Hydrofluoric Acid Reaction with a Porous Sandstone

Williams, Brock; Whiteley, Michael

doi:10.2118/3112-pa

Cited by 24 publications

(8 citation statements)

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“…Eq. 6 is similar to one previously mentioned in the literature, 8 though the approaches are different.…”

Section: Dynamic Sandstone Acidizingsupporting

confidence: 57%

Thermodynamic and Kinetic Aspects of Argillaceous Sandstone Acidizing

Labrid

1975

Society of Petroleum Engineers Journal

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The thermodynamic aspect 'of sandstone acidizing by hydrofluoric acid (H F) is examined. It is shown that silica dissolution, with a first order in HF concentration, leads almost exclusively to the formation of fluosilicic acid. Clay and feldspar dissolution is much more complex,· after a uniform alteration of the crystalline lattice, partial precipitation of silicic species occurs when the acid is spent.An approach to the kine tic aspect is made by de fining, for a naturally complex medi"um, a reactivity prolile that is a characteristic of the medium instead of a single reaction-rate constant. Experimental data enable a correlation between ,permeability, porosity, and reactivity. Also, ,a qualitative interpretation of acid response curves zs given. The numerical simulation of the acidizing process satisfactorily reproduces the experimental results. When extended to radial flow! the model shows the influence of stimulation .parameters, injection rate, concentration, and time.

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“…Eq. 6 is similar to one previously mentioned in the literature, 8 though the approaches are different.…”

Section: Dynamic Sandstone Acidizingsupporting

confidence: 57%

Thermodynamic and Kinetic Aspects of Argillaceous Sandstone Acidizing

Labrid

1975

Society of Petroleum Engineers Journal

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“…To mitigate formation damage due to the fracturing gel, it has been found that lowering pH value can also remove gel residuals and clean up such damage [32,33]. Meanwhile, using acid can also create new flow paths, dissolve suspended fines, and clean up the plugged pores [34][35][36]; in the field, using acid (i.e., acidizing) has already been successfully applied in sandstone reservoirs to enhance the production [37]. Lowpermeability sandstone with well-developed natural fractures has a complex pore structure, where pores and pore throats have a wide range of diameters.…”

Section: Introductionmentioning

confidence: 99%

Formation Damage due to Drilling and Fracturing Fluids and Its Solution for Tight Naturally Fractured Sandstone Reservoirs

Liang

Yao

et al. 2017

Geofluids

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Drilling and fracturing fluids can interact with reservoir rock and cause formation damage that impedes hydrocarbon production. Tight sandstone reservoir with well-developed natural fractures has a complex pore structure where pores and pore throats have a wide range of diameters; formation damage in such type of reservoir can be complicated and severe. Reservoir rock samples with a wide range of fracture widths are tested through a multistep coreflood platform, where formation damage caused by the drilling and/or fracturing fluid is quantitatively evaluated and systematically studied. To further mitigate this damage, an acidic treating fluid is screened and evaluated using the same coreflood platform. Experimental results indicate that the drilling fluid causes the major damage, and the chosen treating fluid can enhance rock permeability both effectively and efficiently at least at the room temperature with the overburden pressure.

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“…One of the earliest reports of this phenomenon appeared almost 15 years ago, 1 and numerous others have followed. [2][3][4][5] These observations have been incorporated into general field guidelines that frequently call for large acid volumes just to overcome the damage caused by initial acid injection. Various theories have attributed this initial damage to fines plugging, precipitation of insoluble fluosilicates, and precipitation of silica.…”

Section: Permeability Increase Caused By Hfmentioning

confidence: 99%

“…Silica precipitation from spent hydrofluoric acid can be very damaging to rock permeability. 3. Sandstone formations containing iron-bearing minerals can be acidized successfully.…”

Section: Introductionmentioning

confidence: 99%

Understanding Sandstone Acidizing Leads to Improved Field Practices

Shaughnessy

Kunze

1981

Journal of Petroleum Technology

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A design criterion based on type and depth of damage is proposed to replace laboratory design curves that may have been distorted by CO 2 evolution. Furthermore, sandstone acidizing experiments have provided evidence that reprecipitation of dissolved silica from spent HF can be a real limitation to acidizing success if operational precautions are not taken. Finally, the potential for iron precipitation from spent HCI acidizing solutions is seen to be dependent on certain conditions such as iron oxidation state and the presence of carbonates.

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Hydrofluoric Acid Reaction with a Porous Sandstone

Cited by 24 publications

References 0 publications

Thermodynamic and Kinetic Aspects of Argillaceous Sandstone Acidizing

Thermodynamic and Kinetic Aspects of Argillaceous Sandstone Acidizing

Formation Damage due to Drilling and Fracturing Fluids and Its Solution for Tight Naturally Fractured Sandstone Reservoirs

Understanding Sandstone Acidizing Leads to Improved Field Practices

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