New Chemical Treatment for Permanent Removal of Condensate Banking from Different Gas Reservoirs

Hassan, Amjed; Mahmoud, Mohamed; Al-Majed, Abdulaziz; Al-Nakhli, Ayman

doi:10.1021/acsomega.9b03685

Cited by 8 publications

(4 citation statements)

References 43 publications

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“…The T 2 cutoff value is utilized to determine the fluid residing in the micro- and macropore pores of composite sandstones. The results demonstrate that the T 2 cutoff value of the Scioto sandstone is 24.6 ± 1.3 ms, which is consistent with the literature findings. , The findings indicate that the prepared composites comprise an average of 65% macropores and 35% micropores.…”

Section: Resultssupporting

confidence: 91%

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Microscopic CO₂ Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

AlKharraa,

Wolf,

AlQuraishi

et al. 2023

Energy Fuels

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Carbon dioxide (CO2) injection has been widely used in conventional reservoirs for enhanced oil recovery and CO2 sequestration. Nevertheless, the effectiveness of CO2 injection in tight reservoirs is limited due to diagenetic processes that impact displacement efficiency. This research work assesses the performance of CO2 injection in tight reservoirs and evaluates oil mobilization and fluid distribution within the rock pore systems. A set of experiments, including routine core analysis, X-ray diffraction (XRD), scanning electron microscopy (SEM), and mercury injection capillary pressure (MICP), was performed on Scioto sandstone. Three core-flooding runs were conducted to evaluate oil recovery of different injection schemes, including tertiary miscible CO2 injection, secondary immiscible CO2 injection, and secondary miscible CO2 injection. A nuclear magnetic resonance (NMR) spectrometer was utilized to evaluate the fluid distribution in pre- and postflooding schemes. Results show that secondary miscible CO2 injection provided the highest displacement efficiency (E d) of 88%, with oil mobilized from both micro- and macropore systems, leading to the highest oil recovery of 93% original oil in place (OOIP). Tertiary miscible CO2 injection had E d of 67%, providing an ultimate oil recovery of 79% OOIP mostly from the macropore system. Limited contribution of micropores during the tertiary miscible CO2 injection is attributed to the increased water content as a result of previously conducted secondary water flooding. Secondary immiscible CO2 injection showed the least oil recovery among the injection schemes of 68% OOIP, which is attributed to the unstable displacement, as indicated by E d of 52%. The efficiency of pore fluid displacement was determined through NMR analyses, and the findings are in line with the displacement efficiency values obtained from core-flood experiments, with a strong positive correlation. This finding is a promising strategy for determining a suitable CO2 injection scheme in tight rocks for oil recovery and CO2 storage.

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Section: Resultssupporting

confidence: 91%

“…The results demonstrate that the T 2 cutoff value of the Scioto sandstone is 24.6 ± 1.3 ms, which is consistent with the literature findings. 50,51 The findings indicate that the prepared composites comprise an average of 65% macropores and 35% micropores.…”

Section: Nmr T 2 Measurementsmentioning

confidence: 88%

Microscopic CO₂ Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

AlKharraa,

Wolf,

AlQuraishi

et al. 2023

Energy Fuels

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“…Exploiting enthalpy associated with the thermochemical reaction allows for remarkable increases in pressure and temperature to be realized downhole [28,29]. The suggested treatment exhibits an attractive performance profile that can combat condensate-banking-related challenges for various types of gas reservoirs associated with carbonate, sandstone, and shale formations [27,30].…”

Section: Introductionmentioning

confidence: 99%

“…Importantly, compared to conventional methods, the outlined process yielded higher thermal efficiency and lower energy loss compared to those of conventional gas-injection methods on an equimolar basis. Given successful lab trials [24][25][26][27]30], this paper for the first time presents a field-scale simulation based on experimentally obtained data for condensate removal from gas reservoirs by means of a thermochemical treatment strategy. In addition, sensitivity analysis was conducted to study the impact of different wellbore conditions on gas-production rate.…”

Section: Introductionmentioning

confidence: 99%

Condensate-Banking Removal and Gas-Production Enhancement Using Thermochemical Injection: A Field-Scale Simulation

et al. 2020

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Condensate-liquid accumulation in the vicinity of a well is known to curtail gas production up to 80%. Numerous approaches are employed to mitigate condensate banking and improve gas productivity. In this work, a field-scale simulation is presented for condensate damage removal in tight reservoirs using a thermochemical treatment strategy where heat and pressure are generated in situ. The impact of thermochemical injection on the gas recovery is also elucidated. A compositional simulator was utilized to assess the effectiveness of the suggested treatment on reducing the condensate damage and, thereby, improve the gas recovery. Compared to the base case, represented by an industry-standard gas injection strategy, simulation studies suggest a significantly improved hydrocarbon recovery performance upon thermochemical treatment of the near-wellbore zone. For the scenarios investigated, the application of thermochemicals allowed for an extension of the production plateau from 104 days, as determined for the reference gas injection case, to 683 days. This represents a 6.5-fold increase in production plateau time, boosting gas recovery from 25 to 89%. The improved recovery is attributed to the reduction of both capillary pressure and condensate viscosity. The presented work is crucial for designing and implementing thermochemical treatments in tight-gas reservoirs.

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Impact of clay mineralogy on the petrophysical properties of tight sandstones

AlKharraa¹,

Wolf²,

AlQuraishi³

et al. 2023

Geoenergy Science and Engineering

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New Chemical Treatment for Permanent Removal of Condensate Banking from Different Gas Reservoirs

Cited by 8 publications

References 43 publications

Microscopic CO₂ Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

Microscopic CO₂ Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

Condensate-Banking Removal and Gas-Production Enhancement Using Thermochemical Injection: A Field-Scale Simulation

Impact of clay mineralogy on the petrophysical properties of tight sandstones

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New Chemical Treatment for Permanent Removal of Condensate Banking from Different Gas Reservoirs

Cited by 8 publications

References 43 publications

Microscopic CO2 Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

Microscopic CO2 Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

Condensate-Banking Removal and Gas-Production Enhancement Using Thermochemical Injection: A Field-Scale Simulation

Impact of clay mineralogy on the petrophysical properties of tight sandstones

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Product

Resources

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Microscopic CO₂ Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage

Microscopic CO₂ Injection in Tight Rocks: Implications for Enhanced Oil Recovery and Carbon Geo-Storage