MATERIAL BALANCE EQUATION FOR CO2 INJECTION IN ABNORMAL PRESSURE (SUBSIDENCE) GAS RESERVOIR
Reservoir performance and storage capacity are two crucial factors that must be estimated before conducting CO2 injection in the Carbon Capture and Storage (CCS) process. These factors can be estimated using a Material Balance equation for injection. The currently available Material Balance equat...
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| Format: | Theses |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/83266 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Reservoir performance and storage capacity are two crucial factors that must be
estimated before conducting CO2 injection in the Carbon Capture and Storage
(CCS) process. These factors can be estimated using a Material Balance equation
for injection. The currently available Material Balance equation for CO2 injection
is designed for injection into depleted normal pressure gas reservoirs. In this study,
an Material Balance equation for CO2 injection into depleted abnormal pressure
gas reservoirs was developed. Unlike the Material Balance equation for depleted
normal pressure gas reservoirs, which have a constant Hydrocarbon Pore Volume
(HCPV), the HCPV in depleted abnormal pressure gas reservoirs will change due
to pressure variations during CO2 injection, necessitating a new Material Balance
equation. The change in HCPV during injection can be expressed as a function of
cumulative effective compressibility defined by Fetkovich, where this value can be
calculated using production data with the Gan and Blasingame model. Several
testing stages were conducted on the new Material Balance equation before CO2
injection simulation, including comparison with the Material Balance equation for
injection into depleted normal pressure gas reservoirs, and testing by injecting the
same gas as produced in Field X. The test results showed that the model we
developed can mathematically transform into the existing model if HCPV is
considered constant during production. Additionally, it was found that if the
reservoir is reversible, the reservoir performance during injection of the same gas
as produced is the same as the reservoir performance during production.
In the CO2 injection simulation in Field X, a depleted abnormal pressure gas
reservoir, it was found that the storage capacity of Field X for CO2 injection is
larger compared to the total gas produced from the field. We also found that
reservoir performance and the total amount of CO2 that can be injected are highly
dependent on the compressibility of the gas mixture during injection. Based on the
simulation, it is known that storage capacity depends only on the initial HCPV
before production and the gas mixture composition after injection, so for the same
initial HCPV, depleted abnormal pressure gas reservoirs and depleted normal
pressure gas reservoirs will have the same storage capacity. |
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