A two-fluid model for vertical flow applied to CO2 injection wells

Niels Bohr Institute

A two-fluid model for vertical flow applied to CO₂ injection wells

Research output: Contribution to journal › Journal article › Research › peer-review

Standard

A two-fluid model for vertical flow applied to CO₂ injection wells. / Linga, Gaute; Lund, Halvor.

In: International Journal of Greenhouse Gas Control, Vol. 51, 01.08.2016, p. 71-80.

Research output: Contribution to journal › Journal article › Research › peer-review

Harvard

Linga, G & Lund, H 2016, 'A two-fluid model for vertical flow applied to CO₂ injection wells', International Journal of Greenhouse Gas Control, vol. 51, pp. 71-80. https://doi.org/10.1016/j.ijggc.2016.05.009

APA

Linga, G., & Lund, H. (2016). A two-fluid model for vertical flow applied to CO₂ injection wells. International Journal of Greenhouse Gas Control, 51, 71-80. https://doi.org/10.1016/j.ijggc.2016.05.009

Vancouver

Linga G, Lund H. A two-fluid model for vertical flow applied to CO₂ injection wells. International Journal of Greenhouse Gas Control. 2016 Aug 1;51:71-80. https://doi.org/10.1016/j.ijggc.2016.05.009

Author

Linga, Gaute ; Lund, Halvor. / A two-fluid model for vertical flow applied to CO₂ injection wells. In: International Journal of Greenhouse Gas Control. 2016 ; Vol. 51. pp. 71-80.

Bibtex

@article{7a272e0126a54418bc18879585055de2,

title = "A two-fluid model for vertical flow applied to CO2 injection wells",

abstract = "Flow of CO2 in wells is associated with substantial variations in thermophysical properties downhole, due to the coupled transient processes involved: complex flow patterns, density changes, phase transitions, and heat transfer to and from surroundings. Large temperature variations can lead to thermal stresses and subsequent loss of well integrity, and it is therefore crucial to employ models that can predict this accurately. In this work, we present a model for vertical well flow that includes both two-phase flow and heat conduction. The flow is described by a two-fluid model, where mass transfer between the phases is modelled by relaxation source terms that drive the phases towards thermodynamic equilibrium. We suggest a new formulation of the mass transfer process that satisfies the second law of thermodynamics, and that is also continuous in the single-phase limit. This provides a more robust transition from two-phase to single-phase flow than the previous formulation. The model predicts which flow regimes are present downhole, and calculates friction and heat transfer depending on this. Moreover, the flow model is coupled with a heat conduction model for the layers that comprise the well, including tubing, packer fluid, casing, cement or drilling mud, and rock formation. This enables prediction of the temperature in the well fluid and in each layer of the well. The model is applied to sudden shut-in and blowout cases of a CO2 injection well, where we employ the highly accurate Span-Wagner reference equation-of-state to describe the thermodynamics of CO2. We predict pressure, temperature and flow regimes during these cases and discuss implications for well integrity.",

keywords = "CO injection wells, Thermal modelling, Two-phase flow, Well integrity",

author = "Gaute Linga and Halvor Lund",

year = "2016",

month = aug,

day = "1",

doi = "10.1016/j.ijggc.2016.05.009",

language = "English",

volume = "51",

pages = "71--80",

journal = "International Journal of Greenhouse Gas Control",

issn = "1750-5836",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - A two-fluid model for vertical flow applied to CO2 injection wells

AU - Linga, Gaute

AU - Lund, Halvor

PY - 2016/8/1

Y1 - 2016/8/1

N2 - Flow of CO2 in wells is associated with substantial variations in thermophysical properties downhole, due to the coupled transient processes involved: complex flow patterns, density changes, phase transitions, and heat transfer to and from surroundings. Large temperature variations can lead to thermal stresses and subsequent loss of well integrity, and it is therefore crucial to employ models that can predict this accurately. In this work, we present a model for vertical well flow that includes both two-phase flow and heat conduction. The flow is described by a two-fluid model, where mass transfer between the phases is modelled by relaxation source terms that drive the phases towards thermodynamic equilibrium. We suggest a new formulation of the mass transfer process that satisfies the second law of thermodynamics, and that is also continuous in the single-phase limit. This provides a more robust transition from two-phase to single-phase flow than the previous formulation. The model predicts which flow regimes are present downhole, and calculates friction and heat transfer depending on this. Moreover, the flow model is coupled with a heat conduction model for the layers that comprise the well, including tubing, packer fluid, casing, cement or drilling mud, and rock formation. This enables prediction of the temperature in the well fluid and in each layer of the well. The model is applied to sudden shut-in and blowout cases of a CO2 injection well, where we employ the highly accurate Span-Wagner reference equation-of-state to describe the thermodynamics of CO2. We predict pressure, temperature and flow regimes during these cases and discuss implications for well integrity.

AB - Flow of CO2 in wells is associated with substantial variations in thermophysical properties downhole, due to the coupled transient processes involved: complex flow patterns, density changes, phase transitions, and heat transfer to and from surroundings. Large temperature variations can lead to thermal stresses and subsequent loss of well integrity, and it is therefore crucial to employ models that can predict this accurately. In this work, we present a model for vertical well flow that includes both two-phase flow and heat conduction. The flow is described by a two-fluid model, where mass transfer between the phases is modelled by relaxation source terms that drive the phases towards thermodynamic equilibrium. We suggest a new formulation of the mass transfer process that satisfies the second law of thermodynamics, and that is also continuous in the single-phase limit. This provides a more robust transition from two-phase to single-phase flow than the previous formulation. The model predicts which flow regimes are present downhole, and calculates friction and heat transfer depending on this. Moreover, the flow model is coupled with a heat conduction model for the layers that comprise the well, including tubing, packer fluid, casing, cement or drilling mud, and rock formation. This enables prediction of the temperature in the well fluid and in each layer of the well. The model is applied to sudden shut-in and blowout cases of a CO2 injection well, where we employ the highly accurate Span-Wagner reference equation-of-state to describe the thermodynamics of CO2. We predict pressure, temperature and flow regimes during these cases and discuss implications for well integrity.

KW - CO injection wells

KW - Thermal modelling

KW - Two-phase flow

KW - Well integrity

U2 - 10.1016/j.ijggc.2016.05.009

DO - 10.1016/j.ijggc.2016.05.009

M3 - Journal article

AN - SCOPUS:84974720007

VL - 51

SP - 71

EP - 80

JO - International Journal of Greenhouse Gas Control

JF - International Journal of Greenhouse Gas Control

SN - 1750-5836

ER -

ID: 170017198