Non-hydrocarbon gas injection followed by steam-gas co-injection for heavy oil recovery enhancement from fractured carbonate reservoirs

A. Mohsenzadeh, M. Escrochi, M. V. Afraz, Gh Karimi, Y. Al-Wahaibi, Sh Ayatollahi

Research output: Contribution to journalArticle

9 Citations (Scopus)

Abstract

Considerable heavy oil is accumulated in naturally fractured carbonate reservoirs, with very low oil recovery efficiency through costly production techniques. In this experimental study, the effects of different non-hydrocarbon gases on the performance of gas injection process followed by steam-gas co-injection on heavy oil recovery from low permeable full sized carbonate cores were investigated at reservoir conditions in a long fractured laboratory model. Three different gases: pure CO2, pure N2, and their mixtures as synthetic flue gas were used to study the performance of gas injection process. Also, the tests were continued by steam-gas co-injection process that gas was injected with specific steam/gas ratio at steam saturation temperature condition. In the course of experiments, oil and water productions, pressure and temperature were monitored carefully.It was found that during fracture depletion, the piston-like displacement by N2 injection and oil foaming by CO2 injection are the most important mechanisms affecting the oil recovery performance before gas breakthrough. The results showed that after gas breakthrough (GBT), the ultimate oil recovery based on residual oil at GBT for CO2 injection was 58.4% (14.8% by gas injection and 43.6% by steam-gas co-injection), for flue gas injection was 73.8% (9.8% by gas injection and 64% by steam-gas co-injection) and for N2 injection was 47% (13.5% by gas injection and 33.5% by steam-gas co-injection). The results of oil recovery and production rate indicated that the flue gas injection during gas injection and steam-gas co-injection processes was outperforming for heavy oil recovery enhancement from fractured reservoirs.

Original languageEnglish
Pages (from-to)121-130
Number of pages10
JournalJournal of Petroleum Science and Engineering
Volume144
DOIs
Publication statusPublished - Aug 1 2016

Fingerprint

Petroleum reservoirs
heavy oil
Carbonates
Steam
Crude oil
carbonate
Recovery
Gases
gas
Flue gases
oil
Oils
Pistons

Keywords

  • Fractured carbonate reservoirs
  • Gas injection
  • Heavy oil
  • Non-hydrocarbon gases
  • Steam-gas co-injection

ASJC Scopus subject areas

  • Geotechnical Engineering and Engineering Geology
  • Fuel Technology

Cite this

Non-hydrocarbon gas injection followed by steam-gas co-injection for heavy oil recovery enhancement from fractured carbonate reservoirs. / Mohsenzadeh, A.; Escrochi, M.; Afraz, M. V.; Karimi, Gh; Al-Wahaibi, Y.; Ayatollahi, Sh.

In: Journal of Petroleum Science and Engineering, Vol. 144, 01.08.2016, p. 121-130.

Research output: Contribution to journalArticle

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AB - Considerable heavy oil is accumulated in naturally fractured carbonate reservoirs, with very low oil recovery efficiency through costly production techniques. In this experimental study, the effects of different non-hydrocarbon gases on the performance of gas injection process followed by steam-gas co-injection on heavy oil recovery from low permeable full sized carbonate cores were investigated at reservoir conditions in a long fractured laboratory model. Three different gases: pure CO2, pure N2, and their mixtures as synthetic flue gas were used to study the performance of gas injection process. Also, the tests were continued by steam-gas co-injection process that gas was injected with specific steam/gas ratio at steam saturation temperature condition. In the course of experiments, oil and water productions, pressure and temperature were monitored carefully.It was found that during fracture depletion, the piston-like displacement by N2 injection and oil foaming by CO2 injection are the most important mechanisms affecting the oil recovery performance before gas breakthrough. The results showed that after gas breakthrough (GBT), the ultimate oil recovery based on residual oil at GBT for CO2 injection was 58.4% (14.8% by gas injection and 43.6% by steam-gas co-injection), for flue gas injection was 73.8% (9.8% by gas injection and 64% by steam-gas co-injection) and for N2 injection was 47% (13.5% by gas injection and 33.5% by steam-gas co-injection). The results of oil recovery and production rate indicated that the flue gas injection during gas injection and steam-gas co-injection processes was outperforming for heavy oil recovery enhancement from fractured reservoirs.

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