Details Details PDF BIBTEX RIS Title Influence of coarse-dispersive solid phase on the ‘particles-wall’ shear stress in turbulent slurry flow with high solid concentration Journal title Archive of Mechanical Engineering Yearbook 2010 Volume vol. 57 Issue No 1 Authors Bartosik, Artur Keywords turbulent slurry flow ; particles-wall shear stress Divisions of PAS Nauki Techniczne Coverage 45-68 Publisher Polish Academy of Sciences, Committee on Machine Building Date 2010.09.14 Type Artykuły / Articles Identifier DOI: 10.2478/v10180-010-0003-1 ; ISSN 0004-0738, e-ISSN 2300-1895 Source Archive of Mechanical Engineering; 2010; vol. 57; No 1; 45-68 References Wilson K. (2006), Slurry transport using centrifugal pumps. ; Shook C. (1991), Slurry Flow: Principles and practice. ; Bartosik A. (2008), Laminarisation effect in fine-dispersive slurry flow, Archives of Thermodynamics, 29, 3, 69. ; Bartosik A. (2009), Application of rheological models in prediction of turbulent slurry flow, Flow, Turbulence and Combustion, Springer-Verlag, 84, 2, 277. ; Doron P. (1996), Flow pattern maps for solid liquid flow in pipes, Int. J. Multiphase Flow, 22, 273. ; Televantos Y. (1979), Flow of slurries of coarse particles at high solid concentration, Can. J. Chem. Eng, 57, 255. ; Wasp E. (1999), Solid-liquid flow slurry pipeline transportation. ; Gillies R. (1991), An improved two-layer model for horizontal slurry pipeline flow, Can. J. Chemical Engng, 69, 173. ; Gillies R. (2004), Modelling heterogeneous slurry flows at high velocities, Can. J. Chemical Engng, 82, 5, 1060. ; Bartosik A. (1996), Modelling the Bagnold stress effects in vertical slurry flow, J. Hydrology and Hydromechanics, 44, 1, 48. ; Bartosik A. (1997), Modification of k-ε model for slurry flow with the yield stress, Proc, null, 10, 265. ; Mishra R. (1998), Improved model for the prediction of pressure drop and velocity field in multi-sized particulate slurry flow through horizontal pipes, Powder Handling Processing, 10, 3, 279. ; Wilson K. (2006), Analytic model of laminar-turbulent transition for Bingham plastics, Canadian J. Chem. Eng, 84, 5, 520. ; Talmon A. (2008), Boundary layer theory for solid-liquid mixtures tested against Couette flow, null, 293. ; Bagnold R. (1954), Experiments on a gravity-free dispersion of large solids spheres in a Newtonian fluid under shear, Proc. Roy. Soc, 225, 49. ; Nasr-El-Din H. (1987), A conductivity probe for measuring local concentrations in slurry systems, Int. J. Multiphase Flow, 13, 365. ; Sumner R. (1991), Concentration and velocity distribution in turbulent vertical slurry flow, J. Solid Liquid Flow, 2, 2, 33. ; Eskin D. (2008), A model of non-Newtonian slurry flow in a fracture, Powder Technology, 182, 313. ; Kuboi R. (1974), Fluid and particle motion in turbulent dispersion-II - influence of turbulence of liquid on the motion of suspended particles, Chem. Eng. Sci, 29, 651. ; Schreck S. (1993), Modification of grid-generated turbulence by solid particles, J, Fluid Mech, 249, 665. ; Nouri J. (1992), Particle velocity characteristics of dilute to moderately dense suspension flows in stirred reactors, Int. J. Multiphase Flow, 18, 1, 21. ; Chen R. (1995), Discrimination between solid and liquid velocities in slurry flow using Doppler Velocimeter, ASME, Powder Technology, 85, 127. ; Gore R. (1991), Modulation of turbulence by a dispersed phase, ASM, J. Fluid Engng, 113, 304. ; Fessler J. (1999), Turbulence modification by particles in a backward-facing step flow, J. Fluid Mech, 394, 97. ; Sundaresan S. (2003), Appendix 2: Report of study group on disperse flow, Int. J. Multiphase Flow, 29, 1069. ; Shook C. (1994), Particle-wall stresses in vertical slurry flows, Powder Technology, Elsevier Science, 81, 117, doi.org/10.1016/0032-5910(94)02877-X ; Longwell P. (1966), Mechanics of fluid flow. ; Matousek V. (2002), Pressure drop and flow patterns in sand-mixture pipes, Experimental, Thermal and Fluid Science, 26, 693. ; Bartosik A. (2009), Badania symulacyjne i eksperymentalne osiowo-symetrycznego przepływu drobno- i grubodyspersyjnej hydromieszaniny w przewodach tłocznych.