1. bookVolume 65 (2017): Edition 2 (June 2017)
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Flow behaviour and local concentration of coarse particles-water mixture in inclined pipes

Publié en ligne: 20 Mar 2017
Volume & Edition: Volume 65 (2017) - Edition 2 (June 2017)
Pages: 183 - 191
Reçu: 09 Aug 2016
Accepté: 26 Sep 2016
Détails du magazine
License
Format
Magazine
eISSN
1338-4333
Première parution
28 Mar 2009
Périodicité
4 fois par an
Langues
Anglais

Campbell, C.S., Francisco, A.S., Liu, Z., 2004. Preliminary observations of a particle lift force in horizontal slurry flow. Int. J. Multiphase Flow, 30, 199–216.10.1016/j.ijmultiphaseflow.2003.10.008Search in Google Scholar

Doron, P., Barnea, D., 1993. A three layer model for solid-liquid flow in horizontal pipes. Int. J. Multiphase Flow, 19, 6, 1029–1043.10.1016/0301-9322(93)90076-7Search in Google Scholar

Doron, P., Barnea, D., 1996. Flow pattern maps for solid-liquid flow in pipes. Int. J. Multiphase Flow, 22, 2, 273–283.10.1016/0301-9322(95)00071-2Search in Google Scholar

Durand, R., 1953. Concentration measuring instrument for hydraulic transportation installation. La Houille Blanche, 8, 2, 296–297.Search in Google Scholar

Gilies, R.G., Shook, C.A., Wilson, K.C, 1991. An improved two layer model for horizontal slurry flow. Can. J. Chemical Engineering, 69, 173–178.10.1002/cjce.5450690120Search in Google Scholar

Kao, D.T.Y., Hwang, L.Y., 1979. Critical slope for slurry pipeline transporting coal and other solid particles. In: Burns, A.P. (Ed.): Proc. 6th Int. Conf. on the Hydraulic Transport of Solids in Pipes - HYDROTRANSPORT, Canterbury (U.K.), BHRA Fluid Engineering Centre, Cranfield (U.K.), Vol. 1, Pap. A5, pp. 57–74.Search in Google Scholar

Kaushal, D.R., Tomita, Y., 2013. Prediction of concentration distribution in pipeline flow of highly concentrated slurry. Particulate Science and Technology, 31, 28–34.10.1080/02726351.2011.639045Search in Google Scholar

Kaushal, D.R., Sato, K., Toyota, T., Funatsu, K., Tomita, Y., 2005. Effect of particle size distribution on pressure drop and concentration profile in pipeline flow of highly concentrated slurry. Int. J. Multiphase Flow, 31, 809–823.10.1016/j.ijmultiphaseflow.2005.03.003Search in Google Scholar

Krupicka, J., Matousek, V., 2012. Gamma-ray-based method for density sensing in pipes - evaluation of measurement and data processing. In: Proc. 2nd IAHR Europe Congr., Munich (Germany), 27–30 June 2012.Search in Google Scholar

Krupicka, J., Matousek, V., 2014. Gamma-ray-based measurement of concentration distribution in pipe flow of settling slurry: vertical profiles and tomographic maps. J. Hydrol. Hydromech., 62, 2, 126–132.10.2478/johh-2014-0012Search in Google Scholar

Lukerchenko, N., Chara, Z., Vlasak, P., 2006. 2D numerical model of particle-bed collision in fluid-particle flows over bed. J. Hydraulic Research, 44, 1, 70–78.10.1080/00221686.2006.9521662Search in Google Scholar

Lukerchenko, N., Piatsevich, S., Chara, Z., Vlasak, P., 2009. 3D numerical model of a spherical particle saltation in channel with rough fixed bed. J. Hydrol. Hydromech., 57, 2, 100–112.10.2478/v10098-009-0009-xSearch in Google Scholar

Maciejewski, W., Oxenford, J., Shook, C. A., 1993. Transport of coarse rock with sand and clay slurries. In: Proc. 12th Int. Conf. on Slurry Handling and Pipeline Transport - HYDROTRANSPORT 12. BHR Group, Brugge (Belgium), pp. 705–724.Search in Google Scholar

Matousek, V., 2009. Concentration profiles and solids transport above stationary deposit in enclosed conduit. J. Hydraulic Engineering ASCE, 135, 12, 1101–1106.10.1061/(ASCE)HY.1943-7900.0000113Search in Google Scholar

Matousek, V., Vlasak, P., Chara, Z., Konfrst, J., 2015. Experimental study of hydraulic transport of coarse-basalt. Maritime Engineering, 168, 93–100.10.1680/maen.14.00023Search in Google Scholar

Newitt, D.M., Richardson, J.F., Abbott, M., Turtle, R.B., 1955. Hydraulic conveying of solids in horizontal pipes. Transactions Institute Chemical Engineers, 33, 2, 93–113.Search in Google Scholar

Petryka, L., Zych, M., Murzyn, R., 2005. The non-stationary two-phase flow evaluation by radioisotopes. Nukleonika, 50, 43–46.Search in Google Scholar

Pullum, L., Graham, L.J. W., Slatter, P., 2004. A non-Newtonian two-layer model and its application to high density hydrotransport. In: N. Heywood (Ed.): Proc. 16th Int. Conf. on Hydrotransport, 26–28 April 2004, Vol. II. BHR Group, Santiago de Chile, pp. 579–594.Search in Google Scholar

Przewlocki, K., Michalik, A., Wolski, K., Korbel, K., 1979. A radiometric device for the determination of solids concentration distribution in a pipeline. In: Burns, A.P. (Ed.): Proc. 6th Int. Conf. on the Hydraulic Transport of Solids in Pipes - HYDROTRANSPORT 6, Canterbury (UK), BHRA Fluid Engineering Centre, Cranfield (U.K.), Pap. B3, pp. 219–227.Search in Google Scholar

Shook, C.A., Roco, M.C., 1991. Slurry Flow: Principles and Practice. 1st Ed. Butterworth/Heinemann, Boston 1991.10.1016/B978-0-7506-9110-9.50006-2Search in Google Scholar

Shook, C.A., Geller, L., Gillies, R.G., Husband, W.H.W., Small, M., 1986. Experiments with coarse particles in a 250 mm pipeline. In: Burns, A.P. (Ed.): Proc. 10th Int. Conf. on the Hydraulic Transport of Solids in Pipes - HYDROTRANSPORT 10, Innsbruck (Austria). BHRA Fluid Engineering Centre, Cranfield (U.K.), pp. 219–227.Search in Google Scholar

Sobota, J., Vlasak, P., Strozik, G., Plewa, F., 2009. Vertical distribution of concentration in horizontal pipeline – density and particle size influence. In: Proc. 8th ISOPE Ocean Mining (& Gas Hydrates) Symposium, Chennai (India), 20–24 September 2009, pp. 220–224.Search in Google Scholar

Sumner, R.J., McKibben, M., Shook, C.A., 1990. Concentration and velocity distribution in turbulent vertical slurry flow. J. Solid Liquid Flow, 2, 2, 33–42.Search in Google Scholar

Thomas, A.D., Wilson, K.C., 1987. New analysis of non-Newtonian turbulent flow - Yield-power-law fluids. Can. J. Chemical Engineering, 65, 335–338.10.1002/cjce.5450650221Search in Google Scholar

Vlasak, P., Chara, Z., 2007. Effect of particle size and concentration on flow behavior of complex slurries. In: Proc. 7th ISOPE Ocean Mining Symp., Lisbon, pp. 188–196.Search in Google Scholar

Vlasak, P., Chara, Z., 2011. Effect of particle size distribution and concentration on flow behaveior of dense slurries. Particulate Science and Technology, 29, 1, 53–65.10.1080/02726351.2010.508509Search in Google Scholar

Vlasak, P., Chara, Z., Kysela B., Sobota, J., 2011. Flow behavior of coarse-grained slurries in pipes. In: Proc. 9th (2011) ISOPE (Deep) Ocean Mining (& Gas Hydrates) Symposium, 19–25 June 2011, Maui (Hawaii, USA), pp. 158–164.Search in Google Scholar

Vlasak, P., Kysela, B., Chara, Z., 2012. Flow Structure of coarse-grained slurry in horizontal pipe. J. Hydrol. Hydromech., 60, 2, 115–124.10.2478/v10098-012-0010-7Search in Google Scholar

Vlasak, P., Chara, Z., Konfrst, J., Kysela, B., 2013a. Experimental investigation of coarse-grained particles in pipes, In: Proc. 16th Int. Conf. on Transport & Sedimentation of Solid Particles, Rostock (Germany), 18–20 September 2013, pp. 265–273.Search in Google Scholar

Vlasak, P., Chara, Z., Konfrst, J., Sobota, J., Kysela, B., 2013b. Conveying of coarse-grained particles in pipes. In: Proc. 10th (2013) ISOPE Ocean Mining & Gas Hydrates Symposium, Szcezecin (Poland), 22–26 September 2013, pp. 215–220.Search in Google Scholar

Vlasak, P., Kysela, B., Chara, Z., 2014a. Fully stratified particle-laden flow in horizontal circular pipe, Particulate Science and Technology, 32, 2, 179–185.10.1080/02726351.2013.840705Search in Google Scholar

Vlasak, P., Chara, Z., Konfrst, J., Krupicka, J., 2014b. Experimental investigation of coarse particle conveying in pipes. EPJ Web of Conferences, Experimental Fluid Mechanics 2014, 18–21 November, Cesky Krumlov (Czech Rep.), pp. 712–719.Search in Google Scholar

Vlasak, P., Chara, Z., Krupicka, J., Konfrst, J., 2014c. Experimental investigation of coarse particles-water mixture flow in horizontal and inclined pipes. J. Hydrol. Hydromech., 62, 3, 241–247.10.2478/johh-2014-0022Search in Google Scholar

Vlasak, P., Chara, Z., Konfrst, J., 2015. Conveying of coarse particles in horizontal and inclined pipes. In: 17th Int.Conf. on Transport & Sedimentation of Solid Particles, Delft (the Netherlands), September 22–25, 2015, pp. 355–362.Search in Google Scholar

Vlasak, P., Chara, Z., Konfrst, J., Krupicka, J., 2016. Distribution of concentration of coarse particle-water mixture in horizontal smooth pipe. Canadian Journal of Chemical Engineering, 94, 1040–1047.10.1002/cjce.22484Search in Google Scholar

Wilson, K.C., 1976. A unified physically based analysis of solid-liquid pipeline flow, In: Proc. 4th Int. Conf. on the Hydraulic Transport of Solids in Pipes - HYDROTRANSPORT 4, B.H.R.A., Banff (Canada), 18–21 May 1976, Pap. A1.Search in Google Scholar

Wilson, K.C., Addie, G.R., 1997. Coarse-particle pipeline transport: effect of particle degradation on friction. Powder Technology, 94, 235–238.10.1016/S0032-5910(97)03300-7Search in Google Scholar

Wilson, K.C., Brown, N.P., Streat, M., 1979. Hydraulic hoisting at high concentration: A new study of friction mechanisms. In: Proc. 6th Int. Conf. on Hydraulic Transport of Solids in Pipes (HYDROTRANSPORT 6). Cranfield, Bedford (UK), BHRA Fluid Engineering, pp. 269–282.Search in Google Scholar

Wilson, K.C., Addie, G.R., Sellgren, A., Clift, R., 2006. Slurry Transport Using Centrifugal Pumps. 3rd Ed. Springer, New York, Philadelphia.Search in Google Scholar

Wilson, K.C., Sanders, R.S., Gillies, R.G., Shook, C.A., 2010. Verification of the near-wall model for slurry flow. Powder Technology, 197, 247–253.10.1016/j.powtec.2009.09.023Search in Google Scholar

Zych, M., Petryka, L., Kępinski, J., Hanus, R., Bujak, T., Puskarczyk, E. 2014. Radioisotope investigations of compound two-phase flows in an open channel flow. Measurement and Instrumentation, 35, 11–15.Search in Google Scholar

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