Abstract
Bentonite clay is a vital ingredient of drilling mud. The time-dependent and high shear thinning yield stress behaviour of drilling mud is essential for maintaining wellbore stability and to remove cuttings, cool and clean the drill bit of debris. As-prepared 3, 5 and 7 wt.% bentonite clay slurries displayed time-dependent behaviour where the yield stress (measured after quick stirring) decreased with time of rest. An equilibrium value is reached after 24 h. Despite the low solids concentration, the yield stress is already relatively high and is displayed at all pH level. The yield stress is maximum at pH 2 and minimum at pH ∼ 7. This yield stress is due to the formation of gel structure by the swelling clay particles. However the addition of phosphate additives such as (PO3)19 − , (P3O10)5 − and (P2O7)4 − completely dispersed the clay slurries at pH above 6. At pH below 6, yield stress is still present but is 3-folds smaller than that of the pure bentonite slurry. With phosphate additives, the magnitude of the critical zeta potential at the complete dispersion pH is ca 48 mV. However for the pure bentonite, the slurry remained flocculated at zeta potential of >50 mV in magnitude. Interestingly, (P2O7)4 − anions is more effective than the other two phosphate additives in reducing the yield stress at low pH, ∼ 2.0.
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The authors wish to acknowledge the support of UWA via a USF grant for the purchase of the ZetaProbe. We wish to thank the referees for the helpful comments in making this a better paper.
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Goh, R., Leong, YK. & Lehane, B. Bentonite slurries—zeta potential, yield stress, adsorbed additive and time-dependent behaviour. Rheol Acta 50, 29–38 (2011). https://doi.org/10.1007/s00397-010-0498-x
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DOI: https://doi.org/10.1007/s00397-010-0498-x