Microbial enhanced oil recovery at high salinities using biosurfactant at lower concentrations

Research output: Chapter in Book/Report/Conference proceedingConference contribution

1 Citation (Scopus)

Abstract

This study investigates the ability of lipopeptide biosurfactant produced from Bacillus subtillis W19 isolated from oil contaminated Omani oil field soil samples to recover the residual oil at reduced concentration. The biosurfactant reduced the interfacial tension to 1.8 mN/m and also altered the wettability to more neutral wettability. The biosurfactant is stable over wide range of pH and temperatures. The minimum biosurfactant concentration required to make the process economically feasible was determined by performing core-flood experiments at various critical micelle dilutions using 200-300 mD Berea sandstone cores with porosity of 22%. The fluids used in the work are 32° API crude oil, and brine with 7-9% salinity collected from the field of interest. All core-flood experiments were conducted at the reservoir temperature, 60°C. It was found that even after 20 times dilution biosurfactant can maintain an extra recovery of 14% of residual oil after water flooding. These results revealed that the biosurfactant is still effective even at concentration as low as the CMC value (0.1 g/L). Furthermore, the performance of 20 times diluted biosurfactant was improved by mixing it with commercial chemical surfactant to the ratios of 50% biosurfactant: 50% chemical surfactant and 25% biosurfactant: 75% chemical surfactant, resulted in extra recovery of 28% and 27% of residual oil after water flooding respectively. Salinity studies show that this biosurfactant has high turbidity point, and maintained a relatively low interfacial tension values over wide range of salinities. When the salinity was increased to 20%, the biosurfactant was still successful in reducing the water flooding residual oil saturation by 12% even when diluted by 10 times. Economical evaluation showed that using this biosurfactant at low concentration would produce appreciable amount of trapped oil with minimum cost.

Original languageEnglish
Title of host publicationSociety of Petroleum Engineers - SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR
PublisherSociety of Petroleum Engineers
Pages207-213
Number of pages7
ISBN (Print)9781632663184
Publication statusPublished - 2014
EventSPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR - Muscat, Oman
Duration: Mar 31 2014Apr 2 2014

Other

OtherSPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR
CountryOman
CityMuscat
Period3/31/144/2/14

Fingerprint

enhanced oil recovery
salinity
Recovery
oil
surfactant
Surface active agents
flooding
wettability
Dilution
Surface tension
Wetting
dilution
Water
Bacilli
Turbidity
Oil fields
Sandstone
Application programming interfaces (API)
Micelles
water

ASJC Scopus subject areas

  • Geotechnical Engineering and Engineering Geology

Cite this

Souayeh, M., Al-Wahaibi, Y., Al-Bahry, S., Elshafie, A., Al-Bemani, A., Joshi, S., ... Al-Mandhari, M. (2014). Microbial enhanced oil recovery at high salinities using biosurfactant at lower concentrations. In Society of Petroleum Engineers - SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR (pp. 207-213). Society of Petroleum Engineers.

Microbial enhanced oil recovery at high salinities using biosurfactant at lower concentrations. / Souayeh, M.; Al-Wahaibi, Y.; Al-Bahry, S.; Elshafie, A.; Al-Bemani, A.; Joshi, S.; Al-Hashmi, A.; Al-Mandhari, M.

Society of Petroleum Engineers - SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR. Society of Petroleum Engineers, 2014. p. 207-213.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Souayeh, M, Al-Wahaibi, Y, Al-Bahry, S, Elshafie, A, Al-Bemani, A, Joshi, S, Al-Hashmi, A & Al-Mandhari, M 2014, Microbial enhanced oil recovery at high salinities using biosurfactant at lower concentrations. in Society of Petroleum Engineers - SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR. Society of Petroleum Engineers, pp. 207-213, SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR, Muscat, Oman, 3/31/14.
Souayeh M, Al-Wahaibi Y, Al-Bahry S, Elshafie A, Al-Bemani A, Joshi S et al. Microbial enhanced oil recovery at high salinities using biosurfactant at lower concentrations. In Society of Petroleum Engineers - SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR. Society of Petroleum Engineers. 2014. p. 207-213
Souayeh, M. ; Al-Wahaibi, Y. ; Al-Bahry, S. ; Elshafie, A. ; Al-Bemani, A. ; Joshi, S. ; Al-Hashmi, A. ; Al-Mandhari, M. / Microbial enhanced oil recovery at high salinities using biosurfactant at lower concentrations. Society of Petroleum Engineers - SPE EOR Conference at Oil and Gas West Asia 2014: Driving Integrated and Innovative EOR. Society of Petroleum Engineers, 2014. pp. 207-213
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abstract = "This study investigates the ability of lipopeptide biosurfactant produced from Bacillus subtillis W19 isolated from oil contaminated Omani oil field soil samples to recover the residual oil at reduced concentration. The biosurfactant reduced the interfacial tension to 1.8 mN/m and also altered the wettability to more neutral wettability. The biosurfactant is stable over wide range of pH and temperatures. The minimum biosurfactant concentration required to make the process economically feasible was determined by performing core-flood experiments at various critical micelle dilutions using 200-300 mD Berea sandstone cores with porosity of 22{\%}. The fluids used in the work are 32° API crude oil, and brine with 7-9{\%} salinity collected from the field of interest. All core-flood experiments were conducted at the reservoir temperature, 60°C. It was found that even after 20 times dilution biosurfactant can maintain an extra recovery of 14{\%} of residual oil after water flooding. These results revealed that the biosurfactant is still effective even at concentration as low as the CMC value (0.1 g/L). Furthermore, the performance of 20 times diluted biosurfactant was improved by mixing it with commercial chemical surfactant to the ratios of 50{\%} biosurfactant: 50{\%} chemical surfactant and 25{\%} biosurfactant: 75{\%} chemical surfactant, resulted in extra recovery of 28{\%} and 27{\%} of residual oil after water flooding respectively. Salinity studies show that this biosurfactant has high turbidity point, and maintained a relatively low interfacial tension values over wide range of salinities. When the salinity was increased to 20{\%}, the biosurfactant was still successful in reducing the water flooding residual oil saturation by 12{\%} even when diluted by 10 times. Economical evaluation showed that using this biosurfactant at low concentration would produce appreciable amount of trapped oil with minimum cost.",
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