu J-X and Milne B, “Hydrodynamic Modeling of CFB Risers and Downers”, Int. J. Chem. Reactor Eng., 1, A51, 1-14, 2003.
110 Bolkan Y, Berruti F, Zhu J-X and Milne B, “Modeling Circulating Fluidized Bed Downers”, Powder Technol., 132(1), 85-100, 2003.
111 Zhang H, Huang W-X and Zhu J-X, “Gas-Solids Flow Behavior: CFB Riser vs. Downer”, AIChE J., 47(9), 2000-2011, 2001.
112 Ma Y and Zhu J-X, “Heat Transfer in the Downer and the Riser of a Circulating Fluidized Bed - A Comparative Study”, Chem. Eng. & Technol., 24(1), 85-90, 2001.
113 Luo K-B, Liu W-D, Zhu J-X and Beeckmans J M, “Characterization of Gas Upward-Solids Downward Counter-Current Fluidized Flow”, Powder Technol., 115(1), 36-44, 2001.
114 Liu W-D, Luo K-B, Zhu J-X and Beeckmans J M, “Characterization of High Density Gas-Solids Downflow Fluidized Beds”, Powder Technol., 115(1), 27-35, 2001.
115 Ball J S and Zhu J-X, “A Preliminary Study into the Local Solids Fluxes in a Downer Reactor”, Powder Technol., 114(2), 96-101, 2001.
116 Zhang H and Zhu J-X, “Hydrodynamics in Downflow Fluidized Beds (2): Particle Velocity and Solids Flux Profiles”, Chem. Eng. Sci., 55(19), 4367-4377, 2000.
117 Ball J S and Zhu J-X, “A Comparison of Solids Fluxes in a Pair of Downer and Riser Reactors”, Chem. Eng. & Technol., 23(8), 701-705, 2000.
118 Ma Y and Zhu J-X, “Heat Transfer between Gas-Solids Suspensions and Immersed Surface in an Upflow Fluidized Bed (Riser)”, Chem. Eng. Sci., 55(5), 981-989, 2000.
119 Zhang H, Zhu J-X and Bergougnou M A, “Hydrodynamics in Downflow Fluidized Beds (1): Solids Concentration Profiles and Pressure Gradient Distributions”, Chem. Eng. Sci., 54(22), 5461-5470, 1999.
120 Johnston P M, Zhu J-X, de Lasa HI and Zhang H, “Effect of Distributor Designs on the Flow Development in Downer Reactor”, AIChE J., 45(7), 1587-1592, 1999.
121 Zhang H, Zhu J-X and Bergougnou M A, “Flow Development in a Gas-Solids Downer Fluidized Bed”, Can. J. Chem. Eng., 77(2), 194-198, 1999.
122 Johnston P M, de Lasa HI and Zhu J-X, “Axial Flow Structure in the Entrance Region of a Downer Fluidized Bed - Effects of the Distributor Design”, Chem. Eng. Sci., 54(13-14), 2161-2173, 1999.
123 Ma Y and Zhu J-X, “Characterizing gas and solids Distributors with Heat Transfer Study in a Gas-Solids Downflow Reactor”, Chem. Eng. J., 72(3), 235-244, 1999.
124 Zhu J-X, Ma Y and Zhang H, “Gas-Solids Contact Efficiency in the Entrance Region of a Co-Current Downflow Fluidized Bed (Downer)”, Chem. Eng. Res. Dev., 77(A), 151-158, 1999.
125 Ma Y and Zhu J-X, “Experimental Study of Heat Transfer in a Co-Current Downflow Fluidized Bed (Downer)”, Chem. Eng. Sci., 54(1), 41-50, 1999.
126 Jiao S-Y, Zhu J-X, Bergougnou M A, Ikura M and Stanciulescu M, “Investigation and Modelling of the Thermal Cracking of Waste Plastics Derived Oil in a Downer Reactor”, Chem. Eng. Res. Dev. (Process. Saf. Environ.), 76(B4), 319-331, 1998.
127 Yang Y-L, Zhu J-X, Yin Y and Yu Z-Q, “Investigation and Modelling of Cocurrent Downflow Circulating Fluidized Bed (Downer)”, Chem. Eng. Commun., 170, 133-157, 1998.
128 Yang Y-L and Zhu J-X, “Modelling the Gas and Solids Flow in Gas-Solid Downer Reactors”, Chem. Reaction Eng. Technol., 13(1), 98-112, 1997.
129 Wei F and Zhu J-X, “Effect of Flow Direction on Axial Solids Dispersion in Gas-Solids Cocurrent Upflow and Downflow Systems”, Chem. Eng. J., 64(3), 345-352, 1996.
130 Wei F and Zhu J-X, “Gas and Solids Mixing in Cocurrent Gas-Solid Downer Fluidized Beds”, Chem. Reaction Eng. Technol., 12(4), 429-437, 1996.
131 Zhu J-X and Wei F, “Gas and Solids Flow Structure in Gas-Solid Downer Reactors”, Chem. Reaction Eng. Technol., 12(3), 323-335, 1996.
132 Zhu J-X, Wei F and Yang Y-L, “Cocurrent Gas-Solid Downflow Fluidized Bed (Downer) Reactors: Development and Applications”, Chem. Reaction Eng. Technol., 12(2), 214-224, 1996.
133 Zhu J-X, Yu Z-Q, Jin Y, Grace J R and Issangya A, “Cocurrent Downflow Circulating Fluidized Bed (Downer) Reactors - A State of the Art Review”, Can. J. Chem. Eng., 73(5), 662-677, 1995. (Review)
(D) GSCFB (Gas-Solid Circulating Fluidized Bed) – Modelling and Correlations:
134 Fu Z-J, Zhu J-X, Barghi S, Zhao Y-M, Luo, Z-F and Duan C-L, “Minimum Fluidization Velocity Growth due to Bed Inventory Increase in an Air Dense Medium Fluidized Bed”, Chem. Eng. J., 359, 1372-1378, 2019.
135 Fu Z-J, Zhu J-X, Shahzad B, Zhao, Y-M, Zhenfu Luo Z-F and Duan C-L, “Dry Coal Beneficiation by the Semi-Industrial Air Dense Medium Fluidized Bed with Binary Mixtures of Magnetite and Fine Coal Particles”, Fuel, 243, 509-518, 2019.
136 Li W-B, Shao Y-Y and Zhu J-X, “Anisotropic Turbulent Mass Transfer Model and its Application to a Gas-Particle Bubbling Fluidized Bed”, I&EC Res., 57(5), 1671-1678, 2018.
137 Li W-B, Zhang Y-W, Shao Y-Y and Zhu J-X, “A Rigorous Model for the Simulation of Chemical Reaction in Gas-Particle Bubbling Fluidized Bed: I. Modeling and Validation”, Powder Technol., 327, 399-407, 2018.
138 Li W-B, Yu K-S, Yuan X-G, Shao Y-Y and Zhu J-X, “Simulation of Chemical Reaction Process in Gas-Particle CFB Downers by Anisotropic Turbulent Mass Transfer Model”, Chem. Eng. Res. and Design, 132, 452-459, 2018.
139 Zhang Y-W, Li W-B, Shao Y-Y and Zhu J-X, “A Rigorous Model for the Simulation of Chemical Reaction in Gas-Particle Bubbling Fluidized Bed: II. Application to Gas Combustion Case”, Powder Technol., 327, 392-398, 2018.
140 Li W-B, Yu K-S, Yuan X-G, Zhu J-X, Liu B-T and Shao Y-Y, “An Anisotropic Reynolds Mass Flux Model for the Simulation of Chemical Reaction in Gas-Particle CFB Risers”, Chem. Eng. Sci., 135, 117-127, 2015.
141 Kong L, Zhang C and Zhu J-X, “Evaluation of the Effect of Wall Boundary Conditions on Numerical Simulations of Circulating Fluidized Beds”, Particuology, 13, 114-123, 2014.
142 Peng B-T, Zhu J-X and Zhang C, “Numerical Study on the Effect of the Air Jets at the Inlet Distributor in the Gas−Solids Circulating Fluidized-Bed Risers”, Ind. Eng. Chem. Res., 49(11), 5310-5322, 2010.
143 Peng B-T, Zhang C and Zhu J-X, “Numerical Study of the Effect of the Gas and Solids Distributors on the Uniformity of the Radial Solids Concentration Distribution in CFB Risers”, Powder Technol., 212(1), 89-102, 2011.
144 Peng B-T, Zhang C and Zhu J-X, “Theoretical and Numerical Studies on the Flow Multiplicity Phenomenon for Gas-Solids Two-Phase Flows in CFB Risers”, International J. of Multiphase Flow, 37(6), 660-670, 2011.
145 Peng B-T, Xu J, Zhu J-X and Zhang C, “Numerical and Experimental Studies on the Flow Multiplicity Phenomenon for Gas-Solids Two-Phase Flows in CFB Risers”, Powder Tchnol., 214(2), 177-187, 2011.
146 Peng B-T, Zhang C and Zhu J-X, “Improvement of the Uniformity of Radial Solids Concentration Profiles in Circulating Fluidized Bed Risers”, Chem. Eng. & Tech., 35(4), 627-634, 2012.
147 Peng B-T, Zhu J-X and Zhang C, “A New Approach to Specify the Inlet Boundary Conditions for Computational Fluid Dynamics (CFD) Modeling of Hydrodynamic Behavior of a Circulating Fluidized Bed (CFB) Riser”, Ind. & Eng. Chem. Res.(I&EC), 51(4), 2152-2165, 2012.
148 Qi X-B, Zhu J-X and Huang W-X, “A New Correlation for Predicting Solids Concentration in the Fully Developed Zone of Circulating Fluidized Bed Risers”, Powder Technol., 188(1), 64-72, 2008.
149 Qi X-B, Huang W-X and Zhu J-X, “Friction between Co-current Upward Gas-solid Flow and Column Wall”, Asia-Pacific J. of Chem. Eng., 3(3), 307-319, 2008.
150 Qi X-B, Huang W-X, Zhu J-X and Shi Y-F, “Correlation and Prediction of Solids Holdups of Gas-Solid Two-Phase Flow in Fully Developed Region of CFB Risers.” J. Chem. Eng. Chinese Univ., 19(5), 613-618, 2005.
151 Ma L-P, Huang W-X, Shi Y-F, Yu H-Y and Zhu J-X, “Multifractal Analysis of Particle-Fluid System in a Circulating Fluidized Bed”, China Particuology, 3(1-2), 80-83, 2005.
152 Li X-X, Shi Y-F, Huang W-X, Yu H, Zhu J-X, “Nonlinear Analysis of Gas-Solid Flow Behavior in Fast Fluidized Bed Riser”, J. Chem. Ind. Eng., 55(2), 182-188, 2004.
153 Li X-X, Shi Y-F, Huang W-X, Qi X-B, Yu H-R and Zhu J-X, “Non-Linear Model for the Calculation of the Time Series of Local Particle Concentration in a Gas-Solid Circulating Fluidized Bed Based on Chaos and Neural Network Method”, J. Chem. Eng. Chinese Univ., 17(5), 580-584, 2003.
154 Bai D-R, Zhu J-X, Jin Y and Yu Z-Q, “Simulation of FCC Catalyst Regeneration in a Riser Regenerator”, Chem. Eng. J., 71(2), 97-109, 1998.
155 Bai D-R, Zhu J-X, Jin Y and Yu Z-Q, “Novel Designs and Simulations of FCC Riser Regeneration”, Ind. Eng. Chem. Res., 36(11), 4543-4548, 1997.
156 Bai D-R, Zhu J-X, Jin Y and Yu Z-Q, “Internal Recirculation Flow Structure in Vertical Upflow Gas-Solids Suspensions, Part II: Flow Structure Predictions”, Powder Technol., 85(2), 179-188, 1995.
157 Bai D-R, Zhu J-X, Jin Y and Yu Z-Q, “Internal Recirculation Flow Structure in Vertical Upflow Gas-Solids Suspensions, Part I: A Core-Annular Model”, Powder Technol., 85(2), 171-177, 1995.
(E) Conventional Fluidization:
158 Dubrawski K, Tebianian S, Bi H-T, Chaouki J, Ellis N, Gerspacher R, Jafari R, Kantzas A, Lim C, Patience G S, Pugsley T, Qi M-Z, Zhu J-X and Grace J R, “Traveling Column for Comparison of Invasive and Non-Invasive Fluidization Voidage Measurement Techniques”, Powder Technol., 235, 203-220, 2013.
159 Li J-J, Zhu J-X, Bassi A S and Kofman S H, “Evaluation of Different Dental Materials Using a Slugging Fluidized Bed”, Powder Technol., 118(3), 275-284, 2001.
160 Bai D-R, Grace J R and Zhu J-X, “Characterization of Gas Fluidized Beds of Group C, A and B Particles based on Pressure Fluctuations”, Can. J. Chem. Eng., 77(2), 319-324, 1999.
161 Zhu J-X and Hong J, “Development and Current Status of Research on Spouted Beds”, Chem. Reaction Eng. Technol., 13(2), 207-222, 1997.
162 Lim K S, Zhu J-X and Grace J R, “Hydrodynamics of Gas-Solid Fluidization”, Int. J. Multiphase Flow, 21(Suppl.), 141-193, 1995. (Review Paper)
163 Zhang J P, Epstein E, Grace J R and Zhu J-X, “Minimum Liquid Fluidization Velocity of Gas-Liquid Fluidized Beds”, Chem. Eng. Res. Des., 73(A3), 347-353, 1995.
164 Bi H T, Grace J R and Zhu J-X, “Propagation of Pressure Waves and Forced Oscillations in Gas-Solid Fluidized Beds and their Influence on Diagnostics of Local Hydrodynamics”, Powder Technol., 82(3), 239-253, 1995.
165 Bi H T, Grace J R and Zhu J-X, “Regime Transitions Affecting Gas-Solids Suspensions and Fluidized Beds”, Chem. Eng. Des. Dev., 73(A2), 154-161, 1995.
166 Zahed A H, Zhu J-X and Grace J R, “Modelling and Simulation of Batch and Continuous Fluidized Bed Dryers”, Drying Technol., 13(1-2), 1-28, 1995.
167 He Y-L, Lim C J, Grace J R, Zhu J-X and Qin S-Z, “Measurements of Voidage Profiles in Spouted Beds”, Can. J. Chem. Eng., 72(2), 229-234, 1994.
168 Zhu J-X, Lim C J, Grace J R and Lund J A, “Tube Wear in Gas Fluidized Beds - II. Low Velocity Impact Erosion and Semi-Empirical Model for Bubbling and Slugging Fluidized Beds”, Chem. Eng. Sci., 46(4), 1151-1156, 1991.
169 Zhu J-X, Grace J R and Lim C J, “Tube Wear in Gas Fluidized Beds - I. Experimental Findings”, Chem. Eng. Sci., 45(4), 1003-1015, 1990.
(F) CTFB (Circulating Turbulent Fluidized Bed) and TFB (Turbulent Fluidized Bed):
170 Yan L-L, Zhu J-X, Lan X-Y and Gao J-S, “Comparative Study of Two Novel Fluidized Beds-HDCFB and CTFB”, J. Chem. Ind. Eng., 65(7), 2495-2503, 2014. (Review)
171 Zhu J-X, Qi M-Z and Barghi S, “Identification of the Flow Structures and Regime Transition in Gas-Solid Fluidized Beds through Moment Analysis”, AIChE, 59(5),1479-1490, May, 2013.
172 Qi M-Z, Barghi S, Zhu J-X, “Particle Velocity and Flux Distribution in a High Solids Concentration Circulating Turbulent Fluidized Bed”, Chem. Eng. Sci., 84, 437-448, 2012.
173 Qi M-Z, Barghi S and Zhu J-X, “Detailed Hydrodynamics of High Flux Gas-Solid Flow in a Circulating Turbulent Fluidized Bed”, Chem. Eng., 209, 633-644, 2012.
174 Zeng T, Qi X-B, Huang W-X, Zhu J-X, “Experimental Study of Local Solid Concentration Distribution in a Square Gas-Solid Fluidized Bed”, J. Chem. Eng. Chinese Univ., 5(24), 783-788, 2010.
175 Zeng T, Qi X-B, Huang W-X and Zhu J-X, “Experimental Study of Flow Regime Transition from Bubbling to Turbulent Fluidization in a Square Gas-solid Turbulent Fluidized Bed”, J. of Sichuan University, 42(4), 176-180, 2010.
176 Zhu J-X, “Circulating Turbulent Fluidization - A New Fluidization Regime or just a Transitional Phenomenon”, Particuology, 8(6), 640-644, 2010. (Review)
177 Qi X-B, Zhu H-Y and Zhu J-X, “Demarcation of a New Circulating Turbulent Fluidization Regime”, AIChE, 55(3), 594-611, 2009.
178 Zhu H-Y and Zhu J-X, “Comparative Study of Flow Structures in a Circulating-turbulent Fluidized Bed”, Chem. Eng. Sci., 63(11), 2920-2927, 2008.
179 Zhu H-Y and Zhu J-X, “Gas-solids Flow Structures in a Novel Circulating-turbulent Fluidized Bed”, AIChE J., 54(5), 1213-1223, 2008.
180 Zhu H-Y and Zhu J-X, “New Investigation in Regime Transition from Bubbling to Turbulent Fluidization”, Can. J. Chem. Eng., 86(3), 553-562, 2008.
181 Zhu H-Y and Zhu J-X, “Characterization of Fluidization Behavior in the Bottom Region of CFB Riser”, Chem. Eng. J., 141(1), 169-179, 2008.
182 Zhu H-Y, Zhu J-X, Li G-Z and Li F-Y, “Detailed Measurements of Flow Structure Inside a Dense Gas-Solids Fluidized Bed”, Powder Technol., 180(3), 339-349, 2008.
(G) LSCFB and GLSCFB (Liquid-Solid and Gas-Liquid-Solid Circulating Fluidized Bed) – Fundamentals:
183 Chen S-Q, Shao Y-Y, Ma K-Y, Zheng Y, Zhu J-X, “Development and applications of liquid-solid circulating fluidized beds---Process integration and intensification”, Chem. Ind. Eng. Process, 38(1), 122-135, 2018.
184 An Z-Q, Zhang, Y-L and Zhu J-X, “Effect of Particle Shape on the Apparent Viscosity of Liquid-Solid Suspensions”, Powder Technol., 328(1), 199-206, 2018.
185 Lin H-B, Zhu J-X and Lan C-X, “Experimental Analysis of Bed Expansion Properties in Gas-Liquid-Solid Three Phase Fluidized Beds”, Huaxue Gongcheng/Chem. Eng. (China), 45(6), 44-49, 2017.
186 Dadashi A, Zhu J-X and Zhang C, “A Computational Fluid Dynamics Study on the Flow Field in a Liquid-Solid Circulating Fluidized Bed Riser”, Powder Tech., 260, 52-58, 2014.
187 Razzak S A, Rahman S M, Hossain M M and Zhu J-X, “Investigation of Artificial Neural Network Methodology for Modeling of a Liquid-Solid Circulating”, Powder Tech., 229, 71-77, 2012.
188 Sang L and Zhu J-X, “Experimental Investigation of the Effects of Particle Properties on Solids Holdup in an LSCFB Riser”, Chem. Eng. J., 197, 322-329, 2012.
189 Razzak S A, Rahman S M, Hossain M M and Zhu J-X, “Artificial Neural Network and Neuro-Fuzzy Methodology for Phase Distributions Modeling of a Liquid-Solid Circulating Fluidized Bed Riser”, Ind. Eng. and Chem. Res., 51(38), 12497-12508, 2012.
190 Razzak S A, Zhu J-X, Barghi S “Effects of Particle Shape, Density, and Size on a Distribution of Phase Holdups in a Gas Liquid Solid Circulating Fluidized Bed Riser”, Ind. Eng. Chem. Res., 49(15), 6998-7007, 2010.
191 Razzak S A, Barghi S and Zhu J-X, “Axial Hydrodynamics Studies in a Gas-Liquid-Solid Circulating Fluidized Bed Riser”, Powder Technol., 199(1), 77-86, 2010.
192 Razzak S A, Zhu J-X, Barghi S “Particle Shape, Density, and Size Effects on the distribution of Phase Holdups in an LSCFB Riser”, Chem. Eng. Technol., 32(8), 1236-1244, 2009.
193 Atta A, Razzak S A, Nigam K and Zhu J-X, “(Gas)-Liquid-Solid Circulating Fluidized Bed Reactors: Characteristics and Applications”, I&EC Research, 48(17), 7876-7892, 2009. (Review)
194 Razzak S A, Barghi S and Zhu J-X, “Application of electrical resistance tomography on liquid-solid two-phase flow characterization in an LSCFB riser”, CES, 64(12), 2851-2858, 2009.
195 Razzak S A, Zhu J-X, Barghi S, “Phase Holdup Measurement in a Gas-Liquid-Solid Circulating Fluidized Bed (GLSCFB) Riser Using Electrical Resistance Tomography and Optical Fibre Probe”, CEJ, 147(2-3), 210-218, 2009.
196 Razzak S A, Zhu J-X and Barghi S, “Radial Distributions of Phase Holdups and Phase Propagation Velocities in a Three-Phase Gas-Liquid-Solid Fluidized Bed (GLSCFB) Riser”, I&EC, 48(1), 281-289, 2009.
197 Razzak S A, Barghi S and Zhu J-X, “Electrical Resistance Tomography for flow characterization of a Gas-Liquid-Solid Three-Phase Circulating Fluidized Bed”, CES, 62(24), 7253-7263, 2007.
198 Razzak S A, Agarwal K Zhu J-X and Zhang C, “Numerical Investigation on the Hydrodynamics of an LSCFB Riser”, PT, 188(1), 42-51, 2008.
199 Zheng Y, Zhu J-X and Wushouer A, “Transition from Low Velocity to High Velocity in a Three Phase Fluidized Bed”, Chem. Eng. & Technol., 28(9), 1010-1015, 2005.
200 Cheng Y and Zhu J-X, “CFD Modeling and Simulation of Hydrodynamics in Liquid-Solid Circulating Fluidized Beds”, Can. J. Chem. Eng., 83(2), 177-185, 2005.
201 Zheng Y and Zhu J-X, “Radial Distribution of Liquid Velocity in a Liquid-Solids Circulating Fluidized Bed”, Int. J. Chem. Reaction Eng., 1, S1, 1-8, 2003.
202 Zheng Y, Zhu J-X, Marwaha N S and Bassi A S, “Radial Solids Flow Structure in a Liquid-Solids Circulating Fluidized Bed”, Chem. Eng. J., 88(2), 141-150, 2002.
203 Zheng Y and Zhu J-X, “The Onset Velocity of a Liquid-Solid Circulating Fluidized Bed”, Powder Technol., 114(3), 244-251, 2001.
204 Zheng Y and Zhu J-X, “Overall Pressure Balance and System Stability in a Liquid-Solid Circulating Fluidized Bed”, Chem. Eng. J., 79(2), 145-153, 2000.
205 Zhu J-X, Zheng Y, Karamanev D G and Bassi A S, “(Gas-)Liquid-Solid Circulating Fluidized Beds and their Potential Applications to Bioreactor Engineering”, Can. J. Chem. Eng., 78(2), 82-94, 2000. (Review)
206 Zheng Y and Zhu J-X, “Microstructure Aspects of the Flow Behaviour in a Liquid-Solids Circulating Fluidized Bed”, Can. J. Chem. Eng., 78(2), 75-81, 2000.
207 Zheng Y, Zhu J-X, Wen J-Z, Martin S, Bassi A S and Margaritis A, “The Axial Hydrodynamic Behaviour in a Liquid-Solid Circulating Fluidized Bed”, Can. J. Chem. Eng., 77(2), 284-290, 1999.
208 Liang W-G and Zhu J-X, “Effect of Radial Flow Nonuniformity on the Alkylation Reaction in a Liquid-Solid Circulating Fluidized Bed (LSCFB) Reactor”, Ind. Eng. Chem. Res., 36(11), 4651-4658, 1997.
209 Liang W-G and Zhu J-X, “A Core-Annulus Model for the Radial Flow Structure in a Liquid-Solid Circulating Fluidized Bed (LSCFB)”, Chem. Eng. J., 68(1), 51-62, 1997.
210 Liang W-G, Zhang S-L, Zhu J-X, Yu Z-Q, Jin Y and Wang Z-W, “Flow Characteristics of the Liquid-Solid Circulating Fluidized Bed”, Powder Technol., 90(2), 95-102, 1997.
211 Liang W-G, Jin Y, Yu Z-Q, Wang Z-W, Zhu J-X and Chen J, “Flow Characteristics and Mixing Properties in a High Velocity Liquid-Solid Loop Reactor”, Chem. Eng. J., 63(3), 181-188, 1996.
212 Liang W-G, Zhu J-X, Jin Y, Yu Z-Q, Wang Z-W and Zhou J, “Radial Nonuniformity of Flow Structure in a Liquid-Solid Circulating Fluidized Bed”, Chem. Eng. Sci., 51(10), 2001-2010, 1996.
(H) LSCFB (Liquid-Solid and Gas-Liquid-Solid Circulating Fluidized Bed) - Biological Applications:
213 Bassi A S, Zhu J-X, Lan Q-D, Margaritis A and Zheng Y, "Continuous Ion Exchange Using a liquid-Solid Circulating Fluidized Bed", U.S. Patent 6,716,344, April 6, 2004.
214 Bassi A S, Zhu J-X, Lan Q-D, Margaritis A and Zheng Y, "Continuous Ion Exchange Using a liquid-Solid Circulating Fluidized Bed", Canadian Patent 2,322,348, November 4, 2008.
215 Bassi A S, Zhu J-X, Lan Q-D, Margaritis A and Zheng Y, "Method for Recovering Ionic Products", U.S. Patent 6,887,368, May 3, 2005.
216 Dadashi A, Zhu J-X and Zhang C, “CFD Modelling of Continuous Protein Extraction Process Using Liquid-Solid Circulating Fluidized Beds”, Canadian J. Chem. Eng., 92(11), 1911-1919, 2014.
217 Dadashi A, Zhu J-X and Zhang C, “Numerical Simulation of Counter-Current Flow Field in the Downcomer of a Liquid-Solid Circulating Fluidized Bed”, Particuology, Accepted.
218 Dadashi A, Zhu J and Zhang C, “CFD Modeling of Continuous Protein Extraction Process Using Liquid-Solid Circulating Fluidized Beds"”, Can. J. Chem. Eng., accepted.
219 Prince A, Bassi A S, Haas C, Zhu J-X and Dawe J, “Soy Protein Recovery in a Solvent-Free Process Using Continuous Liquid-Solid Circulating Fluidized Bed Ion Exchanger”, Biotech. Pro., 28(1), 157-162, 2012.
220 Mazumder J, Zhu J-X and Ray A K, “Optimal Design of Liquid-Solid Circulating Fluidized Bed for Continuous Protein Recovery”, Powder Technol., 199(1), 32-47, 2010.
221 Mazumder J, Zhu J-X, Bassi A S and Ray A K, “Modeling and Simulation of Liquid–Solid Circulating Fluidized Bed Ion Exchange System for Continuous Protein Recovery”, Biotech & Bioeng, 104(1), 111-126, 2009.
222 Mazumder J, Zhu J-X, Amarjeet S. Bassi A S and Ray A K, “Multiobjective Optimization of the Operation of a Liquid–Solid Circulating Fluidized Bed Ion-Exchange System for Continuous Protein Recovery”, Biotech. & Bioeng., 103(5), 873-890, 2009.
223 Patel M, Bassi A S, Zhu J-X, and Gomaa H, “Investigation of a Dual-Particle Liquid-Solid Circulating Fluidized Bed Bioreactor for Extractive Fermentation of Lactic Acid”, Biotech. Prog., 24(4), 821-831, 2008.
224 Cheng Y and Zhu J-X, “Hydrodynamics and Scale-up of Liquid-Solid Circulating Fluidized Beds: Similitude Method VS. CFD”, Chem. Eng. Sci., 63(12), 3201-3211, 2008.
225 Trivedi U J, Bassi A S and Zhu J-X, “Continuous enzymatic polymerization of phenols in a liquid-solid circulating fluidized bed”, Powder Technol., 169(2), 61-70, 2006.
226 Trivedi U J, Bassi A S and Zhu J-X, “Investigation of Phenol Removal using Sol-gel/Alginate Immobilized Soybean Seed Hull Peroxidase”, Can. J. Chem. Eng., 84(2), 239-247, 2006.
227 Lan Q-D, Bassi A S, Zhu J-X, Margaritis A, “Continuous Protein Recovery from Whey Using Liquid-Solid Circulating Fluidized Bed Ion-exchange Extraction”, Biotech. & Bioeng., 78(2), 157-163, 2002.
228 Lan Q-D, Bassi A S, Zhu J-X, Margaritis A, “Continuous Protein Recovery with Liquid-Solid Circulating Fluidized Bed Ion Exchanger”, AIChE J., 48(2), 252-261, 2002.
229 Lan Q-D, Bassi A S, Zhu J-X and Margaritis A, “A Modified Langmuir Model for the Prediction of the Effects of Ionic Strength on the Equilibrium Characteristics of Protein Adsorption onto Ion Exchange/Affinity Adsorbents”, Chem. Eng. J., 81(1-3), 179-186, 2001.
230 Lan Q-D, Zhu J-X, Bassi A S, Margaritis A, Zheng Y and Rowe G N, “Continuous Protein Recovery Using a Liquid-Solid Circulating Fluidized Bed Ion Exchange System: Modelling and Experimental Studies”, Can. J. Chem. Eng., 78(5), 858-866, 2000.
(I) LS/GLS-FBBR (Liquid-Solid Circulating Fluidied Bed Bioreactor) -- Wastewater Treatment:
231 Wang L, Li M, Shao Y-Y, George N, “Effects of Bioparticle Circulation Rate on the Performance of Circulating Fluidized Bed Biofilm Reactor”, Technology of Water Teatment, 8, 61-65, 2018.
232 Nelson M, Zhu J-X and Nakhla G, “Fluidized Bed Bioreactor Applications for Biological Wastewater Treatment: A Review of Research and Developments”, Engineering, 3(3) 330-342, June, 2017.
233 Ragab D, Gomaa HG, Sabouni R, Salem M, Ren M and Zhu J-X, “Micropollutants Removal from Water Using Microfiltration Membrane Modified with ZIF-8 Metal Organic Frameworks (MOFs)”, Chem. Eng. J., 300, 273-279, 2016.
234 Zhu J-X, Nakhla G and Cui Y, "Liquid-Solid Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", U.S. Patent 7,736,513, June 15, 2010
235 Zhu J-X, Nakhla G and Cui Y, "Liquid-Solid Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", Chinese Patent ZL2008-8001,3568.7, April 27, 2010.
236 Zhu J-X, Nakhla G and Cui Y, "Liquid-Solid Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", Canadian Patent 2,703,065, June 2013.
237 Zhu J-X, Nakhla G and Cui Y, "Liquid-Solid Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", European Patent EP 2,197,799 A1, Feb. 13, 2013.
238 Nakhla G, Zhu J-X and Cui Y, "Liquid-Solid Circulating Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", U.S. Patent 7,261,811, August 28, 2007.
239 Nakhla G, Zhu J-X, and Cui Y, "Liquid-Solid Circulating Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", Chinese Patent, ZL2005-8000,5561.X, March 17, 2010.
240 Nakhla G, Zhu J-X and Cui Y, "Removal of Carbon, Nitrogen and Phosphorus from Waste Water Using Fluidized Beds", Canadian Patent 2,557,070, Sept 2013.
241 Nakhla G, Zhu J-X, and Cui Y, "Liquid-Solid Circulating Fluidized Bed Waste Water Treatment System for Simultaneous Carbon, Nitrogen and Phosphorus Removal", European Patent, EP1,723,083A4, September, 2012. (Designations in France 1,723,083 FR, Germany, 1,723,083 DE, Great Britain, 1,723,083 GB)
242 Wang H-L, Kim M, Li K, Shao Y-Y, Zhu J-X and Nakhla G, “Effective Partial Nitrification of Ammonia in a Fluidized Bed Bioreactor”, Enviro. Technol., 40(1), 1-8, 2017.
243 Chowdury M, Nakhla G and Zhu J-X, “Ultrasonically Enhanced Anaerobic Digestion of Thickened Waste Activated Sludge Using Fluidized Bed Reactors”, Applied Energy, 204, 807-818, October, 2017.
244 Nzila A, Razzak SA and Zhu J-X, “Bioaugmentation: An Emerging Strategy of Industrial Wastewater Treatment for Reuse and Discharge”, Int J Environ Res Public Health, 13(9), 1-20, 2016.
245 Wang Z-Q, Nakhla G and Zhu J-X, “Anaerobic Fluidized Bed Digestion of Primary and Thickened Waste Activated Sludges”, Chem. Eng. J., 284, 620-629, 2016.
246 Mustafa N, Nakhla G and Zhu J-X, “Anaerobic Digestion of Municipal Wastewater Sludges Using Anaerobic Fluidized Bed Bioreactor”, Bioresource Techl., Accepted.
247 Eldyasti A, Nakhla G and Zhu J-X, “Influence of Diffusivity and Biofilm Thickness on Nitrous Oxide (N2O) Emissions from Denitrifying Fluidized Bed Bioreactors (DFBBRs)” J. of Biotech., Accepted.
248 Mustafa N, Elbeshbishy E, Nakhla G and Zhu J-X, “Anaerobic Digestion of Municipal Wastewater Sludges Using Anaerobic Fluidized Bed Bioreactor”, Bioresource Tech., 172, 461-466, 2014.
249 Eldyasti A, Nakhla G and Zhu J-X, “Mitigation of Nitrous Oxide (N2O) Emissions from Denitrifying Fluidized Bed Bioreactors (DFBBRs) Using Calcium”, Bioresource Tech., 173, 272-283, 2014.
250 Andalib M, Elbeshbishy E, Mustafa N, Hafez H, Nakhla G and Zhu J-X, “Performance of an Anaerobic Fluidized Bed Bioreactor (AnFBR) for Digestion of Primary Municipal Wastewater Treatment Biosolids and Bioethanol Thin Stillage”, Renewable Energy, 71, 276-285, 2014.
251 Eldyasti A, Nakhla G and Zhu J-X, “Performance and Energy Properties of Different Bioparticles Used in a Denitrification Fluidized Bed Bioreactor (DFBBR)”, Biores. Tech., accepted.
252 Eldyasti A, Nakhla G and Zhu J-X, “Impact of calcium on Biofilm Morphology, Structure, Detachment and Performance in Denitrifying Fluidized Bed Bioreactors”, Chem. Eng. J., 232, 183-195, 2013.
253 Hu F-M, Zhou H-H, Jin Z-F, Sun Q, Pan Z-Y, Zhu J-X, “Biodegradation of TCP in Sequencing Batch Fluidized Bed Bioreactor with Waste Coke Particles as Carrier”, J. of Envir. Eng., 139(9), 1222-1227, April, 2013.
254 Chowdhury P, Malekshoar G, Ray M, Zhu J-X and Ray A, "Sacrificial Hydrogen Generation from Formaldehyde with TiO2/Pt Photocatalyst in Solar Radiation", Ind. Eng. Chem. Res., 52(14), 5023-5029, March, 2013,
255 Li M, Nakhla G and Zhu J-X, “Impact of Worm Predation on Pseudo-Steady-State of the Circulating Fluidized Bed Biofilm Reactor”, Bio. Tech., 128, 281-289, 2013.
256 Andalib M, Nakhla G and Zhu J-X, “High Rate Biological Nutrient Removal from High Strength Wastewater Using Anaerobic-Circulating Fluidized Bed Bioreactor (A-CFBBR)”, Bio. Tech., 118, 526-535, August, 2012.
257 Eldyasti A, Nakhla G and Zhu J-X, “Influence of Particles Properties on Biofilm Structure and Energy Consumption in Denitrifying Fluidized Bed Bioreactors (DFBBRs)”, Biores Tech., 126, 162-171, 2012.
258 Chowdhury N, Nakhla G and Zhu J-X, “A Novel Fluidized Bed Respirometric Technique for Determination of in Situ Biofilm Kinetics”, Environ. Technol., 33(4), 455-465, 2012.
259 Andalib M, Zhu J-X, Nakhla G, “A New Definition of Bed Expansion Index and Voidage for Fluidized Biofilm-Coated Particles”, Chem. Eng. J., 189-190, 244-249, 2012.
260 Eldyasti A, Nakhla G and Zhu J-X, “Development of a Calibration Protocol and Identification of the Most Sensitive Parameters for the Particulate Biofilm Models Used in Biological Wastewater Treatment”, Bioresource Tech., 111, 111-121, 2012.
261 Li M, Nakhla G and Zhu J-X, “Simultaneous Carbon and Nitrogen Removal with Enhanced Bioparticle Circulation in a Circulating Fluidized Bed Biofilm Reactor”, Chem. Eng. J., 181-182, 35-44, 2012.
262 Andalib M, Nakhla G, McIntee E and Zhu J-X “Simultaneous Methanogenesis and Denitrification Activity: An Overview of Two-decade Research”, Desalination, 279(1-3), 1-14. 2011.
263 Eldyasti A, Andalibb M, Hafeza H, Nakhlaa G and Zhu J-X, “Comparative Modeling of Biological Nutrient Removal from Landfill Leachate Using a Circulating Fluidized Bed Bioreactor (CFBBR)”, J. of Hazardous Materials, 187(1-3), 140-149, 2011.
264 Andalib M, Nakhla G, Sen D and Zhu J-X, “Evaluation of Biological Nutrient Removal from Wastewater by Twin Circulating Fluidized Bed Bioreactor (TCFBBR) Using a Predictive Fluidization Model and AQUIFAS APP”, Bioresource Technol., 102(3), 2400-2410, 2011.
265 Chowdhury N, Nakhla G, Sen D, Zhu J-X, “Modeling biological nutrient removal in a liquid-solid circulating fluidized bed bioreactor”, J. Chem. Tech. & Biotech., 85(10), 1389-1401, 2010.
266 Andalib M, Zhu J-X and Nakhla G, “Terminal Settling Velocity and Drag Coefficient of Biofilm-Coated Particles at High Reynolds Numbers”, AIChE, 56(10), 2598-2606, 2010.
267 Eldyasti A, Chowdhury N, Nakhla G, Zhu J-X, “Biological Nutrient Removal from Leachate Using a Pilot Liquid-solid Circulating Fluidized Bed Bioreactor (LSCFB)”, J. Hazardous Materials, 181, 289-297, 2010.
268 Andalib M; Nakhla G and Zhu J-X, “Biological Nutrient Removal Using a Novel Laboratory-Scale Twin Fluidized-Bed Bioreactor”, Chem. Eng. & Technol., 33(7), 1125-1136, 2010.
269 Chowdhury N, Nakhla G, Zhu J-X and Islam M, “Pilot-scale Experience with Biological Nutrient Removal and Biomass Yield Reduction in a Liquid-solid Circulating Fluidized Bed Bioreactor”, Water Envir. Res., 82(9), 772-781, 2010.
270 Chowdhury N, Zhu J-X and Nakhla G, “Effect of Dynamic Loading on Biological Nutrient Removal in a Pilot-scale Liquid-Solid Circulating Fluidized Bed Bioreactor” J. Environ. Eng., 136(9), 906-913, 2010.
271 Andalib M, Nakhla G and Zhu J-X, “Dynamic testing of the twin circulating fluidized bed bioreactor (TCFBBR) for nutrient removal from municipal wastewater” Chem. Eng. J., 162(2), 616-625, 2010.
272 Islam M, Nakhla G, Zhu J-X and Chowdhury N, “Impact of Carbon to Nitrogen Ratio on Nutrient Removal in a Liquid Solid Circulating Fluidized Bed Bioreactor (LSCFB)”. Process Biochemistry, 44(5), 578-583, 2009.
273 Chowdhury N, Zhu J-X, Nakhla G, Patel A and Islam M, “A Novel Liquid-Solid Circulating Fluidization-Bed Bioreactor for Nutrient Removal from Municipal Wastewater, Chem. Eng. Tech., 32, 364-372, 2009.
274 Chowdhury N, Nakhla G and Zhu J-X, “Load Maximization of a Liquid-Solid Circulating Fluidized Bed Bioreactor for Nitrogen Removal from Synthetic Municipal Wastewater”, Chemosphere, 71(5), 807-815, 2008.
275 Patel A, Zhu J-X and Nakhla G, “Simultaneous Carbon, Nitrogen and Phosphorous Removal from Municipal Wastewater in a Circulating Fluidized Bed Bioreactor”, Chemosphere, 65(7), 1103-1112, 2006.
276 Patel A, Nakhla G and Zhu J-X, “Detachment of Multi Species Biofilm in Circulating Fluidized Bed Bioreactor”, Biotechnol. Bioeng., 92(4), 427-437, 2005.
277 Cui Y-B, Nakhla G, Zhu J-X and Patel A, “Simultaneous Carbon and Nitrogen Removal in Anoxic-Aerobic Circulating Fluidized Bed Biological Reactor (CFBBR)”, Environ. Technol., 25(6), 699-712, 2004.
(J) Inverse and Gas-Driven Liquid-Solid and Gas-Liquid-Solid Fluidized Beds
278 380 Liu Y-J and Zhu J-X, “Flow Behaviors in Bubble-Driven Liquid-Solid Fluidized-Bed Adopting Binary Particles”, J. Chem. Ind. Eng., 70(1), 91-98, 2019.
279 Liu Y-J and Zhu J-X, “Hydrodynamics of a Bubble-Driven Liquid-Solid Fluidized Bed”, Chem. Eng. Sci., 195, 730-736, 2019.
(K) LSCFB/GLSCFB (L-S and G-L-S Circulating Fluidized Bed) – Modelling and Correlations:
280 Song Y-F, Zhu J-X, Zhang C, Sun Z-N and Lu X-F, “Comparison of Liquid-Solid Flow Characteristics in Upward and Downward Circulating Fluidized Beds by CFD Approach”, Chem. Eng. Sci., 196, 501-513, March, 2019.
281 Luo J-W, Li W-B, Shao Y-Y, Nakhla G and Zhu J-X, “Method for Determining the Hydraulic-Retention Time and Operating Conditions of a Circulating-Fluidized-Bed Bioreactor with Composition Disturbances”, Ind. Eng. Chem. Res, 58(5), 2113-2124, 2019.
282 Razzak SA, Hossainb SA, Rahmanc SM, Hossaina MM and Zhu J-X, “A Multigene Genetic Programming Approach for Modeling Effect of Particle Size in a Liquid-Solid Circulating Fluidized Bed Reactor”, Chem. Eng. Res. and Design, 134, 370-381, 2018.
283 Dadashi A, Zhu J-X and Zhang C, “Numerical Simulation of Counter-Current Flow Field in the Downcomer of a Liquid-Solid Circulating Fluidized Bed”, Particuology 21, 48-54, 2015.
284 Razzak S A, Rahman S M, Hossain M M and Zhu J-X, “Effects of Particle Size and Shape on Solids Holdups Distributions Modelling in a LSCFB Reactor using Abductive Network”, The Canadian J. of Chem. Eng., 93(9), 1686-1692, 2015.
(L) Fine Powder Handling – Fundamentals:
285 Zhu J-X, Grace J R and Pourkavoos N, "Dispensing of Ultra-Fine Particles in a Reproducible Manner", U.S. Patent 6,183,169, February 6, 2001.
286 Zhu J-X, Grace J R and Pourkavoos N, "Apparatus for Precisely Dispensing Small Amounts of Ultra-Fine Particles", European Patent 1,105,207, January 2, 2003.
287 Zhu J-X, Grace J R and Pourkavoos N, "Apparatus for Precisely Dispensing Small Amounts of Ultra-Fine Particles", Chinese Patent ZL99-810,716.6, March 19, 2003.
288 Zhu J-X, Grace J R and Jiao S-Y, "Gaseous Fluidization Aids", U.S. Patent 6,212,794, April 10, 2001.
289 Zhu J-X, Grace J R and Jiao S-Y, "Gaseous Fluidization Aids", European Patent 1,109,620, March 19, 2003.
290 Zhang H-P, Krantz M, Dong S, Zhang H, Zhu J-X, “Flowability Characterization of Fine Powder Coatings”, Paint&Coatings Ind., 48(10), 5-9, 2018. (
291 Zhang H-P, Yan B-W, Yang S, Krantz M, Shao Y-Y, Zhang H, Zhu J-X, “Application of Ultrafine Powder Coatings in Automotive Industry”, Paint & Coating Ind., 48(10), 82-87, 2018.
292 Shi T, Shao Y-Y, Zhang H-P, Zhang H and Zhu J-X, “Characterization Techniques for Determining Flow Property of Powder in Powder Coating Process”, Paint & Coatings Ind., 47(7), 58-65, 2017.
293 Kaliyaperumal S, Barghi S, Briens L, Rohani S and Zhu J-X, “Fluidization of Nano and Sub-Micron Powders Using Mechanical Vibration”, Particuoliogy, 9(3), 279-287, 2011.
294 Kaliyaperumal S, Barghi S, Zhu J-X, Briens L and Rohani S, “Effects of Acoustic Vibration on Nano and Sub-Micron Powders Fluidization”, Powder Technol., 210(2), 143-149, 2011.
295 Huang Q, Mesbah-Nejad A, Tadayyon SM, Norton P, Zhang H and Zhu J-X, “Measurement of Inter-Particle Forces by an Interfacial Force Microscope”, Particuology, 8(5), 400-406, 2010.
296 Huang Q, Zhang H and Zhu J-X, “Flow Properties of Fine Powders in Powder Coating”, Particuology, 8(1), 19-27, 2010.
297 Huang Q, Zhang H and Zhu J-X, “Onset of an Innovative Gasless Fluidized Bed-Comparative Study on the Fluidization of Fine Powders in a Rotating Drum and a Traditional Fluidized Bed”, Chem. Eng. Sci, 65(3), 1261-1273, 2010.
298 Xu C-B and Zhu J-X, “Improving Flowability of Cohesive Particles by Partial Coating on the Surfaces”, CJChE, 87(3), 403-414, 2009.
299 Krantz M, Zhang H and Zhu J-X, “Characterization of Powder Flow: Static and Dynamic Testing”, Powder Technol., 194(3), 239-245, 2009.
300 Huang Q, Zhang H and Zhu J-X, “Experimental Study on Fluidization of Fine powders in Rotating Drums with Various Wall Friction and Baffled Rotating Drums, CES, 64(9), 2234-2244, 2009.
301 Xu C-B and Zhu J-X, “Prediction of the Minimum Fluidization Velocity for Fine Particles of Various Degrees of Cohesiveness”, Chem. Eng. Comm., 196(4), 499-517, 2009.
302 Xu C-B and Zhu J-X, “Effects of Gas Type and Temperature on Fine Particle Fluidization”, Particuologoy, 4(3-4), 114-121, 2006.
303 Xu C-B, Cheng Y and Zhu J-X, “Fluidization of Fine Particles in a Sound Field and Identification of Group C/A Particles Using Acoustic Waves”, Powder Technol., 161(3), 227-234, 2006.
304 Xu C-B and Zhu J-X, “Parametric Study of Fine Particle Fluidization under Mechanical Vibration”, Powder Technol., 161(2), 135-144, 2006.
305 Xu C-B and Zhu J-X, “Experimental and Theoretical Study on the Agglomeration Arising from Fluidization of Cohesive Particles - Effects of Mechanical Vibration”, Chem. Eng. Sci., 60(23), 6529-6541, 2005.
306 Xu C-B and Zhu J-X, “One-step Preparation of Highly Dispersed Metal-supported Catalysts by Fluidized-bed MOCVD for Carbon Nanotube Synthesis”, Nanotechnology, 15, 1671-1681, 2004.
(M) Fine Powder Applications - Powder Coating Technology:
307 Zhu J-X, Perinpanayagam H, Mozumder ASM, Zhang H, and Wen Shi, “Biocompatible Polymer Nanoparticle Coating Composition and Method of Production Thereof”, U.S. Patent Application, April 25, 2012, + Chinese Patent Application ZL2011,1002,7700.6.
308 Zhu J-X and Zhang H, "Apparatus for Uniformly Dispensing Additive Particles in Fine Powders", U.S. Divisional Patent 8,104,702, January 31, 2012.
309 Zhu J-X and Zhang H, "Powder Blending Methods for Adding Fluidization Additives to Enhance the Flowability of Fine Powders", U.S. Patent, 7,878,430 B2, February1, 2011. + Chinese Patent Application 2007-8004,9841.X, Canadian Patent Application 2,660,046, European Patent Application 07,845,542.5.
310 Zhu J-X and Zhang H, "Method and Apparatus for Dispensing Paint Powders for Powder Coatings", U.S. Patent 7,240,861, July 10, 2007.
311 Zhu J-X and Zhang H, "Fluidization Additives to Fine Powders", U.S. Patent 6,833,185, December 21, 2004.
312 Zhu J-X and Zhang H, "Fluidization Additives to Fine Powders", Chinese Patent ZL03-816,550.3, June 3, 2009.
313 Zhu J-X and Zhang H, "Fluidization Additives to Fine Powders", Canadian Patent CA 2,492,129, Feb 8, 2011.
314 Li W-H, Shao Y-Y, Zhu J-X, Zhang H-P, Zhang H, “Reducing Comminution over-grinding of Powder Coatings with Modified Grinding Pins in an Air Classifier Mill”, Powder Technol., 344(), 36-45, 2019.
315 383 Li W-H, Franco D C, Yang S, Zhu X-P, Zhang H-P, Shao Y-Y, Zhang H, Zhu J-X, “Investigation of the performance of ATH powders in organic powder coatings”, Coatings, 9(2), 110, 2019.
316 Yeasmin R, Zhang H, Zhu J-X and Cadieux P, “Fabrication and Analysis of Antimicrobial Additives for Powder Coated Surface”, Progress in Organic Coatings, 127, 308-318, 2018.
317 Dong Shuai, Zhang Haiping, Shao Yuanyuan, Zhang Hui and Zhu Jingxu, “Cold Bonding Method for Metallic Powder Coatings”, Environ. Chem., 2018.
318 Zheng B-K, Zhang H, Shao Y-Y and Zhu J-X, “Research Progress in Ultrafine Powder Coatings”, Paint & Coatings Ind., 47(8), 76-82, 2017.
319 Yeasmin R, Zhang H, Zhu J-X and Kazemian H, “Pre-treatment and Conditioning of Chabazites Followed by Functionalization for Making Suitable Additives Used in Antimicrobial Ultra-fine Powder Coated Surfaces”, RSC Advances, 91, 88340-88349, 2016.
320 Seyedmehdi SA, Zhang H and Zhu J-X, “Influence of Production Method, Silicone Type and Thickness on Silicon Rubber Superhydrophobic Coatings”, Progress of Organic Coatings, 90, 291-295, 2016.
321 Mozumder MS, Mourad AI, Perinpanayagam H and Zhu J-X, “Nano TiO2-Enriched Biocompatible Polymeric Powder Coatings: Adhesion, Thermal and Biological Characterizations”, Advanced Mater. Res., 995, 113-124, 2014.
322 Hou N, Perinpanayagam H, Zhu J-X and Zhang H, “Ultrafine Calcium-Titania-Polyester Dry Powder Coatings Promote Human Mesenchymal Cell Attachment and Biomineralization”, J Surface and Coatings Technol., 251(25), 177-185, 2014.
323 Seyedmehdi S A, Zhang H and Zhu J-X, “Effect of Nanoclay on Electrical and Mechanical Properties of Polyurethane Conductive Coatings Filled with Nickel Coated Carbon Fibers”, Polymer Eng. Sci. J., 54(5), 1120-1125, 2014.
324 Fu J, Krantz M, Zhang H, Zhu J-X, Kuo H, Wang Y-M and Lis K, “Investigation of the Recyclability of Powder Coatings”, Powder Technol., 211(1), 38-45, 2011.
325 Fu J, Zhang H and Zhu J-X, “Improvement on the First Pass Transfer Efficiency of Fine Polymer Coating Powders for Corona Spraying Process”, Advanced Powder Tech., accepted.
326 Seyedmehdi S A, Zhang H and Zhu J-X, “Superhydrophobic RTV Silicone Rubber Insulator Coatings”, Appl. Surface Sci., 258(7), 2972-2976, 2012.
327 Seyedmehdi S A, Zhang H and Zhu J-X, “Fabrication of Superhydrophobic Coatings Based on Nanoparticles and Fluoropolyurethane”, J. Appl. Polym. Sci., 128(6), 4136-4140, June, 2013.
328 Shi W, Mozumder M S, Zhang H, Zhu J-X and Perinpanayagam H “MTA-enriched Nanocomposite TiO2-Polymeric Powder Coatings Support Human Mesenchymal Cell Attachment and Growth”, Biomedical Materials, 7(5), 1-12, 2012.
329 Mozumder M S, Zhu J-X and Perinpanayagam H, “Titania-Polymeric Powder Coatings with Nano-Topography Support Enhanced Human Mesenchymal Cell Responses”, J. Biomed. Mater., 100A(10), 2695-2709, 2012.
330 Mozumder M S, Zhang H and Zhu J-X, “Mimicking Lotus Leaf: Development of Micro-Nanostructured Biomimetic Superhydrophobic Polymeric Surfaces by Ultrafine Powder Coating Technology”, Macromolecular Matrl & Eng., 296(10), 929-936, 2011.
331 Mozumder M S, Zhu J-X and Perinpanayagam H, “Nano-TiO2 Enriched Polymeric Powder Coatings Support Human Mesenchymal Cell Attachment and Growth”, J. Biomaterials Appl., 26(2), 173-193, 2011.
332 Mozumder M S, Zhu J-X and Perinpanayagam H, “TiO2-Enriched Polymeric Powder Coatings Support Human Mesenchymal Cell Spreading and Osteogenic Differentiation”, 6(3), 1-11, J. Biomed. Materials, 2011.
333 Haile T, Nakhla G, Zhu J-X, Zhang H and Shugg J, “Mechanistic Study of the Bactericidal Action of Silver-Loaded Chabasite on Acidithiobacillus Thiooxidans”, Microporous and Mesoporous Materials, 127(1-2), 32-40, 2010.
334 Meng X-B, Zhang H and Zhu J-X, “Characterization of Particle Size Evolution of the Deposited Layer During Electrostatic Powder Coating Processes” Powder Technol., 195(3), 264-270, 2009.
335 Meng X-B, Zhu J-X and Zhang H, “Influences of Different Powders on the Characteristics of Particle Charging and Deposition in Powder Coating Processes”, J. of Electrostatics, 67(4), 663-671, 2009.
336 Meng X-B, Zhu J-X and Zhang H, “The Characteristics of Particle Charging and Deposition During Powder Coating Processes with Ultrafine Powder”, J. of Physics D: Applied Physics, 42(6), 1-12, 2009.
337 Meng X-B, Zhang H and Zhu J-X, “The Characteristics of Particle Charging and Deposition During Powder Coating Processes with Coarse Powder”, J. Phys. D: Appl. Phys. 41(19), 1-12, 2008.
338 Meng X-B, Zhu J-X and Zhang H, “The Characteristics of Current Density Distribution During Corona Charging Processes of Different Particulates”, J. of Phys. D: Appl. Phys. 41(17), 1-5, 2008.
339 Meng X-B, Zhang H and Zhu J-X, “A General Empirical Formula of Current-Voltage Characteristics for Point-to-Plane Geometry Corona Discharges”, Journal of Physics D: Applied Physics, 41(6),1-10, 065209, 2008.
340 Shah U, Zhang C and Zhu J-X, “Comparison of Electrostatic Fine Powder Coating and Coarse Powder Coating by Numerical Simulations”, J. Electrostatics, 64(6), 345-354, 2006.
341 Li Z-N, Zhang C, Zhu J-X, “Numerical Study of Air-Particle Two-Phase Flows inside a Powder Coating Booth”, International Journal for Computational Methods in Engineering Science and Mechanics. Mechanics, 7(3), 141-154, 2006.
342 Shah U, Zhu J-X, Zhang C and Nother Senior J H, “Numerical Investigation of Coarse Powder and Air Flow in an Electrostatic Powder Coating Process”, Powder Technol., 164(1), 22-32, 2006.
343 Li Z-N, Zhang C and Zhu J-X, “Numerical Study of the Effect of Particle Size on the Coating Efficiency and Uniformity of an Electrostatic Powder Coating Process”, Can. J. Chem. Eng, 83(5), 882-888, 2005.
344 Li Z-N, Zhu J-X and Zhang C, “Numerical Simulations of Ultrafine Powder Coating Systems”, Powder Technol., 150(3), 155-167, 2005.
345 Wang F-J, Martinuzzi R and Zhu J-X, “Experimental Study of Particle Trajectory in Electrostatics Powder Coating Process”, Powder Technol., 150(1), 20-29, 2005.
(N) Fine Powder Applications - Pharmaceutical Processes:
346 Zhu J-X, Luo Y, Ma Y and Zhang H, "Apparatus for Powder Coating of Solid Dosage Forms", U.S. Divisional Patent 8,161,904, April 24, 2012.
347 Zhu J-X, Wen J-Z, Ma Y and Zhang H, "Dry Powder Inhaler", U.S. Patent 8,037,880, October 18, 2011.
348 Zhu J-X, Wen J-Z, Ma Y and Zhang H, "Powder Inhaler Featuring Disc with Dosing Holes", Chinese Patent ZL2007-8001,2575.3, September 5, 2012.
349 Zhu J-X, Luo Y, Ma Y and Zhang H, "Direct Coating Solid Dosage Forms Using Powdered Materials", U.S. Patent 7,862,848, January 4, 2011.
350 Zhu J-X, Luo Y, Ma Y and Zhang H, "Direct Coating Solid Dosage Forms Using Powdered Materials", Chinese Patent ZL2006,8002,8559.9, Sept 28, 2011.
351 Zhu J-X, Luo Y, Ma Y and Zhang H, "Direct Coating Solid Dosage Forms Using Powdered Materials", Canadian Patent 2,617,190, granted, 2014.
352 Zhu J-X, Wen J-Z, Ma Y and Zhang H, "Apparatus for Volumetric Metering of Small Quantity of Powder from Fluidized Beds", U.S. Patent 6,684,917, February 3, 2004.
353 Zhu J-X, Wen J-Z, Ma Y and Zhang H, "Apparatus for Volumetric Metering of Small Quantity of Powder from Fluidized Beds", Chinese Patent ZL02-825,232.2, November 22, 2006.
354 Yang Q-L, Ma Y-L, Shi K-Q, Yang G-S and Zhu J-X, “Electrostatic Coated Controlled Porosity Osmotic Pump with Ultrafine Powders”, Powder Technol.
323, 71-77, June, 2018. (361) Doi:org/10.1016/j.powtec.2018. 04.009 (Yang QL5, Electrostatic Coating-PT) (WOS: 000433655400008; Impact Factor: 3.230; Citations: 1; JCR分区: 2)
355 Yang Q-L, Ma Y-L and Zhu J-X, “Dry Powder Coated Osmotic Drug Delivery System”, European J. of Pharma. Sci., 111, 383-392, 2018.
356 Hou N, Zhu J-X and Perinpanayagam H, “Human Mesenchymal Cell Attachment, Growth and Biomineralization on Calcium-enriched Titania-Polyester Coatings”, AIMS Cell and Tissue Eng., 1(2), 64-83, 2017.
357 Yang Q-L, Ma Y-L, Zhu J-X, Chow K and Shi K-Q, “An Update on Electrostatic Powder Coating for Pharmaceuticals”, Particuology, 31, 1-7, 2017.
358 Yang Q-L, Ma Y-L and Zhu J-X, “Sustained Drug Release from Electrostatic Powder Coated Tablets with Ultrafine Ethylcellulose Powders”, Advanced Powder Technol., 25(7), 2145-2152, 2016.
359 Hou N, Perinpanayagam H and Zhu J-X, “Epoxy Resin-Based Ultrafine Dry Powder Coatings for Implants”, J. of Appl. Polym. Sci., 133(37), 1-9, 2016.
360 Yang Q-L Ma Y-L and Zhu J-X, “Applying a Novel Electrostatic Dry Powder Coating Technology to Pellets”, Eur. J Pharm. Biopharm., 97, 118-124, 2015.
361 Hou N, Perinpanayagam H, Mozumder MS and Zhu J-X, “Novel Development of Biocompatible Coatings for Bone Implants”, Coatings, 5(4), 737-757, 2015.
362 Qiao M-X, Zhang L, Ma Y-L, Zhu J-X and Xiao W, “A Novel Electrostatic Dry Coating Process for Enteric Coating of Tablets with Eudragit(®) L100-55”, Eur. J Pharm. Biopharm., 83(2), 293-300, 2013.
363 Zhang X, Ma Y-L, Zhang L-Q, Zhu J-X and Jin F, “The Development of a Novel Dry Powder Inhaler”, Inter. J. of Pharma., 431(1-2), 45-52, July, 2012.
364 Qiao M-X, Zhang L-Q, Ma Y-L, Zhu J-Z and Chow K, “A Novel Electrostatic Dry Powder Coating Process for Pharmaceutical Dosage forms: Immediate Release Coatings for Tablets”, Eur. J Pharm. Biopharm., 76(2), 304-310, 2010.
365 Qiao M-X, Luo Y-F, Zhang L-Q, Ma Y-L, Stephenson TS, Zhu J-X, “Sustained Release Coating of Tablets with Eudragit RS/RL Using a Novel Electrostatic Dry Powder Coating Process” Inter. J. of Pharma, 399(1-2), 37-43, 2010.
366 Luo Y-F, Zhu J-X, Ma Y-L and Zhang H, “Dry Coating, a Novel Coating Technology for Solid Pharmaceutical Dosage Forms”, Int. J. of Pharmaceutics, 358(1-2), 16-22, 2008.
367 Liang H, Li Y, Zhang C and Zhu J-X, “Air Flow and Solid Particle Deposition Patterns in a Lung Airway Model”, Int. J. of Transport Phenomena, 10(4), 261-276, 2008.
368 Daniher D I and Zhu J-X, “Dry Powder Platform for Pulmonary Drug Delivery”, Particuology, 6(4), 225-238, 2008.
(O) Biomass Gasification and Utilization:
369 Shao Y-Y, Meng D, Xu C-B, Preto F and Zhu J-X, “Ash Deposition in Air-Blown Gasification of Peat and Woody Biomass in a Fluidized-Bed Gasifier”, Energy & Fuels, 32(6), 6788-6796, 2018.
370 Wang T-J, Chang J, Lv P-M and Zhu J-X, “A New Method for the Production of Syngas through Catalytic Reforming from Methane Gas”, Chinese Patent, ZL03-126,935.4, February 9, 2005.
371 Miao Q, Zhu J-X, Barghi S, Wu C-Z, Yin X-L and Zhou Z-Q, “Model Validation of a CFB Biomass Gasification Model”, Renewable Energy, 63, 317-323, 2013.
372 Miao Q, Zhu J-X, Barghi S, Wu C-Z, Yin X-L and Zhou Z-Q, “Modeling Biomass Gasification in Circulating Fluidized Beds: Model Sensitivity Analysis”, Inter. J. Energy & Power, 2(3), 57-63, 2013.
373 Miao Q, Zhu J-X, Barghi S, Wu C-Z, Yin X-L and Zhou Z-Q “Modeling Biomass Gasification in Circulating Fluidized Beds Renewable Energy”, Renewable Energy, 50, 655-661, 2013.
374 Shao Y-Y, Wang J-S, Preto F, Zhu J-X and Xu C-B, “Ash Deposition in Biomass Combustion or Co-Firing for Power/Heat Generation”, Energies, 5(12), 5171-5189, December, 2012.
375 Miao Q, Zhu J-X, Barghi S, Wu C-Z, Yin X-L and Zhou Z-Q, “A Hydrodynamic Model of a Circulating Fluidized Bed with Low-Density Particle”, Canadian J. Chem. Eng., 90(4), 1027-1032, August, 2012.
376 Shao Y-Y, Xu C-B, Zhu J-X, Preto F, Wang J-S, Tourigny G, Badour C and Li H, “Ash and Chlorine Deposition during Co-Combustion of Lignite and a Chlorine-Rich Canadian Peat in a Fluidized Bed - Effects of Blending Ratio, Moisture Content and Sulfur Addition”, Fuel, 95, 25-34, 2012.
377 Xie J-J, Su D, Yin X-L, Wu C-Z and Zhu J-X, “Thermodynamic Analysis of Aqueous Phase Reforming of Three Model Compounds in Bio-Oil for Hydrogen Production”, Fuel and Energy, 36(24), 15561-15572, 2011.
378 Shao Y-Y, Xu C-B, Zhu J-X, Preto F, Wang J-S, Li H-N and Badour C, “Ash Deposition in Co-Firing Three-Fuel Blends Consisting of Woody Biomass, Peat and Lignite in a Pilot-Scale Fluidized-Bed Reactor”, Energy & Fuels, 25(7), 2841-2849, 2011.
379 Shao Y-Y, Wang J-S, Xu C-B, Zhu J-X, Preto F, Tourigny G, Badour C and Li H-N, “An Experimental and Modeling Study of Ash Deposition Behaviour for Co-Firing Peat with Lignite”, Applied Energy, 88(8), 2635-2640, 2011.
380 Miao Q, Wang C, Wu C-Z, Yin X-L and Zhu J-X, “Fluidization of Sawdust in a Cold Model Circulating Fluidized Bed: Experimental Study”, Chem. Eng. J., 167(1), 335-341, 2011.
381 Shao Y-Y, Xu C-B, Zhu J-X, Preto F, Wang J-S, Tourigny G, Badour C, Li H-N, “Ash Deposition during Co-firing Biomass and Coal in a Fluidized-Bed Combustor”, Energy & Fuels, 24(9), 4681-4688, 2010.
382 Wang T-J, Chang J, Lv P-M and Zhu J-X, “Novel Catalyst for Cracking of Biomass Tar”, Energy & Fuel, 19(1), 22-27, 2005.
383 Wang T-J, Chang J, Lv P-M and Zhu J-X, “Dimethyl Ether Synthesis From Syngas Derived From Biomass Gasification and Reforming”, J. Fuel. Chem. Tech., 32(3), 297-300, 2004.
384 Wang T-J, Chang J, Lv P-M, Zhu J-X, “Single-Step Synthesis of DME from Biomass”, Coal Conversion, 26(4), 21-25, 2003.
385 Wang T-J, Chang J and Zhu J-X, “Synthesis of Dimethel Ether from Biomass”. Chem. Ind. Eng. Progress, 22(11), 1156-1159, 2003.
386 Lv P-M, Chang J, Xiong Z, Huang H, Wu C-Z, Chen Y and Zhu J-X, “Biomass Air-Steam Gasification in a Fluidized Bed to Produce Hydrogen-Rich Gas”, Energy & Fuels, 17(3), 677-682, 2003.
387 Lv P-M, Chang J, Fu Y, Wang T-J, Chen Y and Zhu J-X, “An Experimental Investigation of Hydrogen Production from Biomass”. Chinese J. Process Eng., 3(5), 464-470, 2003.
388 Lv P-M, Chang J, Wang T-J, Fu Y, Chen Y and Zhu J-X, “Hydrogen-Rich Gas Production from Biomass Catalytic Gasification”, Energy & Fuels, 18(1), 228-233, 2004.
389 Lv P-M, Xiong Z, Chang J, Wu C-Z, Chen Y and Zhu J-X, “An Experimental Study on Biomass Air-Steam Gasification in a Fluidized Bed”, Bioresource Technol., 95(1), 95-101, 2004.
390 Lv P-M, Chang J, Fu Y, Wang T-J, Wu C-Z, Chen Y and Zhu J-X, “Studies on the Production of Hydrogen-Rich Gas from Catalytic Biomass Gasification in a Liquid Bed”, J Solar Energy., 25(6), 769-775, 2004.
391 Lv P-M, Yuan Z-H, Ma L-L, Wu C-Z, Chen Y and Zhu J-X, “Hydrogen-Rich Gas Production from Biomass Air and Oxygen/Steam Gasification in a Downdraft Gasifier”, Renewable Energy, 32(4), 2173-2185, 2007.
(P) Other Miscellaneous papers:
392 Luo J-W, Xu C-J, Zhang Y-W, Yan K-X and Zhu J-X, “A Steady-State Analysis Method for Optimal Operation of Dividing-Wall Column”, Computers & Chem. Eng., 119, 112-127, 2018.
393 Hu M, Li R, Zhang X-C, Zhang C-M, Zhang H, Fan C-M and Zhu J-X, “HCl Post-Processing BiOBr Photocatalyst: Structure, Morphology, and Composition and their Impacts to Activity”, RSC Advances, 79, 50079-50086, 2017.
394 Mohammad L, Gomaa HG, Ragab D and Zhu J-X, “Magnetic Nanoparticles for Environmental and Biomedical Applications - A Review”, Particuology, 30, 1-14, 2017.
395 Sabouni R, Gomaa HG, Liu J-S and Zhu J-X, “Emulsification Characteristics Using Dynamic Woven Metal Microscreen Membrane”, Membranes, 6(34), 1-12, 2016.
396 Gomaa HG, Liu J-S, Sabouni R and Zhu J-X, “Experimental and Theoretical Analysis of Emulsification Characteristics Using a High Porosity Microscreen under Oscillatory Shear Conditions”, Colloids and Surfaces A: Physicochemical and Eng. Aspects, 456, 160-168, 2014.
397 Gilmour CR, Ray A, Zhu J-X and Ray M, “Photocatalytic Performance of Titanium Dioxide Thin Films from Polymer Encapsulated Titania”, Ind. & Eng. Chem. Res., 52(50), 17800-17811, 2013.
398 Zeng W, Gomaa H G, Liu J and Zhu J-X, “Intensification of Production of O/W Emulsions Using Oscillatory Woven Metal Micro-Screen (WMMS)”, Chem. Eng. and Processing, 73, 111-118, 2013.
399 Isimjan T T, He Q, Liu Y, Zhu J-X and Puddephatt R J, “Nanocomposite Catalyst with Palladium Nanoparticles Encapsulated in a Polymeric Acid: A Mode for Tandem Environmental Catalysis”, Sustainable Chem. & Eng., 1(4), 381-388, 2013.
400 Akhter K F, Zhu J-X and Zhang J, “Nanoencapsulation of Protein Drug for Controlled Release”, J. of Phy. Chem. & Biophy., 11(1), 1-5, 2012.
401 Saremirad P, Gomaa H G and Zhu J-X, “Effect of Flow Oscillations on Mass Transfer in Electrodialysis with Bipolar Membrane”, J. of Mem. Sci., 405-406(1), 158-166, 2012.
402 He Q, Rohani S, Zhu J-X and Gomaa H, “Resolution of Sertraline with (R)-Mandelic Acid: Chiral Discrimination Mechanism Study”, Chirality, 24(2), 119-128, 2012.
403 He Q, Rohani S, Zhu J-X and Gomaa H, “Crystallization of Racemic Compound and Conglomerate of (RS)-2-Chloromandelic Acid”. Crystal Growth & Design, 10(12), 5136-5145, 2010.
404 He Q, Gomaa H, Rohani S, Zhu J-X and Jennings M, “Chiral Discrimination of Diastereomeric Salts of Chlorine-Substituted Mandelic Acid and Phenylethylamine”, Chirality, 22(8), 707-716, 2010.
405 He Q, Rohani S, Zhu J-X and Gomaa H, “Sertraline Racemate and Enantiomer: Solid-State Characterization, Binary Phase Diagram, and Crystal Structures” Crystal Growth & Design, 10(4), 1633-1645, 2010.
406 He Q, Zhu J-X, Gomaa H, Jennings M and Rohani S, “Identification and Characterization of Solid-State Nature of 2-Chloromandelic Acid”, J. of Pharmaceutical Sciences, 98(5), 1835-1844, 2009.
407 He Q, Jennings MC, Rohani S, Zhu J-X and Gomaa H, “((R)-1-Phenylethanaminium (S)-4-chloromandelate”, Acta. Crystallographica, 64(3), o559-o559, 2008.
408 He Q, Jennings MC, Rohani S, Zhu J and Gomaa H, “(Phenylethylammonium (R)-4-chloromandelate”, Acta. Crystallographica, 63(11), o4199, 2007.
409 Rowe G E, Margaritis A, Lan Q-D, Bassi A S and Zhu J-X, “A New Kinetic Model of Protein Adsorption on Suspended Anion-Exchange Resin Particles”, Biotechnol. Bioeng., 65(6), 613-621, 1999.
410 Connell H A, Zhu J-X and Bassi A S, “Effect of Particle Shape on Crossflow Filtration Flux”, J. Membrane Sci., 153(1), 121-139, 1999.
411 Bassi A S, Lee E S B and Zhu J-X, “Carbon Paste Mediated, Amperometric, Thin Film Biosensors for Fructose Monitoring in Honey”, Food Research Int., 31(2), 119-127, 1998.
412 Bassi A S, Tang D, Lee E S B, Zhu J-X and Bergougnou M A, “Biosensors in Environmental and Bioprocess Monitoring and Control”, Food Technol. Biotech. 34(1), 9-22, 1996.
Books and Book Chapters: (Career total 14)
413 Brereton C, Grace J R, Lim C J and Zhu J-X, “Engineering Aspects of Recirculating Fluidized Bed Combustion”, in Chemical Reactor Technology for Environmentally Safe Reactors and Products, ed. HI de Lasa, Kluwer Academic Publ., Boston, 507-536, 1993.
414 Jin Y, Zhu J-X and Yu Z-Q “Novel Configurations and Variants”, Chapter 16 in Circulating Fluidized Beds, eds. JR Grace, AA Avidan and TM Knowlton, Blackie Academic & Professional (Chapman & Hall), London, 525-566, 1997.
415 Jin Y, Zhu J-X (executive editor), Wang Z-W and Yu Z-Q, Fluidization Engineering Principles, Tsinghua University Press, Beijing, 2001.
416 Zhu J-X and Zhang H, “Fundamentals of Fluidization and Classification of Flow Regimes”, Chapter 2, ibid.
417 Wei F, Zhu J-X, Qi C-M and Jin Y, “Gas-Solid Cocurrent Downward Fluidization”, Chapter 5, ibid.
418 Zhu J-X, Ma Y-L and Luan W-Q, “Heat Transfer in Gas-Solid Fluidized Beds”, Chapter 6, ibid.
419 Zhu J-X and Hong J, “Spouted Beds”, Chapter 8, ibid.
420 Wang Z-W, Zhou J-H and Zhu J-X, “Experimental Equipment, Measurement Techniques and Instrumentation of Fluidized Beds”, Chapter 10, ibid.
421 Zheng Y and Zhu J-X, “Liquid-Solid Particulate Fluidization and Gas-Liquid-Solid Three-Phase Fluidization”, Chapter, ibid.
422 Grace JR, Zhu J-X and de Lasa HI, Editors, Circulating Fluidized Bed Technology VII - Proceedings of the 7th Int. Conf . on Circulating Fluidized Beds, Can. Society of Chemical Engineering, Ottawa, May 2002.
423 Zhu J-X “Fluidization of Fine Powders”, Chapter 10 in Advances in Granular Materials: Fundamentals and Applications, eds. S. J. Antony, W. Hoyle and Y. Ding, Royal Society of Chemistry, London, 2003, pp 270-295.
424 Zhu J-X and Cheng Yi, “Fluidized-Bed Reactors and Applications”, Chapter 5.3 in Multiphase Flow Handbook, ed. Clayton Crowe, CRC Press, New York, 2005, pp 5.55-5.93.
425 Andalib M, Eldayasti A, Nakhla and G, Zhu J, “Denitrification: Processes, Regulations and Ecological Significance”, Chapter 5.3 in Denitrification: Processes, Regulations and Ecological Significance, ed. Nicolo Savaglio, Nova Science Publishers, Inc., Hauppauge, NY, 2011,
426 Zhu J-X and Cheng Y, “Applications of Fluidized Bed Reactors”, Chapter 17.3 in Multiphase Flow Handbook, ed. Efstathios E. Michaelides, Clayton T. Crowe and John D. Schwarzkopf, CRC Press, New York, 2017, pp1029-1058.
427 Zhu J-X and Xu Jing, “How to Write Good Scientific Research Papers in English”, Science and Tehcnology Press, Beijing, 2019 (120 pages). to be published.