Improvements of Superheated Steam Stimulation in Secondary Development of Heavy Oil Reservoir

An Zhu Xu; Xiang Hong Wu; Zi Fei Fan; Lun Zhao; Cheng Gang Wang

doi:10.4028/www.scientific.net/AMR.524-527.1450

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 524-527Improvements of Superheated Steam Stimulation in...

Improvements of Superheated Steam Stimulation in Secondary Development of Heavy Oil Reservoir

Abstract:

With superheated steam, there is no direct relationship between temperature and pressure, Therefore, at a particular pressure it is possible for superheated steam to exist at a wide range of temperatures higher than that of its saturated steam. The heat transfer coefficient is 1/150-1/250 as much as that of saturated steam during heat transferring, and it takes a relatively long time to cool, during which time the steam is releasing very little energy and transmitted long distances. The mechanisms of superheated steam stimulation are mainly pointed to the performance of crude oil viscosity reduced, flow environment improved, rock wettability changed, oil displacement efficiency improved. Physical simulation shows that oil displacement efficiency by superheated steam is 6-12% higher than that of saturated steam at the same temperature, and under the condition of carrying the same heat, superheated steam enlarged the heating radius by about 10m, oil steam ratio increased by 0.7. Superheated steam stimulation was put into Kazakstan’s heavy oil reservoir after two cycles of saturated steam stimulation. The average daily oil production was 2-4 times that of saturated steam stimulation, which improved heavy oil production effectively. The secondary heavy oil thermal recovery by superheated steam stimulation applied in marginal heavy oil reservoirs achieved satisfactory effect.

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Periodical:

Advanced Materials Research (Volumes 524-527)

Pages:

1450-1455

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.524-527.1450

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Online since:

May 2012

Authors:

An Zhu Xu, Xiang Hong Wu, Zi Fei Fan, Lun Zhao, Cheng Gang Wang

Keywords:

Heat Transfer Coefficient (HTC), Heavy Oil, Recovery Mechanism, Secondary Thermal Recovery, Superheated Steam Stimulation

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