Summary
A self-diverting-acid based on viscoelastic surfactant (SDVA) has been
successfully used recently on numerous stimulation treatments of carbonate
formations in various fields.
The decrease of acid concentration during the spending process
viscosifies the fluid through the transformation from spherical micelles to an
entangled wormlike micellar structure while penetrating the carbonate rock. The
highly viscous fluid acts as a temporary barrier and diverts the fluid into the
remaining lower-permeability treating zones. After treatment, the SDVA barrier
breaks when contacted either by formation hydrocarbons or pre- and postflush
fluids. Quantifying diversion, fluid efficiency, and cleanup are important
factors for successful candidate selection and job design. Laboratory tests
defining these key factors are presented in this paper.
This paper demonstrates the diverting ability of the acid as a function of
permeability, characterized by introducing the concept of maximum pressure
ratio (dPmax/dP0) supported by core-flow
and acid conductivity tests using limestone and dolomite cores. Results
demonstrate high dPmax/dP0 in
high-permeability cores and low dPmax/dP0 in low-permeability cores. Retained permeability measurements are
presented that assess the level of cleanup. Flow-initiation experiments of
spent acid systems with gas and brine were performed to illustrate the cleanup
behavior of SDVA in comparison to gelled acid systems under conditions
encountered in gas and oil wells. The results indicate that SDVA systems clean
up easily and that SDVA provides higher regained permeability than conventional
gelled acid systems.
Background
The purpose of matrix stimulation in limestone and dolomite reservoirs is
the formation of wormholes, which can bypass the damaged areas and increase the
effective wellbore area. When acid enters the formation with the highest
injectivity it creates highly conductive flow channels, called wormholes, by
dissolving the carbonate-containing minerals. Consequently, the injectivity
will be further increased. The other zones are left untreated by the acid. To
overcome this problem, a diverting agent is used. Mechanical diverters
such as ball sealers, degradable ball sealers, rock salt, and benzoic acid
flakes are used alone or in conjunction with chemical diverters based on foams
or polymeric gels (Williams et al. 1979; Economides and Nolte 1989). These
materials can work effectively only in a narrow permeability contrast and may
result in residual damage (Lynn and Nasr-El-Din 2001). These characteristics
are highly undesirable, particularly in low-pressure gas wells, and in long
vertical and horizontal sections.
Polymer-based systems such as in-situ crosslinked gelled acids (XLGA) have
been used in the field as self-diverting fluids. These systems rely on a
pH-triggered increase of viscosity during the acid spending process.
Essentially, the pH change activates a metallic reagent that crosslinks the
polymer chains, and the resulting viscosity increase causes a higher flow
resistance (Mukherjee and Gudney 1993; Saxon et al. 1997). Further increase of
the pH deactivates the metallic crosslinker and breaks the fluid down to the
original linear gel with dissociated polymer chains. However, because of the
nature of the long polymer chains, potential damage of the formation may occur
(Lynn and Nasr-El-Din 2001).
Recently, a new polymer-free self-diverting acid system was developed with a
fluid stability in temperatures greater than 300°F (Taylor et al. 2003; Chang
et al. 2001). The fluid system has been applied successfully in both matrix
(Al-Mutawa et al. 2001) and acid-fracturing (Al-Muhareb et al. 2003; Artola et
al. 2004) treatments. It causes rapid viscosity development throughout the
spending process. The reduction in acid concentration, together with the
simultaneous release of ions in solution, promotes the transformation from
spherical micelles into worm-like micelles, resulting in increased viscosity of
the fluid. The highly viscous fluid subsequently diverts the remaining acid
treatment fluid into zones of lower injectivity by reducing the acid loss into
wormholes, resulting in an improved zonal coverage of the treatment interval.
Diversion tests using multiple parallel cores with varying permeabilities
showed effective stimulation in all cores (Taylor et al. 2003; Chang et al.
2001).
This paper presents new data providing further insight into the
understanding of the unique properties of this SDVA based on laboratory
studies. Specifically described are the chemical and physical properties of the
SDVA fluid, including cleanup efficiency that is relevant to low-pressure
reservoirs.
© 2007. Society of Petroleum Engineers
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History
- Original manuscript received:
16 June 2004
- Meeting paper published:
18 February 2004
- Revised manuscript received:
23 May 2006
- Manuscript approved:
23 May 2006
- Version of record:
20 February 2007
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