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Revision as of 10:23, 12 September 2018

Contents

1 Brief
2 Math & Physics
3 Diff eq
4 See also
5 Nomenclature
- 5.1 Greek symbols

Brief

Stimulated well drainage

6/π is the maximum possible stimulation potential for pseudo steady state linear flow in a square well spacing.

Math & Physics

Pseudo steady state flow boundary conditions:

P |_{x=x_e/2} = P |_{x=-x_e/2} = 0

\frac{dP}{dt} =const\ for \ \forall x

From Diffusivity Equation:

\frac{d^2P}{dx^2}=\frac{\phi c \mu}{k} \frac{dP}{dt}

( 1 )

From Darcy's law:

\frac{q}{2}=\frac{kA}{\mu}\ \frac{dP}{dx}

A =y_e*h

From Material Balance:

q/2 =\frac{dV}{dt}

V =y_e*h*x_e/2*\phi

c=-\frac{1}{V} \frac{dV}{dP}

\frac{dP}{dt} = -\frac{q}{2 c y_e h \phi} \frac{2}{x_e}

( 2 )

( 2 ) - > ( 1 ) :

\frac{d^2P}{dx^2}=- \frac{q \mu}{2 k y_e h} \frac{2}{x_e}

( 3 )

Integrating ( 3 ):

\frac{dP}{dx}=- \frac{q \mu}{2 k y_e h} \frac{2}{x_e} x + c_1

( 3 )

c_1

must satisfy boundary condition:

c_1 = \frac{q \mu}{2 k y_e h}

\frac{dP}{dx}=- \frac{q \mu}{k x_e y_e h} \left ( x- \frac{x_e}{2} \right )

( 4 )

Integrating ( 4 ):

P - P_{wf} = - \frac{q \mu}{k x_e y_e h} \left ( \frac{x^2}{2} - \frac{x x_e}{2} \right )

( 5 )

Since average pressure is: $\bar P = \frac{\int P dx}{\int dx}$ :

\bar P = \frac{ \int \limits_{0}^{x_e/2} \left ( - \frac{q \mu}{k x_e y_e h} \left ( \frac{x^2}{2} - \frac{x x_e}{2} \right ) + P_{wf} \right ) dx}{\int \limits_{0}^{x_e/2}dx} = - \frac{q \mu}{2 k x_e y_e h} \left. \frac{\frac{x^3}{3} - x_e \frac{x^2}{2}}{x} \right|_{x=0}^{x=x_e/2} + P_{wf}

\bar P - P_{wf} = - \frac{q \mu}{2 k x_e y_e h} \frac{\frac{1}{3} \frac{x_e^3}{8} -\frac{1}{2} \frac{x_e^3}{4}}{\frac{x_e}{2}} = - \frac{q \mu}{12 k h} \frac{x_e}{y_e}

J_D=\frac{q \mu}{2 \pi k h} \frac{1}{( \bar P - P_{wf})} =\frac{q \mu}{2 \pi k h} \frac{12 k h}{q \mu} \frac{y_e}{x_e} = \frac{6 y_e}{\pi x_e}=\frac{6}{\pi}

Diff eq

From Mass conservation:

\frac{d(\rho q)}{2 dx}=y_e h \phi \frac{d\rho}{dt}

( 1 )

From Darcy's law:

\frac{q}{2}=\frac{kA}{\mu}\ \frac{dP}{dx}

( 2 )

A =y_e*h

( 2 ) →( 1 ):

\frac{d}{dx} \left ( \frac{\rho k y_e h}{\mu} \frac{dP}{dx} \right )=y_e h \phi \frac{d\rho}{dt}

( 3 )

\frac{d}{dx} \left ( \frac{k \rho}{\mu} \frac{dP}{dx} \right )=\phi \frac{d\rho}{dt}

( 4 )

c=\frac{1}{\rho} \frac{d \rho}{dP}

( 5 )

( 5 ) -> ( 4 ):

\frac{d}{dx} \left ( \frac{k \rho}{\mu} \frac{dP}{dx} \right )=\phi c \rho \frac{dP}{dt}

( 6 )

\frac{d}{dx} \left ( \frac{k}{\mu} \right ) \rho \frac{dP}{dx} + \frac{k}{\mu} \left ( \frac{d \rho}{dx} \right ) \frac{dP}{dx} + \frac{k \rho}{\mu} \frac{d^2P}{dx^2}=\phi c \rho \frac{dP}{dt}

( 7 )

Assumption that viscosity is constant cancels out first term in left hand side of (7):

\frac{k}{\mu} \left ( \frac{d \rho}{dx} \right ) \frac{dP}{dx} + \frac{k \rho}{\mu} \frac{d^2P}{dx^2}=\phi c \rho \frac{dP}{dt}

( 8 )

\frac{d \rho}{dx} = c \rho \frac{d P}{dx}

( 9 )

( 9 ) -> ( 8 ):

\frac{k}{\mu} c \rho \left ( \frac{dP}{dx} \right )^2+ \frac{k \rho}{\mu} \frac{d^2P}{dx^2}=\phi c \rho \frac{dP}{dt}

( 10 )

Term $\left ( \frac{dP}{dx} \right )^2$ in (10) is second order of magnitude low and can be cancelled out, which yields:

\frac{d^2P}{dx^2}=\frac{\phi c \mu}{k} \frac{dP}{dt}

( 11 )

See also

optiFrac
fracDesign
Production Potential

Nomenclature

A

= cross-sectional area, cm2

h

= thickness, m

k

= permeability, d

P

= pressure, atm

P_i

= initial pressure, atm

\bar P

= average pressure, atm

q

= flow rate, cm³/sec

x

= length, m

x_e

= drinage area length, m

y_e

= drinage area width, m

Greek symbols

\mu

= oil viscosity, cp

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