The Impact of HCl to HF Ratio on Hydrated Silica Formation During the Acidizing of a High Temperature Sandstone Gas Reservoir in Saudi Arabia

Thomas, Robert; Nasr‐El‐Din, Hisham A.; Mehta, S.; Hilab, V.V.; Lynn, J.D.

doi:10.2118/77370-ms

Cited by 41 publications

(6 citation statements)

References 24 publications

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“…The corresponding original permeabilities of the core samples with the initial gas permeabilities of 30 × 10 –3 μm 2 , 80 × 10 –3 μm 2 , and 150 × 10 –3 μm 2 were 38.3%, 44.5%, and 47.5% as shown in Table . This reduction in inorganic plugs can be attributed to the dissolution of CaCO 3 into CO 2 and CaCl 2 by the application of HCl as shown in reaction …”

Section: Resultsmentioning

confidence: 99%

Comparison of Acidizing and Ultrasonic Waves, and Their Synergetic Effect for the Mitigation of Inorganic Plugs

Khan

et al. 2017

Energy Fuels

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The oil and gas industry is plagued by inevitable formation damaged in the wellbore proximity during entire life of the well. Therefore, it is indispensable to ameliorate the damaged permeability by either using conventional applied techniques or ultrasonic-assisted stimulation method. The latter is characterized by efficient, simple and convenient, and environmentally secure method. Due to these distinguished characteristics, the demand of this physical Enhanced Oil Recovery (EOR) technique increased in petroleum industry. In this study, ultrasonic waves and hydrochloric acid (HCl) were used separately as well as in combination to recover the lost productivity caused by calcium carbonate (CaCO3) inorganic plugs in low permeability sandstone core samples. Results showed that permeability recovery increased with irradiation time up to 100 min; however, it decreased with further irradiation. This deviation could be due to particles bridge formation at later stage. In addition, optimum frequency and power of ultrasonic waves (20 kHz and 1000 W) significantly recovered the damaged permeability. Although maximum frequency (25 kHz) could not achieve maximum permeability, but higher power was quite effective. The damaged permeability recoveries of HCl and ultrasonic waves were 44.5% and 37.6% respectively, but the permeability recovery was escalated to 61.5% when HCl and ultrasonic techniques were applied together. Inorganic plugs using ultrasonic waves could chiefly be caused by cavitation, acoustic streaming, and heat generation in three different ways, such as cavitation, boundary friction and transformation upon hitting the medium.

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Section: Resultsmentioning

confidence: 99%

Comparison of Acidizing and Ultrasonic Waves, and Their Synergetic Effect for the Mitigation of Inorganic Plugs

Khan

et al. 2017

Energy Fuels

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“…The past 20 years have yielded a wealth of research on HF acidizing that helps explain problems associated with such treatments (Gdanski 1999;Gdanski and Shuchart 1996;Hartman et al 2006;Li et al 1998;Mahmoud et al 2011;Thomas et al 2002;Zhou and Nasr-El-Din 2013). One of the primary problems associated with using APCA fluids in HF acidizing is eliminating the formation and precipitation of CaF 2 .…”

Section: Problem Frameworkmentioning

confidence: 99%

GLDA/HF Facilitates High Temperature Acidizing and Coiled Tubing Corrosion Inhibition

Reyes

Smith

Beuterbaugh

et al. 2015

SPE European Formation Damage Conference and Exhibition

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An existing limitation of chelant-based fluids available for sandstone acidizing with hydrofluoric acid (HF) is the presence of sodium in the concentrate of the aminopolycarboxylate fluid, which is common in all chelating agents soluble below pH 3.5. The presence of sodium complicates stabilization of the fluid during acidizing processes because of the myriad of chemical reactions that can impact the outcome of a treatment. The use of chelating agents has expanded the temperature range as well as the type of clay minerals that can be exposed to an HF fluid; however, limitations still exist. Core flow testing at 360°F and corrosion testing from 265 to 360°F were conducted. Flow tests were performed using outcrops of two types of sandstones and inductively coupled plasma (ICP) analysis was conducted to elucidate the ionic composition of the spent fluid. Results reported stem from core flow testing with glutamic acid diacetic acid (GLDA) containing HF at very high temperatures (360°F). To encompass a broad range of mineral composition, two types of sandstone cores were employed-heterogeneous (Bandera, 65% quartz) and clean (Leopard, 95% quartz). Corrosion inhibition of the GLDA/HF fluid for use with coiled tubing (CT) was achieved up to 320°F, employing varying classes of inhibitors. The GLDA/HF fluid exhibited lessened corrosion tendencies and could be inhibited for at least 6 hours at 360°F for drillpipe (mass loss rates of 0.025 to 0.05 in./ft 2 were obtained).The presence of sodium in GLDA/HF could be managed, leading to effective permeability improvement of the Bandera core, while the Leopard core underwent a decrease in overall permeability; this latter observation was attributed to the formation of metal fluorides. Neither the presence of CaCO 3 in the Bandera substrate or the use of KCl brine substituting for the usual NH 4 Cl led to permeability impairment. The overall results indicated that 1% HF and 0.6 M GLDA with an auxiliary agent could circumvent the expected problems associated with HF acidizing and modification, volume minimization, or elimination of preflushes. The use of the GLDA chelant facilitates, when using CT to deliver fluid to hot zones (which can be susceptible to formation damage if aggressive fluids based on HCl or formic acid are used, or if acetic acid is employed), could be jeopardized because of the difficulties inhibiting the corrosive effects of HF, HCl, formic, or acetic blends.

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“…In principle, it can also lead to amorphous or colloidal silica precipitation if the pH of the spent fluid was allowed to rapidly increase. Thomas et al (2002) additionally provided data for high-temperature work (300°F), indicating that hydrated silica precipitation can be minimized with the application of 9:1 HCl/HF; but, lower ratios, such as 4:1, cannot (Thomas et al 2002). Geochemical simulation, in conjunction with experimental work, indicates one common conclusion: precipitation of colloidal silica is part of the chemical balance and so far appears to be inevitable (Ying-Hsiao et al 1998;Morgenthaler et al 2008;Gdanski and Schuchart 1997).…”

Section: Introductionmentioning

confidence: 99%

“…The complicated nature of HF-sandstone acidizing is exemplified by the different theories that have been formulated throughout the last decades to explain the reaction of HF on aluminosilicates (Quinn et al 2000;Ying-Hsiao et al 1998;Morgenthaler et al 2008; Thomas et al 2002). Further complicated by the effect of pore network on reactivity (Morgenthaler et al 2008), sandstone acidizing fluids that have HF include either HCl as the base acid or an organic, formic, acetic, or citric acid, or some chelating agents.…”

Section: Introductionmentioning

confidence: 99%

Applications and Laboratory Studies of a New Class of Silica Polymerization Inhibitors of Bio-renewable Origin

Reyes-García

2011

All Days

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Silica precipitation during a sandstone acidizing treatment or its subsequent deposition post-treatment can negate the effectiveness of said acid treatment. Moreover, the removal of tenacious silica scale from a wellbore can sometimes result in matrix damage as a result of injecting the dissolved silicon into the formation. While this problem is well-known, effective solutions continue to be sought to sustain mature, hydrothermal, and siliceous wells that suffer from fines migration. Geochemical reactions operative in siliceous formations can induce various processes, such as silica migration, diagenesis, or hard scale. Laboratory investigations focused on preventing the formation of silica have identified a new class of silica polymerization inhibitor (SPI). The SPI mechanism is disruption or retardation of the condensation and polymerization of silicic acid monomers and oligomers and the ultimate growth of amorphous silica. Aluminum, commonly present in clay and feldspar minerals, can interfere with the SPI, so its effect has been studied. Dissolved Al 3+ in the fluid must be regulated with the use of chelating agents to prevent precipitation, along with the silicon-SPI complex, at pH levels of interest in acidizing operations, namely <4. Most effective acidizing treatments employ HF formulations, with HCl or organic acids, to dissolve the silicate minerals or scale in the near-wellbore region; hence, these studies are directed toward this application.The SPI described in this work is a naturally occurring material of low molecular weight (MW) that effectively maintains in solution total dissolved silicon concentrations of up to 3,000 mg/L (0.12 M) below 2 pH, where minimal precipitation has been observed. Minimization of silica precipitation with typical concentrations of 1,000 to 2,000 mg/L of SPI was attained at <4 pH. At this and lower pH levels, nearly constant silicon concentrations of 2,400 mg/L were maintained. These findings are significant to maximizing resource recovery because they allow the operator to consider alternatives for treatment processes geared toward higher-temperature wells, fracture acidizing, and expansion of the pH range of treatment fluids.

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The Impact of HCl to HF Ratio on Hydrated Silica Formation During the Acidizing of a High Temperature Sandstone Gas Reservoir in Saudi Arabia

Cited by 41 publications

References 24 publications

Comparison of Acidizing and Ultrasonic Waves, and Their Synergetic Effect for the Mitigation of Inorganic Plugs

Comparison of Acidizing and Ultrasonic Waves, and Their Synergetic Effect for the Mitigation of Inorganic Plugs

GLDA/HF Facilitates High Temperature Acidizing and Coiled Tubing Corrosion Inhibition

Applications and Laboratory Studies of a New Class of Silica Polymerization Inhibitors of Bio-renewable Origin

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