According to the Joukowski transformation, the elliptical area with the major half-axis of a and minor half-axis of b can be transformed into a circular area with a radius of (a+b) and well diameter of 0.5 L. According to the Darcy formula, the production at steady state is as follows: v n = ( q 1 B o 2 π r ) n = k μ e f f d p d r , (3) where Bo is the oil volume factor and q ₁ is the inner zone production, m³/d.

Equation 4 is obtained by transforming Eq. 3: ∫ 0 . 5 L a + b ( q 1 B o 2 π ) n 1 r n d r = k μ e f f ∫ p w p e d p . (4)

Integrating Eq. 4 can get the following equation: q 1 n = k ( p e − p w ) μ e f f ( B o 2 π ) n 1 1 − n [ ( a + b ) 1 − n − ( 0.5 L ) 1 − n ] . (5)

Based on Eq. 5, the outer zone productivity formula is given by the following formula: q H n = ( q 1 ⋅ h ) n = k ( p e − p w ) μ e f f ( B o 2 π h ) n 1 1 − n [ ( a + b ) 1 − n − ( 0.5 L ) 1 − n ] . (6)

Then, the seepage resistance of the outer zone is given by the following equation: R fH = Δ p q H = Δ p { k ( p e − p w ) μ e f f ( B o 2 π h ) n 1 1 − n [ ( a + b ) 1 − n − ( 0.5 L ) 1 − n ] } 1 n . (7)

By the transformation of ξ = ( 1 - e − π z h ) × ( 1 - e π z h ) , the inner zone is equal to a unit circle region on the ξ plane, the well eccentricity is changed to d, where d = 2 σ h . The radius of the wellbore is transformed to ξ w = 2 r w h .

Based on η = ξ - ξ 0 1 - ξ 0 ¯ ξ , it is transformed into a unit circle with a well located at the origin of coordinates. On the η plane, the well radius is ρ w = ξ w 1 − d 2 = 2 r w / h 1 − ( 2 σ / h ) 2 .

The productivity formula of the inner zone is given by the following equation: q H n = ( q 1 ⋅ L ) n = k ( p e − p w ) μ e f f ( B o 2 π L ) n 1 1 − n ( 1 − ρ w 1 − n ) . (8)

Then the seepage resistance in the inner zone is given by the equation: R fV = Δ p q V = Δ p { k ( p e − p w ) μ e f f ( B o 2 π L ) n 1 1 − n [ 1 − ρ w 1 − n ] } 1 n . (9)

According to the principle of equivalent seepage resistance, the production of the horizontal well can be written as follows: Q H = Δ p R fH + R fV = 1 { k ( p e − p w ) μ e f f ( B o 2 π h ) n 1 1 − n [ ( a + b ) 1 − n − ( 0.5 L ) 1 − n ] } − 1 n + { k ( p e − p w ) μ e f f ( B o 2 π L ) n 1 1 − n [ 1 − ρ w 1 − n ] } − 1 n . (10)

The following equation can be obtained after the simplification of Eq. 10: Q H = [ k ( p e − p w ) μ e f f ( B o 2 π h ) n ] 1 n { 1 1 − n [ ( a + b ) 1 − n − ( 0.5 L ) 1 − n ] } 1 n + { ( h L ) n 1 1 − n { 1 − ( 2 r w / h 1 − ( 2 σ / h ) 2 ) 1 − n ] } 1 n . (11)

Considering the reservoir anisotropy, h is changed to βh according to the Muskat correction method,where β = K h K V .

Then, Eq. 11 is transformed to Eq. 12 as follows: Q H = [ K h K V ( p e − p w ) μ e f f ( B o 2 π β h ) n ] 1 n { 1 1 − n [ ( a + b ) 1 − n − ( 0.5 L ) 1 − n ] } 1 n + { ( β h L ) n 1 1 − n [ 1 − ( 2 r w / β h 1 − ( 2 σ / β h ) 2 ) 1 − n ] } 1 n . (12)

The horizontal well production under different power-law indices is studied by changing the power-law indices. Figures 2, 3 show the influence of the power-law index on horizontal well production under different horizontal well lengths and different production pressure differences, respectively.

As can be seen from Figures 2, 3, for horizontal wells of a certain length, production increases with the increase of the power-law index. When the power-law index is less than 0.8, production increases slowly; after the power-law index reaches a value greater than 0.8, production rapidly increases. The longer the horizontal well, the higher the production and the greater the increase of production with the power-law index. The larger the production pressure difference, the higher the production, and the influence of the power-law index on the production is more obvious.

The effect of anisotropy on horizontal well production was studied by changing the ratio of horizontal permeability to vertical permeability. Figures 4, 5 show the effects of anisotropy on production under different power-law indices and different horizontal well lengths, respectively.

It can be seen from Figures 4, 5 that anisotropy has a great influence on the production of horizontal wells. With the increase of anisotropy, that is, when the K_h/K_v ratio increases, the production of horizontal wells decreases. When K_h/K_v is less than 10, the production decreases rapidly, and after K_h/K_v is more than 10, the production decreases slowly. The effect of anisotropy on production is related to the power-law index and horizontal well length. With the increase of power-law index and horizontal well length, the horizontal well production decreases more with the increase of anisotropy and is more sensitive to anisotropy.

The influence of eccentricity on horizontal well production is studied by changing the magnitude of eccentricity σ. The eccentric factor λ is defined as λ = σ/(H ⁄2) (Liu et al., 2019). The eccentric factor is proportional to eccentricity; the greater the eccentricity, the greater the eccentricity factor. Figures 6, 7, show the influence of eccentricity on production under different power-law indices and different horizontal well lengths, respectively.

It can be seen from Figures 6, 7 that when the value of eccentricity factor is changed, the production of horizontal wells with different power-law indices and different horizontal well lengths basically does not change, indicating that eccentricity has little influence on the production of horizontal wells in power-law fluid heavy oil reservoirs and therefore can be ignored in production calculation.