Cristin-prosjekt-ID: 666520
Sist endret: 2. oktober 2021, 17:54

Cristin-prosjekt-ID: 666520
Sist endret: 2. oktober 2021, 17:54
Prosjekt

Foam dynamics in the presence of oil during multiphase flow in porous rock

prosjektleder

Johan Olav Helland
ved NORCE Norwegian Research Centre AS

prosjekteier / koordinerende forskningsansvarlig enhet

  • NORCE Norwegian Research Centre AS

Finansiering

  • TotalbudsjettNOK 10.384.000
  • Norges forskningsråd
    Prosjektkode: 294886

Klassifisering

Vitenskapsdisipliner

Fysikk • Anvendt matematikk • Petroleumsteknologi

Kontaktinformasjon

Sted
Johan Olav Helland

Tidsramme

Aktivt
Start: 1. april 2019 Slutt: 31. desember 2022

Beskrivelse Beskrivelse

Tittel

Foam dynamics in the presence of oil during multiphase flow in porous rock

Vitenskapelig sammendrag

Foam injection is a promising method to increase oil recovery in mature oil
fields because it can overcome the limitations of conventional gas injection
by significantly reducing the mobility and improve sweep efficiency. It is
economic because later gas breakthrough leads to less gas production and
reduced costs related to gas recycling and re-injection. Reservoir simulation
models describe foam behaviour with parameters that are difficult to measure
in core-flooding experiments. For example, foam mobility depends on gas
bubble density, which changes through bubble generation and coalescence
events on the pore scale. A further complication is that foam mechanisms
and film stability generally are different in the presence of oil, as shown
in experiments. Thus, reservoir simulators rely heavily on fitting foam
parameters to core-scale floods before their use. In this project, we will
develop and use mathematical methods to investigate multiphase foam flow
on the pore scale with a detailed description of the mechanisms for foam film
stability and rupture. The project will conduct new pore-scale micromodel
experiments to validate and calibrate the modelling approach. We will
use the developed methods on segmented 3D rock images to understand
and quantify the effect of oil on foam flow in porous rock. Efforts to model
foam with oil present on pore scale are missing in the scientific literature,
yet it is an essential part to improve our understanding of foam and make
reservoir simulations with foam reliable. From pore-scale simulations, we
will determine foam stability and texture, foam generation and coalescence rates, trapped gas fractions, limiting capillary pressure for foam coalescence,
relative permeability curves, and hysteresis effects, to investigate foam
mobility reduction with and without oil present. The outcome will be a better
understanding of foam dynamics in porous rock, which allows a more
accurate foam representation in reservoir simulations.
 

prosjektdeltakere

prosjektleder

Johan Olav Helland

  • Tilknyttet:
    Prosjektleder
    ved NORCE Norwegian Research Centre AS

Espen Jettestuen

  • Tilknyttet:
    Prosjektdeltaker
    ved NORCE Norwegian Research Centre AS

Helmer André Friis

  • Tilknyttet:
    Prosjektdeltaker
    ved NORCE Norwegian Research Centre AS
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Resultater Resultater

Pore-Scale CO2-Foam Texture at Reservoir Pressure.

Benali, Benyamine; Alcorn, Zachary Paul; Fernø, Martin. 2021, Microfluidics & Energy symposium. UIBPoster

A level set approach to Ostwald ripening of real gases in porous media.

Singh, Deepak; Friis, Helmer Andre`; Jettestuen, Espen; Helland, Johan Olav. 2021, InterPore2021 - 13th International Conference on Porous Media. NORCE, UISVitenskapelig foredrag

A Discrete-Domain Approach to Three-Phase Hysteresis in Porous Media.

Helland, Johan Olav; Jettestuen, Espen; Friis, Helmer Andre`. 2021, Water Resources Research. NORCEVitenskapelig artikkel

A locally conservative multiphase level set method for capillary-controlled displacements in porous media.

Jettestuen, Espen; Friis, Helmer Andre`; Helland, Johan Olav. 2021, Journal of Computational Physics. NORCEVitenskapelig artikkel

Pore-and core-scale insights of nanoparticle-stabilized foam for CO2-enhanced oil recovery.

Alcorn, Zachary Paul; Føyen, Tore Lyngås; Gauteplass, Jarand; Benali, Benyamine; Soyke, Aleksandra; Fernø, Martin. 2020, Nanomaterials. SINTEF, UIBVitenskapelig artikkel
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