References
- Azamathulla, H.M., Ahmad, Z., 2013. Estimation of critical velocity for slurry transport through pipeline using adaptive neuro-fuzzy interference system and gene-expression programming. Journal of Pipeline Systems Engineering and Practice, 131–137.
- Berg, C.H., 1998. Pipelines as transportation systems. In: Proceedings of the European Mining Course. IHC-MTI, Kinderdijk, the Netherlands.
- Charles, M.E., 1970. Transport of solids by pipeline. Hydrotransport 1. BHRA, Cranfield.
- Davies, J.T., 1987. Calculation of critical velocities to maintain solids in suspension in horizontal pipes. Chemical Engineering Science, 42, 7, 1667–1670.
- Durand, R., 1953. Basic Relationships of the Transportation of Solids in Pipes - Experimental Research. In: Proceedings of the International Association of Hydraulic Research. Minneapolis.
- Durand, R., Condolios, E., 1952. Etude experimentale du refoulement des materieaux en conduites en particulier des produits de dragage et des schlamms. [Experimental study of the discharge pipes materieaux especially products of dredging and slurries]. Deuxiemes Journees de l'Hydraulique, 27–55. (In French.)
- Fuhrboter, A., 1961. Über die Förderung von Sand-Wasser-Gemischen in Rohrleitungen. [On the advances of sand - water mixtures in pipelines]. Mitteilungen des Franzius-Instituts, H. 19.(In German.)
- Garcia, M.H., 2008. Sedimentation Engineering (Vol. 110). ASCE Manuals & Reports on Engineering Practise No. 110.
- Gibert, R., 1960. Transport hydraulique et refoulement des mixtures en conduites. [Hydraulic transport and discharge pipes of mixtures]. Annales des Ponts et Chausees, 130, 3, 307–374, 130, 4, 437–494. (In French.)
- Gillies, R.G., 1993. Pipeline flow of coarse particles, PhD Thesis. University of Saskatchewan, Saskatoon.
- Gogus, M., Kokpinar, M.A., 1993. Determination of critical flow velocity in slurry transporting pipeline systems. In: Proceeding of the 12th International Conference on Slurry Handling and Pipeline Transport. British Hydraulic Research Group, Bedfordshire, UK, pp. 743–757.
- Graf, W.H., Robinson, M., Yucel, O., 1970. The critical deposit velocity for solid-liquid mixtures. Hydrotransport 1. BHRA, Cranfield, UK, pp. H5-77–H5-88.
- Hepy, F.M., Ahmad, Z., Kansal, M.L., 2008. Critical velocity for slurry transport through pipeline. Dam Engineering, 19, 3, 169–184.
- Jufin, A.P., Lopatin, N.A., 1966. O projekte TUiN na gidrotransport zernistych materialov po stalnym truboprovodam. [TUiN project on hydrotransport of grain materials in steel tubes]. Gidrotechniceskoe Strojitelstvo, 9, 49–52. (In Russian.)
- Kokpinar, M.A., Gogus, M., 2001. Critical velocity in slurry transport in horizontal pipelines. Journal of Hydraulic Engineering, 127, 9, 763–771.
- Lahiri, S.K., 2009. Study on slurry flow modelling in pipeline. National Institute of Technology, Durgapur, India.
- Miedema, S.A., 2012a. Constructing the Shields Curve: Part A Fundamentals of the Sliding, Rolling and Lifting Mechanisms for the Entrainment of Particles. Journal of Dredging Engineering, 12., 1–49.
- Miedema, S.A., 2012b. Constructing the Shields Curve: Part B Sensitivity Analysis, Exposure & Protrusion Levels, Settling Velocity, Shear Stress & Friction Miedema, S.A., 2014 Velocity, Erosion Flux and Laminar Main Flow. Journal of Dredging Engineering, 12, 50–92.
- Miedema, S.A., 2014. An analytical approach to explain the Fuhrboter equation. Maritime Engineering, 167, 2, 1–14.
- Miedema, S.A., 2015a. A head loss model for homogeneous slurry transport. Journal of Hydrology and Hydromechanics, 1, 1–12.
- Miedema, S.A., 2015b. Head loss model for slurry transport in the heterogeneous regime. Journal of Ocean Engineering, 12., 50–92.
- Miedema, S.A., 2015c. The Slip Ratio or Holdup Function in Slurry Transport. Dredging Summit and Expo 2015. WEDA, Houston, Texas, USA, p. 12.
- Miedema, S.A., Matousek, V., 2014. An explicit formulation of bed friction factor for sheet flow. In: Proc. 15th International Freight Pipeline Society Symposium, IFPS, Prague, Czech Republic, p. 17.
- Miedema, S.A., Ramsdell, R.C., 2013. A head loss model for slurry transport based on energy considerations. In: Proc. XX World Dredging Conference, WODA, Brussels, Belgium, p. 14.
- Miedema, S.A., Ramsdell, R.C., 2014a. An analysis of the hydrostatic approach of wilson for the friction of a sliding bed. WEDA/TAMU. WEDA, Toronto, Canada, p. 21.
- Miedema, S.A., Ramsdell, R.C., 2014b. The Delft Head Loss & Limit Deposit Velocity Model. In: Hydrotransport, BHR Group, Denver, USA, p. 15.
- Newitt, D.M., Richardson, M.C., Abbott, M., Turtle, R.B., 1955. Hydraulic conveying of solids in horizontal pipes. Transactions of the Institution of Chemical Engineers, 33, 93–110.
- Oroskar, A.R., Turian, R.M., 1980. The hold up in pipeline flow of slurries. AIChE, 26, 550–558.
- Parzonka, W., Kenchington, J.M., Charles, M.E., 1981. Hydrotransport of solids in horizontal pipes: Effects of solids concentration and particle size on the deposit velocity. Canadian Journal of Chemical Engineering, 59, 291–296.
- Poloski, A.P., Etchells, A.W., Chun, J., Adkins, H.E., Casella, A.M., Minette, M.J., Yokuda, S., 2010. A pipeline transport correlation for slurries with small but dense particles. Canadian Journal of Chemical Engineering, 88, 182–189.
- Ramsdell, R.C., Miedema, S.A., 2013. An overview of flow regimes describing slurry transport. In: WODCON XX, WODA, Brussels, Belgium, p. 15.
- Sanders, R.S., Sun, R., Gillies, R.G., McKibben, M., Litzenberger, C., Shook, C.A., 2004. Deposition velocities for particles of intermediate size in turbulent flows. In: Hydrotransport 16, BHR Group, Santiago, Chile, pp. 429– 442.
- Schiller, R.E., Herbich, J.B., 1991. Sediment Transport in Pipes. Handbook of Dredging. McGraw-Hill, New York.
- Shook, C.A., Gillies, R.G., Sanders, R.S., 2002. Pipeline Hydrotransport with Application in the Oil Sand Industry. SRC Publication 11508-1E02, Saskatchewan Research Council, Saskatoon, Canada.
- Souza Pinto, T.C., Moraes Junior, D., Slatter, P.T., Leal Filho, L.S., 2014. Modelling the critical velocity for heterogeneous flow of mineral slurries. International Journal of Multiphase Flow, 65, 31–37.
- Thomas, A.D., 1979. Predicting the deposit velocity for horizontal turbulent pipe flow of slurries. International Journal of Multiphase Flow, 5, 113–129.
- Thomas, A.D., 2014. Slurries of most interest to the mining industry flow homogeneously and the deposit velocity is the key parameter. In: HydroTransport 19, BHR Group, Denver, Colorado, USA, pp. 239–252.
- Thomas, D.G., 1962. Transport characteristics of suspensions: Part VI. Minimum velocity for large particle size suspensions in round horizontal pipes. A.I.Ch.E. Journal, 8, 3, 373–378.
- Thomas, D.G., 1965. Transport characteristics of suspensions: VIII. A note on the viscosity of Newtonian suspensions of uniform spherical particles. Journal of Colloidal Sciences, 20, 267–277.
- Turian, R.M., Hsu, F. L., Ma, T.W., 1987. Estimation of the critical velocity in pipeline flow of slurries. Powder Technology, 51, 35–47.
- Wasp, E.J., Slatter, P.T., 2004. Deposition velocities for small particles in large pipes. In: Proc. 12th International Conference on Transport & Sedimentation of Solid Particles, Prague, Czech Republic, pp. 20–24.
- Wasp, E.J., Kenny, J.P., Aude, T.C., Seiter, R.H., Jacques, R.B., 1970. Deposition velocities transition velocities and spatial distribution of solids in slurry pipelines. In: Hydro Transport 1, paper H42, BHRA Fluid Engineering, Coventry, pp. 53–76.
- Wasp, E.J., Kenny, J.P., Gandhi, R.L., 1977. Solid liquid flow slurry pipeline transportation. Transactions Technical Publications.
- Wilson, K.C., 1979. Deposition limit nomograms for particles of various densities in pipeline flow. In: Hydrotransport 6, BHRA, Canterbury, UK, p. 12.
- Wilson, K.C., Judge, D.G., 1976. New techniques for the scale-up of pilot plant results to coal slurry pipelines. In: Proceedings International Symposium on Freight Pipelines, University of Pensylvania, Washington DC, USA, pp. 1–29.
- Wilson, K.C., Judge, D.G., 1977. Application of analytical model to stationary deposit limit in sand water slurries. In: Dredging Technology, BHRA Fluid Engineering, College Station, Texas, USA, pp. J1 1–12.
- Wilson, K.C., Addie, G.R., Clift, R., 1992. Slurry Transport using Centrifugal Pumps. Elsevier Applied Sciences, New York.
- Wilson, W.E., 1942. Mechanics of flow with non colloidal inert solids. Transactions ASCE, 107, 1576–1594.
- Yagi, T., Okude, T., Miyazaki, S., Koreishi, A., 1972. An Analysis of the Hydraulic Transport of Solids in Horizontal Pipes. Nagase, Yokosuka, Japan. Report of the Port & Harbour Research Institute, Vol. 11, No. 3.
- Zandi, I., Govatos, G., 1967. Heterogeneous flow of solids in pipelines. Proc. ACSE, J. Hydraul. Div., 93(HY3), 145–159.