SPE Drilling & Completion
Volume 26, Number 4, December 2011, pp. 499-505

SPE-141447-PA

Stabilizing Viscoelastic Surfactants in High-Density Brines

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DOI  More information 10.2118/141447-PA http://dx.doi.org/10.2118/141447-PA

Citation

  • van Zanten, R. 2011. Stabilizing Viscoelastic Surfactants in High-Density Brines. SPE Drill & Compl  26 (4): 499-505. SPE-141447-PA. http://dx.doi.org/10.2118/141447-PA.

Discipline Categories

  • 1.2.5 Materials Selection (Casing, Fluids, Cement)
  • 1.7 Fundamental Research in Drilling & Completions

Keywords

  • completion fluids, viscoelastic surfactant, brine

Summary

Viscoelastic-surfactant (VES) systems are the preferred gelling and viscosity-generating agents for fluids used in the production zone because of their nondamaging effects on the reservoir. Polymer gels have relatively higher rock-retention values and can often damage the invaded zone, in most cases requiring acid treatment to remove. In contrast, VES systems behave as "equilibrium" or "living" polymers, and their viscosity can be reduced by contact with the produced hydrocarbons or with an internal breaker. This can eliminate the need for remedial treatments, greatly reducing operating cost/time and damage to the formation.

Cationic, anionic, and cationic/anionic VES systems have historically demonstrated limitations in high-density brines. Electrostatic screening generally reduces the viscosity or causes phase separation. Many surfactants generally have low salt tolerance and minimal to zero tolerance of divalent brines. Most surfactants exhibit a dramatic decrease in viscosity after a certain concentration of salt is reached and even phase separation in some cases.

A novel method has been developed to stabilize different VES packages in high-density completion brines. By controlling the curvature of surfactant aggregates using low-molecular-weight surfactant polymers, nanometer-scale manipulation of the phase behavior is achieved. We have viscosified mono- and divalent high-density brines using cationic, anionic, and catanionic mixtures that were previously considered ineffective. This unlocks a vast range of surfactants for use in high-density completion brines, fracturing/stimulation/acidizing fluids, and sand-control operations.

This paper details the laboratory work performed to develop VES packages for fluids ranging from fresh water to completion brines. Extensive rheology experiments have been run on several fluids, showing the viscoelasticity of these systems. The self-breaking nature of VES systems when in contact with hydrocarbons or exposed to a built-in breaker has also been demonstrated by laboratory experiment.

© 2011. Society of Petroleum Engineers

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History

  • Original manuscript received: 17 May 2011
  • Meeting paper published: 11 April 2011
  • Revised manuscript received: 14 September 2011
  • Manuscript approved: 22 September 2011
  • Published online: 19 December 2011
  • Version of record: 27 December 2011