(1) | \sigma_f = s_w \cdot \sigma_w(T) + s_o \cdot \sigma_o(T) + s_g \cdot \sigma_g(T) |
where
s_w, \, s_o, \, s_g | volumetric fractions of water, oil and gas phases: s_w + s_o + s_g = 1 |
\sigma_w(T), \, \sigma_o(T), \, \sigma_g(T) | electrical conductivity of the water, oil and gas phases |
T | fluid temperature |
In many practical applications the electrical conductivity of hydrocarbons is much less than that of produced water \sigma_w(T) \gg \sigma_o(T) \gg \sigma_g(T) so that (1) can be approximated as:
(2) | \sigma_f \approx s_w \cdot \sigma_w(T) |
See Also
Petroleum Industry / Upstream / Data Acquisition / Well & Reservoir Surveillance / Well logging / Cased-Hole Logging / Production Logging (PLT) / Borehole Flow Profile (BFP) / Fluid Conductivity Log (FCOND)