Rheological properties of water based slurry under turbulent flow condition
- 1Mechanical Engineering Department, National Institute of Technology, Raipur, 492010, C.G, India
- 2Mechanical Engineering Department, National Institute of Technology, Raipur, 492010, C.G, India
- 3Mechanical Engineering Department, National Institute of Technology, Raipur, 492010, C.G, India
Res. J. Engineering Sci., Volume 6, Issue (3), Pages 16-22, March,26 (2017)
In previous researches the testing of additives had been performed under laminar flow conditions where as in this paper, results are taken under turbulence flow condition. So the results that are getting from this research may be varying from other that had been performed under laminar flow condition. This paper presents the effect of different additives on rheological properties of water- bentonite slurry by studying the rheological behaviour of additives. This work present the results to relate the turbulent flow condition of any fluid flow. In the present investigation, 19 different samples have been prepared by varying concentration of additives. The variation of shear stress and shear rate has been plotted and on the basis of this behaviour of fluids has been explained. The value of k and n are calculated by using Power law.
- Abdou M.I., Al-sabagh A.M. and Dardir M.M. (2013)., Evaluation of Egyptian bentonite and nano-bentonite as drilling mud., Egyptian Journal of Petroleum, 22(1), 53-59.
- Vipulanandan C. and Mohammed A.S. (2014)., Hyperbolic rheological model with shear stress limit for acrylamide polymer modified bentonite drilling muds., Petroleum Science and Engineering, 122, 38-47.
- Kok M.V. (2004)., Determination of rheological models for drilling fluids (a statistical approach)., Energy Sources, 26(2), 153-165.
- Vipulanandan C. and Mohammed A. (2015)., Effect of nano-clay on the electrical resistivity and rheological properties of smart and sensing bentonite drilling muds., Journal of Petroleum Science and Engineering, 130, 86-95.
- National Iranian Oil Company (2002)., Drilling formation., Department of drilling chemistry, Ahwaz, Iran.
- Yan J.N. (2006)., Drilling Fluid Technology., 1st ed., China University of petroleum Press: Shandong, China.
- Mahto V. and Sharma V.P. (2004)., Rheological study of a water based oil well drilling fluid., Journal of Petroleum Science and Engineering, 45(1), 123-128.
- Garcıa-Ochoa F., Santos V.E., Casas J.A. and Gomez E. (2000)., Xanthan gum: production, recovery, and properties., Biotechnology Advances, 18(7), 549-579.
- Benchabane A. and Bekkour K. (2008)., Rheological properties of carboxy-methyl cellulose (CMC) solutions., Colloid and Polymer Science, 286(10), 1173-1180.
- Vermolen Esther, Haasterecht Menno J.T. Van, Masalmeh Shehadeh K., Faber Marinus J., Boersma Diederik Michiel and Gruenenfelder Marc A. (2011)., Pushing the envelope for polymer flooding towards high-temperature and high-salinity reservoirs with polyacrylamide based terpolymers., Society of Petroleum Engineering 141497. Kok M.V., and Alikaya T., (2005). Effect of Polymers on the Rheological Properties of KCl/Polymer Type Drilling Fluids, Energy Sources, 27:5, 405-415.
- Chilingarian G.V. and Vorabutr P. (1983)., Drilling and drilling fluids., Elsevier, Amsterdam, Netherlands, 50(133), 149-151.
- Darley H.C.H. and Gray George R. (1988)., Composition and properties of drilling and completion fluids., fifth edition. Gulf Professional Publishing, Texas. ISBN: 0-87201-147-X.