Estimated Ultimate Recovery
Natural Depletion
(1) | EUR = \frac{Q_o}{V_o} = \frac{ (p_i - p_{wf \, min}) \, c_t}{(1-s_{wi})\, B_o} = \frac{ (p_i - p_{wf \, min}) }{(1-s_{wi})\, B_o} \, \big( c_r + s_{wi} c_w + (1-s_{wi})c_o \big) |
Water flooding
Motivation = maintain formation pressure at sweep interface
(9) | EUR = E_S \, E_D = E_{SV} \, E_{SH} \, E_D |
Sweep effciency
Total sweep | Areal sweep | Vertical sweep | ||||||
---|---|---|---|---|---|---|---|---|
|
|
| ||||||
V_{sweep} – sweep volume V_\phi – pore volume | A_{sweep} – sweep area A_\phi – pore area | h_{sweep} – sweep thickness h_\phi – pore thickness |
Water displacement efficiency
(13) | E_D = \frac{1-s_{wi}-s_{orw}}{1-s_{wi})} |
Gas flooding
Motivation = maintain formation pressure at sweep interface with gas in case of high water mobility \frac{k_{rw}}{\mu_w} \gg \frac{k_{ro}}{\mu_o} which makes watrflood inefficient.
Gas displacement efficiency
(14) | E_D = \frac{1-s_{wi}-s_{org}}{1-s_{wi})} |
WAG flooding
Motivation = maintain formation pressure at sweep interface with alternating inejction of water and gas in case of high residual oil to water sweep is high s_{orw} and gas sweep is less than to water sweep s_{org} < s_{orw}.
(15) | E_D = \frac{1-s_{wi}-s_{org}}{1-s_{wi})} |
Chemical EOR
Motivation = maintain formation pressure at sweep interface with chemical injection and reduce residual oil to EOR sweep s_{or \, eor} < s_{orw}.
(16) | E_D = \frac{1-s_{wi}-s_{or \, eor}}{1-s_{wi})} |
CО2 injection
Reference
[1]