Low Viscosity Polymer Free Acid Retarded System, a Novel Alternative to Emulsified Acid: Successful Application in West Kuwait Field

Al-Sabea, Salem; Abdullah, Amir; Patra, Milan; AlEidi, Mohammad Naji; Ambrosi, Giuseppe; Khandelwal, Nakul; Gaur, Rishika; Matar, Khaled; wazzan, Abdulatif Al; Vasquez, Julio Estuardo

doi:10.2523/iptc-22665-ms

Cited by 2 publications

(1 citation statement)

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“…EAS stability is affected by acid-to-oil ratio, types of acid and oil, and chemical additives A low-viscosity, single-phase acid system for acid fracturing. The system consists of a pre-engineered blend of an alkyl sulfonic acid and a strong mineral acid and exhibited comparable performance to the 15 wt % HCl−EAS in terms of diffusion and reduced drag Al-Sabea et al, (2022) 40 Developed a low-viscosity, polymer-free acid-retarded system and a successful case study in the west Kuwait field. The acid system consists of a robust mineral acid, HCl, with a nondamaging retarding agent.…”

Section: ■ Introductionmentioning

confidence: 99%

Novel Environmentally Friendly Nanomaterials for Drag Reduction of the Emulsified Acid System

AL-Dogail,

Gajbhiye,

Solling

et al. 2023

ACS Omega

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Matrix acidizing is a technique that is widely used in the petroleum industry to remove scales and create channels in the rock. Removal of scales and creation of channels (wormhole) enhance productivity. Conventional acidizing fluids, such as hydrochloric acid (HCl) for carbonate and a mixture of hydrofluoric acid (HF) and HCl acid, are used for the matrix acidizing process. However, these fluids have some drawbacks, including strong acid strength, corrosion at high temperatures, and quick reactions with scale and particles. Emulsified acid systems (EASs) are used to address these drawbacks. EASs can create deeper and narrower wormholes by reducing the reaction rate of the acid due to the external oil phase. However, EASs have a much higher viscosity compared to conventional acidizing fluids. The high viscosity of EASs leads to a high drag that restricts pumping rates and consumes energy. This study aims to utilize environmentally friendly and widely available nanomaterials as drag-reducing agents (DRAs) of the EAS. The nanomaterials used in this study are carbon nanodots (CNDs). CNDs have unique properties and are used in diverse applications in different industries. The size of these CNDs is usually smaller than 10 nm. CNDs are characterized by their biocompatibility and chemical stability. This study investigates the use of CNDs as DRAs for EAS. Several experiments have been conducted to investigate the CNDs as a DRA for the EAS. The developed EAS was initially tested for conductivity and drop-test analysis to ensure the formation of an inverted emulsion. Thereafter, the thermal stability for the range of temperatures and the rheological properties of the EAS were evaluated to meet the criteria of field operation. Then flow experiments with EASs were conducted before and after adding the CNDs to investigate the efficacy of drag reduction of EASs. The results revealed that CNDs can be used as viscosity reducers for the EAS, where adding the CNDs to the EAS reduces the viscosity at two different HCl concentrations (15 and 20%). It reduces the viscosity of the EAS in the presence of corrosion inhibitors as well as other additives to the EAS, showing its compatibility with the field formulation. The drag reduction was observed at the range of temperatures investigated in the study. The conductivity, stability, and rheology experiments for the sample taken after the flow experiment are consistent, ensuring CNDs work as a DRA. The developed EAS with CNDs is robust in terms of field mixing procedures and thermally stable. The CNDs can be used as a DRA with EAS, which will reduce drag in pipes, increasing pumping rates and saving energy.

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Section: ■ Introductionmentioning

confidence: 99%

Novel Environmentally Friendly Nanomaterials for Drag Reduction of the Emulsified Acid System

AL-Dogail,

Gajbhiye,

Solling

et al. 2023

ACS Omega

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Novel Density-Controlled Acidizing Approach: Weighted Single-Phase Retarded Acid System in Conjunction with Light-Density Gel Slugs and Fluidic Oscillator Technology Shows a Two-Fold Oil Production Increase and 10% Water Cut Reduction in a Single Run, Case Study from Iraq

Masoodi,

Corrales,

Nunez

et al. 2024

Adipec

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A novel strategy to optimize hydrocarbon recovery from low-permeability carbonate reservoirs under challenging high-pressure/high- temperature (HP/HT) conditions is discussed, along with water intrusion from higher-permeability layers. The strategy uses coiled tubing (CT), a tailored 60-cp gel slug, and a single-phase hydrochloric retarded acid (SPHRA) system, densified via the density control acidizing (DCA) principle. This approach was tailored to the reservoir complexities and an HP/HT environment. Rigorous simulation studies informed the acid solution formulation, focused on leakoff control in the upper high-permeability layer. The high gel load (60 cp) strategy combined with CT assistance facilitated precise placement and isolation of the water-bearing zone to mitigate reservoir challenges. Enhanced CT placement using a fluid oscillating tuned frequency and amplitude (FOTFA) tool, coupled with DCA for the hydrochloric retarded acid (HRA), resulted in deep penetration into the near-wellbore (NWB) region. Post-operation analysis confirmed successful mitigation of water intrusion from higher-permeability layers, with no increase in water cut observed. Strategic HRA deployment led to substantial and sustained improvements in hydrocarbon production. The strength of the HRA, combined with meticulous FOTFA deployment planning and a tailored DCA-enhanced acid solution, demonstrated adaptability and efficacy in extreme reservoir environments. This integrated methodology overcame challenges posed by layered reservoir structures and sets a new standard for precision in HP/HT reservoir management. The innovative synergy of a high-viscosity gel slug and the novel HRA with FOTFA placement, customized and densified via the DCA principle, are presented. The integration of DCA into the acid system ensures adaptability and optimal performance in extreme reservoir conditions, which marks a significant advancement in reservoir stimulation practices.

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Low Viscosity Polymer Free Acid Retarded System, a Novel Alternative to Emulsified Acid: Successful Application in West Kuwait Field

Cited by 2 publications

References 1 publication

Novel Environmentally Friendly Nanomaterials for Drag Reduction of the Emulsified Acid System

Novel Environmentally Friendly Nanomaterials for Drag Reduction of the Emulsified Acid System

Novel Density-Controlled Acidizing Approach: Weighted Single-Phase Retarded Acid System in Conjunction with Light-Density Gel Slugs and Fluidic Oscillator Technology Shows a Two-Fold Oil Production Increase and 10% Water Cut Reduction in a Single Run, Case Study from Iraq

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