Scale Squeeze Treatments in Short Perforation and High Water Production ESP Wells - Application of Oilfield Scale Management Toolbox

Chen, Tao; Chen, Ping; Montgomerie, Harry; Hagen, Thomas; Heath, Steve

doi:10.2523/iptc-16844-ms

Cited by 9 publications

(2 citation statements)

References 8 publications

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“…When these two incompatible waters mix, unstable, supersaturated brine is created which precipitates CaSO 4 , SrSO 4 and BaSO 4 within the reservoir rock (BinMerdhah et al, 2010). Oilfield scales are inorganic deposits associated with fluidefluid interaction and production of brine (Collins et al, 2006;Chen et al, 2013). Several factors may lead to scale formation, which supersaturation is the most important factor.…”

Section: Introductionmentioning

confidence: 98%

Effect of temperature and calcium ion concentration on permeability reduction due to composite barium and calcium sulfate precipitation in porous media

Naseri

Moghadasi

Jamialahmadi

2015

Journal of Natural Gas Science and Engineering

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Section: Introductionmentioning

confidence: 98%

Effect of temperature and calcium ion concentration on permeability reduction due to composite barium and calcium sulfate precipitation in porous media

Naseri

Moghadasi

Jamialahmadi

2015

Journal of Natural Gas Science and Engineering

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“…Salt precipitation occurs in all operations of wells, but the most negative consequences of scaling occur during oil production using electric submersible pumps (ESPs) (Poynton et al 2008;Chen et al 2013). Intense deposition of calcium carbonate on impellers of ESPs results from an increase in the produced fluid temperature, which is caused by the heat generated by the operating submersible motor.…”

Section: Introductionmentioning

confidence: 99%

Laboratory investigation of a new scale inhibitor for preventing calcium carbonate precipitation in oil reservoirs and production equipment

Khormali

Petrakov

2016

Pet. Sci.

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The formation of mineral scale is a complex problem during the oilfield operations. Scale inhibitors are widely used to prevent salt precipitation within reservoirs, in downhole equipment, and in production facilities. The scale inhibitors not only must have high effectiveness to prevent scale formation, but also have good adsorptiondesorption characteristics, which determine the operation duration of the scale inhibitors. This work is focused on the development of a new scale inhibitor for preventing calcium carbonate formation in three different synthetic formation waters. Scale inhibition efficiency, optical density of the solution, induction time of calcium carbonate formation, corrosion activity, and adsorption-desorption ability were investigated for the developed scale inhibitor. The optimum concentration of hydrochloric acid in the inhibitor was determined by surface tension measurement on the boundary layer between oil and the aqueous scale inhibitor solution. The results show that the optimum mass percentage of 5 % hydrochloric acid solution in the inhibitor was in the range of 8 % to 10 %. The new scale inhibitor had high efficiency at a concentration of 30 mg/L. The results indicate that the induction period for calcium carbonate nucleation in the presence of the new inhibitor was about 3.5 times longer than the value in the absence of the inhibitors. During the desorption process at reservoir conditions, the number of pore volumes injected into the carbonate core for the developed inhibitor was significantly greater than the volume of a tested industrial inhibitor, showing better adsorption/desorption capacity.

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Coiled Tubing Squeeze Intervention: A Case History for Prevention of Mineral Scales Introduced by Seawater Injection in Burgan Reservoir

Yue

Chen

Hagen

et al. 2020

Day 1 Mon, November 09, 2020

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Substantial buildup of CaSO4 and CaCO3 scales downhole contributed to a loss of 10,000 BOPD and the shut-in of 12 of the 70 wells in a Middle East field. The mineral encrustation occurred on electrical submersible pumps (ESPs), motors, and throughout the entire downstream production systems. The root cause was identified to result from water injection of sulfate-containing seawater into calcium-rich formation waters of Burgan and Mauddud reservoirs. This paper presents a case history from scale prediction and laboratory evaluations to the squeeze intervention to demonstrate how an effective scale treatment strategy was set up and implemented. To mitigate the risk of scale deposition during production, a scale inhibitor squeeze treatment was designed and implemented in the field. The design process started with a comprehensive field survey conducted by a field-experienced technologist. Scaling risks were assessed using water chemistries not only from Upper and Lower Burgan and Mauddud reservoirs, but also under all mixing scenarios with seawater. The systematic performance, fluid compatibility, and stability testing were conducted to formulate a cost-effective, custom scale inhibitor that considered the water chemistry and conditions of the specific horizontal well. A collaborative effort between the chemical supplier and coiled-tubing team engineered an effective application procedure to minimize the loss of squeeze fluid due to refilling in the annulus and to deliver the scale inhibitor to targeted zones. This application technique maximized the effectiveness and lifetime of the squeeze treatment. The approach to squeeze treatment design combines extensive field experience and application engineering with custom, cost-effective chemistry to meet well-defined key performance indicators (KPIs). In this case, the product candidate demonstrated a superior minimum effective concentration (MEC) of 5 ppm, as determined by dynamic loop tests and static bottle tests, as well as a full range of brine compatibility at any given mixing condition in the reservoirs. Once the intervention was executed, continuous monitoring of the squeeze application demonstrated that the inhibitor residual concentration in the produced brine remained above MEC for ten months, effectively inhibiting scale during that period. A 55% increase in the treatment lifetime was achieved relative to the target of 180 days while recovering the oil production rate of the well, resulting in an increase of 1,000 BOPD. A revisit to the field confirmed that the scale treatment was effective and found no sign of scale deposition in the previous well locations. Modelling simulation was performed before the intervention and matched the field operation results. Future treatment design was also optimized. The squeeze treatment was carried out for the first time in the field with significant cost savings for the operator in comparison to the previous frequent chemical interventions for the wells involved.

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Scale Squeeze Treatments in Short Perforation and High Water Production ESP Wells - Application of Oilfield Scale Management Toolbox

Cited by 9 publications

References 8 publications

Effect of temperature and calcium ion concentration on permeability reduction due to composite barium and calcium sulfate precipitation in porous media

Effect of temperature and calcium ion concentration on permeability reduction due to composite barium and calcium sulfate precipitation in porous media

Laboratory investigation of a new scale inhibitor for preventing calcium carbonate precipitation in oil reservoirs and production equipment

Coiled Tubing Squeeze Intervention: A Case History for Prevention of Mineral Scales Introduced by Seawater Injection in Burgan Reservoir

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