[Biswas, A., Gandhi, B.K., Singh, S.N., Seshadri, V., 2000. Characteristics of coal ash and their role in hydraulic design of ash disposal pipelines. Indian Journal of Engineering and Material Science, 7, 1–7.]Search in Google Scholar
[Chandel, S., Seshadri, V., Singh, S.N., 2009a. Effect of additive on pressure drop and rheological characteristics of fly ash slurry at high concentration. Particulate Science and Technology, 27, 3, 271–284.10.1080/02726350902922036]Search in Google Scholar
[Chandel, S., Singh, S.N., Seshadri, V., 2009b. Deposition characteristics of coal ash slurries at higher concentrations. Advanced Powder Technology, 20, 383–389.10.1016/j.apt.2009.06.004]Search in Google Scholar
[Chandel, S., Seshadri, V., Singh, S.N., 2010. Transportation of high concentration coal ash slurries through pipelines. Inter. Archive of Applied Science and Technology, 1, 1, 1–9.]Search in Google Scholar
[Chong, J.S., Christiansen, E.B., Baer, A.D., 1971. Rheology of concentrated suspensions. Journal of Applied Polymer Science, 15, 2007–2021.10.1002/app.1971.070150818]Search in Google Scholar
[Gahlot, V.K., Seshadri, V., Malhotra, R.C., 1988. A method for the experimental determination of the rheological parameters of multisized course particulate slurries. In: Inter. Symposium on Hydraulic Transportation of Coal and Other Minerals, IIT Delhi, March 4–6, pp. 283–295.]Search in Google Scholar
[Kolar, V., Pollert, J., Sellin, R.H.J., Vlasak, P., 1988. Experiment with drag reducing polymer in an ash-slag hydro transport pipeline. Journal of Hydraulic Research, 26, 2, 143–158.10.1080/00221688809499222]Search in Google Scholar
[Kunal, S., Kundan, L., 2012. Effect of Cetylpyridinium chloride, Triton x-100 and Sodium Dodecyl Sulphate on rheology of fly ash slurry. International Journal of Scientific and Research Publications, 2, 8, 1–5.]Search in Google Scholar
[Mosa, S., Abdel, H.M.S., Taha, A., Anas, M.E., 2008. Effect of chemical additives on flow characteristics of coal slurries. J. of Physicochemical Problems of Mineral Processing, 42, 107–118.]Search in Google Scholar
[Naik, H.K., Mishra, M.K., Rao Karanam, U.M., Deb, D., 2009a. Evaluation of the role of a cationic surfactant on the flow characteristics of fly ash slurry. Journal of Hazardous Materials, 169, 1134–1140.10.1016/j.jhazmat.2009.03.01619345482]Search in Google Scholar
[Naik, H.K., Mishra, M.K., Rao Karanam, U.M., 2009b. The effect of drag reducing additives on the rheological properties of fly ash-water suspensions at varying temperature environment. Coal Combustion and Gasification Products, 1, 25–31.10.4177/CCGP-D-09-00005.1]Search in Google Scholar
[Naik, H.K., Mishra, M.K., Rao, K.U.M., 2011. Influence of chemical reagents on rheological properties of fly ash – water slurry at varying temperature environment. Coal Combustion and Gasification Products, 3, 83–93.10.4177/CCGP-D-11-00015.1]Search in Google Scholar
[Panda, D., Pradhan, B., 2014. Hydraulic transport of fly ash and fly ash- bottom ash mixtures at high concentrations. International Journal of Chemical Engineering and Applied Sciences, 4, 1, 1–4.]Search in Google Scholar
[Senapati, P.K., Mishra, B.K., 2012. Design considerations for hydraulic backfilling with coal combustion products (CCPs) at high solids concentrations. Powder Technology, 229, 119–125.10.1016/j.powtec.2012.06.018]Search in Google Scholar
[Senapati, P.K., Mishra, B.K., Parida, A., 2010. Modeling of viscosity for power plant ash slurry at higher concentrations: Effect of solids volume fraction, particle size and hydrodynamic interactions. Powder Technology, 197, 1–8.10.1016/j.powtec.2009.07.005]Search in Google Scholar
[Senapati, P.K., Mishra, B.K., Parida, A., 2013. Analysis of friction mechanism and homogeneity of suspended load for high concentration fly ash & bottom ash mixture slurry using rheological and pipeline experimental data. Powder Technology, 250, 154–163.10.1016/j.powtec.2013.10.014]Search in Google Scholar
[Seshadri, V., Singh, S.N., Jain, K.K., Verma, A.K., 2005. Rheology of fly ash slurries at high concentrations and its application to the design of high concentration slurry disposal system (HCSD). In: Proceedings of the International Conference on Fly Ash Utilization, 1, 10.]Search in Google Scholar
[Umesh, K., Mishra, R., Singh, S.N., Seshadri, V., 2003. Effect of particle gradation on flow characteristics of ash disposal pipelines. Powder Technology, 132, 39–51.10.1016/S0032-5910(03)00045-7]Search in Google Scholar
[Verma, A.K., Singh, S.N., Seshadri, V., 2006. Pressure drop for the flow of high concentration solid liquid mixture 90° horizontal conventional circular pipe bends. Indian Journal of Engineering and Material Science, 13, 477–483.]Search in Google Scholar
[Vlasak, P., Chara, Z., 2004. Laminar and turbulent transition of fine-grained slurries. Particulate Science and Technology, 22, 2, 189–200.10.1080/02726350490457268]Search in Google Scholar
[Vlasak, P., Chara, Z., 2009. Conveying of solid particles in Newtonian and non-Newtonian carriers. Particulate Science and Technology, 27, 5, 428–443.10.1080/02726350903130019]Search in Google Scholar
[Vlasak, P., Chara, Z., 2011. Effect of particle size distribution and concentration on flow behaviour of dense slurries. Particulate Science and Technology, 29, 1, 53–65.10.1080/02726351.2010.508509]Search in Google Scholar
[Vlasak, P., Chara, Z., Stern, P., 2010. Drag reduction of dense Fine-Grained slurries. Journal of Hydrology and Hydromechanics, 58, 4, 261–270.10.2478/v10098-010-0024-y]Search in Google Scholar