The first assumption of CRM is that productivity index of producers stays constant in time: LaTeX Math Block |
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| J = \frac{q_{\uparrow}(t)}{p_r(t) - p_{wf}(t)} = \rm const |
which can re-written as explicit formula for formation pressure: LaTeX Math Block |
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| p_r(t) = p_{wf}(t) + J^{-1} q_{\uparrow}(t) |
The second assumption is that drainage volume of producers-injectors system is finite and constant in time: LaTeX Math Block |
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| V_\phi = V_{rocks} \phi = \rm const |
The third assumption is that total formation-fluid compressibility stays constant in time: LaTeX Math Block |
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| c_t \equiv \frac{1}{V_{\phi}} \cdot \frac{dV_{\phi}}{dp} = \frac{1}{V_{\phi}} \cdot \frac{1}{p_i - p_r(t) } \cdot \Bigg[ \int_0^t q_{\uparrow}(\tau) d\tau - f \int_0^t q_{\downarrow}(\tau) d\tau \Bigg] = \rm const |
where – field-average initial formation pressure, – field-average formation pressure at time moment ,
The last equation can be rewritten as: LaTeX Math Block |
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| \int_0^t q_{\uparrow}(\tau) d\tau - f \int_0^t q_{\downarrow}(\tau) d\tau = c_t \, V_\phi \, [p_i - p_r(t)] |
and differentiated LaTeX Math Block |
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| q_{\uparrow}(\tau) d\tau - f q_{\downarrow}(\tau) d\tau = - c_t \, V_\phi \, \frac{d p_r(t)}{d t} |
and substituting from productivity equation LaTeX Math Block Reference |
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| : LaTeX Math Block |
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| q_{\uparrow}(\tau) d\tau - f q_{\downarrow}(\tau) d\tau = - c_t \, V_\phi \, \bigg[ \frac{d p_{wf}(t)}{d t} + J^{-1} \frac{d q_{\uparrow}}{d t} \bigg] |
which leads to LaTeX Math Block Reference |
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