1) The Equivalent Grain Size (EGS) method provides a way to assess seal capacity for carbon capture and storage based on the relationship between pore throat size and fluid column height.
2) Case studies have shown that the height of a CO2-gas column injected into a reservoir is controlled by the seal's EGS, with a higher EGS allowing a taller fluid column before reaching hydrostatic equilibrium.
3) Application of the EGS method to a gas field in East Java, Indonesia indicated that CO2 could safely be injected and stored in the carbonate reef reservoir due to the seal's estimated EGS and separation from the main reservoir by facies changes.
Equivalent Grain Size Method for Sealing Capacity in CCS
1. Equivalent Grain Size Method for
Sealing Capacity Assessment in CCS
Yohanes Nuwara 1, Kazuo Nakayama 2, Kevyn Augusta 1
1 Department of Geophysics, Bandung Institute of
Technology
2 GeoResearch Nakayama
2. Outline
● Motivation
● Geological overview of EGS
● Physics overview of EGS
● The use of EGS in CCS
● Workflow of EGS
● Case study in East Java Basin
● Lesson learned
3. Motivation: WHY do we need this? Seal integrity matters.
https://sequestration.mit.edu/tools/projects/in_salah.html
Injection started in 2004 and injection
suspended in 2011 due to concerns
about the integrity of the seal. During
the project lifetime 3.8MT/CO2 was
successfully stored in the Krechba
Formation. No leakage of CO2 was
reported during the lifetime of the project.
In Salah CCS Project (Algeria)
4. Type of Traps controlled by Geological Settings
1. Capillary-limited Traps 2. Spill-point Traps
5. Type of traps controlled by Physics (Capillary vs Spill-
point)
7. Hydrostatic Equilibrium
Pc = Pb
(2⋅γ⋅cosθ)/R = g⋅Hc⋅(ρw-ρh)
Hc = {(2⋅γ⋅cosθ)/R} / {g⋅(ρw-ρh)}
Capillary pressure Buoyancy pressure
Fluid column height
Fluid column height
is controlled by pore
throat radius
Hc = f (R)
8. Experiments shows relation between porosity and EGS
R = 0.5 ⋅ EGS⋅ (aΦ2 + bΦ)
Since and we know Hc = f (R) therefore Hc = f (EGS)
Sawamura and Nakayama (2005)
9. EGS is originally used for oil and gas knowledge
● Estimate seal capacity
● Predict types and height of each fluid
column in pre-drilling stage
● Explain oil and gas distribution and
accumulation
Case Study: Field in Sakhalin
Nakayama presentation in FGI (2019)
A
B
A B
EGS = 9.7 phi
12. Case Study: East Java Basin, Indonesia
● A gas producer field since 2001
● 21% CO2 in gas will be reduced
● The first CCS pilot project in Indonesia
● Vast carbonate reef reservoir for CO2 storage
Purwaningsih (2002)
14. Interpreted Gas-CO2 Column based on EGS
Due to facies separation from the main reef
and slope margin, CO2 is less likely to leak
through spill point
15. Conclusion
● Hydrostatic equilibrium between capillary pressure and buoyancy pressure
keeps CO2-gas from leaking on the top of structure
● CO2-gas column height is controlled by seal equivalent grain size: Hc = f
(EGS)
● Knowing the maximum column height of CO2, we know how much CO2 can
be injected
● Knowing the capillary pressure at hydrostatic equilibrium, we know the limit of
injection pressure
● Both are needed to be known to prevent CO2 leaking through the seal
16. Recommended Reading
● EGS original paper in AAPG Memoir: Sawamura, F. and K. Nakayama.
[2005] Estimating the amount of oil and gas accumulation from top seal and
trap geometry, in R. Sorkhabi and Y. Tsuji, eds., Fault and fluid flow, and
petroleum traps, AAPG Memoir 85, 33-42.
● Geology and simulation of CCS in this location: Nuwara, Y. [2020] Integration
of Reservoir. Rock Physics, Seismic, and Geomechanical Modelling for CO2
Injection in Carbonate Reef reservoir, EAGE 82nd Annual Conference and
Exhibition.
17. Acknowledgment
Thanks to JGI, Inc., where Dr. Kazuo Nakayama had worked for in the past year,
for providing access to their EGS “SeaCap” Excel Spreadsheet
18. Thank you for attending!
See you Q & A session on August
25