Application of a non-ionic bio-surfactant instead of chemical additives for prevention of the permeability impairment of a swelling sandstone oil reservoir

Formation damage is a general term, which refers to any process that reduces the production or injectivity of an oil well. Clay swelling formation damage, due to incompatible fluid invasion, is a common problem in the petroleum industry. In this research, the effect of Acanthophyllum root extract (A...

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Bibliographic Details
Published in:Journal of petroleum exploration and production technology 2022-06, Vol.12 (6), p.1523-1539
Main Authors: Razzaghi-Koolaee, Farnam, Zargar, Ghasem, Soltani Soulgani, Bahram, Mehrabianfar, Parviz
Format: Article
Language:English
Subjects:
Additives
Aqueous solutions
Clay
Damage
Earth and Environmental Science
Earth Sciences
Electron microscopy
Energy Systems
Geology
Impairment
Industrial and Production Engineering
Industrial Chemistry/Chemical Engineering
Measurement
Monitoring/Environmental Analysis
Montmorillonite
Montmorillonites
Offshore Engineering
Oil reservoirs
Oil wells
Original Paper-Production Engineering
Particle size
Permeability
Petroleum
Petroleum industry
Plugging
Porous media
Reduction
Reservoirs
Sandstone
Scanning electron microscopy
Sedimentary rocks
Stability analysis
Static tests
Surfactants
Swelling
Tests
Thermal stability
Thermogravimetric analysis
Water chemistry
Zeta potential
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Summary:Formation damage is a general term, which refers to any process that reduces the production or injectivity of an oil well. Clay swelling formation damage, due to incompatible fluid invasion, is a common problem in the petroleum industry. In this research, the effect of Acanthophyllum root extract (ACRE) , a bio-based surfactant, on the reduction in reservoir permeability impairment has been studied. Some static tests were applied to investigate the chemical interaction between the surfactant and montmorillonite (Mt), including Mt sedimentation test, Free swelling index (FSI) test, Zeta potential tests, particle size measurement, and scanning electron microscopy (SEM). Experiments were followed by coreflood and micromodel tests to verify their effect on preventing permeability reduction and pore plugging in porous media. According to the results, Mt dispersion is unstable in the presence of ACRE solution. ACRE can reduce the FSI from 233.3 (totally hydrated Mt) to 94.3%, representing the reduction in hydration potential. The zeta potential of Mt in ACRE aqueous solution moves toward the lowest magnitude, implying that the water molecules surrounding the Mt particles are unstable. Particle size measurement and SEM analysis proved simultaneously that ACRE solution sustains Mt particles flocculated and prevents delamination. The thermal stability of the ACRE was evaluated by thermogravimetric analysis (TGA), and it showed a suitable resistance to the temperature rise. Eventually, coreflood and micromodel tests revealed that ACRE has a high performance in lowering the permeability impairment and pore plugging. All in all, ACRE showed high potential in preventing Mt swelling and, therefore, formation damage in clay-bearing sandstones.
ISSN:2190-0558
2190-0566
DOI:10.1007/s13202-021-01416-7