Cyclic Supercritical Multi-Thermal Fluid Stimulation Process: A Novel Improved-Oil-Recovery Technique for Offshore Heavy Oil Reservoir

Tian, Jijun; Yan, Wende; Zhou, Qi; Huang, Shi‐Wen; Yuan, Yilong; Dong, Meichen

doi:10.3390/en15239189

Cited by 3 publications

(2 citation statements)

References 21 publications

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“…The mixed fluid provides a significant oil recovery effect through the synergistic effect in the reservoir . Due to the large amount of N 2 and CO 2 contained in the supercritical multicomponent thermal fluid, the dissolved NCGs (mainly CO 2 ) in the multicomponent thermal fluid can also achieve the effect of reducing crude oil viscosity, in addition to conventional heating viscosity reduction. , Furthermore, NCGs (mainly N 2 ) can also reduce the reservoir heat loss, maintain the reservoir pressure, and thereby increase the recovery rate. , …”

Section: Introductionmentioning

confidence: 99%

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Study on Hydrothermal Cracking of Heavy Oil under the Coexisting Conditions of Supercritical Water and Non-condensate Gas

et al. 2023

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This study looked at the effects of temperature, water−oil ratio, and the addition of non-condensable gas on the thermal cracking of extra-heavy oil in the lab. The goal was to learn more about the properties and reaction rates of deep extra-heavy oil under supercritical water conditions, which are not well understood. The changes in the composition of the extra-heavy oil were analyzed with and without the presence of non-condensable gas. The reaction kinetics of the thermal cracking of extra-heavy oil were quantitatively characterized and compared between the two conditions of supercritical water alone and supercritical water mixed with non-condensable gas. The results showed that (1) under supercritical water conditions, the extra-heavy oil underwent significant thermal cracking, which led to a significant increase in the amount of light components, the release of CH 4 , and the formation of a new component, coke, which led to a noticeable decrease in the viscosity of the oil; (2) increasing the water−oil ratio could promote the thermal cracking of extra-heavy oil and led to a significant decrease in oil viscosity, indicating a more complete thermal cracking reaction. Moreover, increasing the water−oil ratio was found to facilitate the flowability of the cracked oil; (3) the addition of non-condensable gas intensified the conversion of coke but inhibited and slowed down the thermal cracking of asphaltene, which is detrimental to the thermal cracking of extra-heavy oil; and (4) the kinetic analysis showed that the addition of non-condensable gas resulted in a decrease in the thermal cracking rate of asphaltene, which is detrimental to the thermal cracking of heavy oil.

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Section: Introductionmentioning

confidence: 99%

“… 35 , 36 Furthermore, NCGs (mainly N 2 ) can also reduce the reservoir heat loss, maintain the reservoir pressure, and thereby increase the recovery rate. 37 , 38 …”

Section: Introductionmentioning

confidence: 99%

Study on Hydrothermal Cracking of Heavy Oil under the Coexisting Conditions of Supercritical Water and Non-condensate Gas

et al. 2023

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Review on mechanisms of petrophysical properties variation during thermal fluids injection into heavy oil reservoirs

Yang,

et al. 2024

Geoenergy Science and Engineering

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New Advances in Oil, Gas, and Geothermal Reservoirs

Zhu

2023

Energies

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The most significant geo-energy sources in the world today continue to be oil, gas, and geothermal reservoirs. To increase oil and gas reserves and production, new theories are constantly being developed in the laboratory and new technologies are being applied in the oilfield. This Special Issue compiles recent research focusing on cutting-edge ideas and technology in oil, gas, and geothermal reservoirs, covering the fields of well drilling, cementing, hydraulic fracturing, improved oil recovery, conformance control, and geothermal energy development.

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Cyclic Supercritical Multi-Thermal Fluid Stimulation Process: A Novel Improved-Oil-Recovery Technique for Offshore Heavy Oil Reservoir

Cited by 3 publications

References 21 publications

Study on Hydrothermal Cracking of Heavy Oil under the Coexisting Conditions of Supercritical Water and Non-condensate Gas

Study on Hydrothermal Cracking of Heavy Oil under the Coexisting Conditions of Supercritical Water and Non-condensate Gas

Review on mechanisms of petrophysical properties variation during thermal fluids injection into heavy oil reservoirs

New Advances in Oil, Gas, and Geothermal Reservoirs

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