Difference between revisions of "Hydrodynamic influence on trapping"

	Exploring for Oil and Gas Traps
Series	Treatise in Petroleum Geology
Part	Critical elements of the petroleum system
Chapter	Formation fluid pressure and its application
Author	Edward A. Beaumont, Forrest Fiedler
Link	Web page
Store	AAPG Store

Revision as of 21:26, 13 October 2014

Hydrodynamic influence on trapping

Potential of water vs. hydrocarbons

Fluid pressure equals pgH. Under hydrostatic conditions, the buoyant force equals

\rho _{\rm {w}}{\mbox{gH}}_{\rm {w}}-\rho _{\rm {h}}{\mbox{gH}}_{\rm {h}}

where:

ρ_w = water density
ρ_h = hydrocarbon density
H_w = water depth
H_h = hydrocarbon column height

Under hydrodynamic conditions, the potential for a hydrocarbon column (Φ_h) is related to the potential of the water by the equation

\Phi _{\rm {h}}=\rho _{\rm {h}}{\mbox{gH}}_{\rm {h}}=\rho _{\rm {w}}{\mbox{gH}}_{\rm {w}}-(\rho _{\rm {w}}-\rho _{\rm {h}}){\mbox{gZ}}

Dividing through by g (ρ_w – ρ_h)/ρ_h to simplify gives (in a uniformly flat gravity field)

\left({\frac {\rho _{\rm {h}}}{\rho _{\rm {w}}-\rho _{\rm {h}}}}\right){\mbox{H}}_{\rm {h}}=\left({\frac {\rho _{\rm {w}}}{\rho _{\rm {w}}-\rho _{\rm {h}}}}\right){\mbox{H}}_{\rm {w}}-{\mbox{Z}}

Constant values for the left-hand side of the equation are equipotential surfaces for hydrocarbons. Hubbert^[1] called this factor U. From the right side, constant values for ρ_w/(ρ_w – ρ_h)H_w are equipotential surfaces for water. Hubbert called this factor V. The elevation factor (Z) is the difference between the equipotential surfaces for hydrocarbons and water.

Substituting U and V in the above equation gives

{\mbox{U}}={\mbox{V}}-{\mbox{Z}}

Fluid flow is perpendicular to equipotential surfaces.

Hydrodynamic effect on traps

Figure 1 Vectors and equipotential lines for a hydrocarbon accumulation in an anticline in a hydrodynamic environment. Modified. Copyright: North;^[2] courtesy Allen and Unwin.

In a hydrostatic environment, the free-water level of a trap is horizontal. In a hydrodynamic environment, the free-water level of a trap is tilted because the buoyant force (P_b) is interfered with by the hydrodynamic force (P_w). The resultant interference is the vector known as the confining force (P_cf). U, an equipotential line, is perpendicular to P_cf and is tilted because of the effect of P_w. The diagram in Figure 1 shows these vectors and the equipotential lines for a hydrocarbon accumulation in an anticline in a hydrodynamic environment.

References

↑ Hubbert, K., 1953, Entrapment of petroleum under hydrodynamic conditions: AAPG Bulletin, vol. 37, no. 8, p. 1954–2026. The original paper that proposed hydrodynamics as an important trapping mechanism.
↑ North, F. K., 1985, Petroleum Geology: London, Allen & Unwin, 246 p.

External links

find literature about
Hydrodynamic influence on trapping

[ch05r11-1] Hubbert, K., 1953, Entrapment of petroleum under hydrodynamic conditions: AAPG Bulletin, vol. 37, no. 8, p. 1954–2026. The original paper that proposed hydrodynamics as an important trapping mechanism.

[North1985-2] North, F. K., 1985, Petroleum Geology: London, Allen & Unwin, 246 p.

[1]

[2]

@@ Line 25: / Line 25: @@
 * ρ<sub>w</sub> = water density
-* ρ<sub>h</sub> = hydrocarbon density
+* ρ<sub>h</sub> = [[hydrocarbon]] density
 * H<sub>w</sub> = water depth
 * H<sub>h</sub> = hydrocarbon column height
@@ Line 37: / Line 37: @@
 :<math>\left(\frac{\rho_{\rm h}}{\rho_{\rm w} - \rho_{\rm h}}\right) \mbox{H}_{\rm h} = \left(\frac{\rho_{\rm w}}{\rho_{\rm w} - \rho_{\rm h}}\right)\mbox{H}_{\rm w} - \mbox{Z}</math>
-Constant values for the left-hand side of the equation are equipotential surfaces for hydrocarbons. Hubbert<ref name=ch05r11>Hubbert, K., 1953, [http://archives.datapages.com/data/bulletns/1953-56/data/pg/0037/0008/1950/1954.htm Entrapment of petroleum under hydrodynamic conditions]: AAPG Bulletin, vol. 37, no. 8, p. 1954–2026. The original paper that proposed hydrodynamics as an important trapping mechanism.</ref> called this factor U. From the right side, constant values for ρ<sub>w</sub>/(ρ<sub>w</sub> – ρ<sub>h</sub>)H<sub>w</sub> are equipotential surfaces for water. Hubbert called this factor V. The elevation factor (Z) is the difference between the equipotential surfaces for hydrocarbons and water.
+Constant values for the left-hand side of the equation are [[Wikipedia:Equipotential|equipotential]] surfaces for hydrocarbons. Hubbert<ref name=ch05r11>Hubbert, K., 1953, [http://archives.datapages.com/data/bulletns/1953-56/data/pg/0037/0008/1950/1954.htm Entrapment of petroleum under hydrodynamic conditions]: AAPG Bulletin, vol. 37, no. 8, p. 1954–2026. The original paper that proposed hydrodynamics as an important trapping mechanism.</ref> called this factor U. From the right side, constant values for ρ<sub>w</sub>/(ρ<sub>w</sub> – ρ<sub>h</sub>)H<sub>w</sub> are equipotential surfaces for water. Hubbert called this factor V. The elevation factor (Z) is the difference between the equipotential surfaces for hydrocarbons and water.
 Substituting U and V in the above equation gives

Difference between revisions of "Hydrodynamic influence on trapping"

Revision as of 21:26, 13 October 2014

Contents

Hydrodynamic influence on trapping

Potential of water vs. hydrocarbons

Hydrodynamic effect on traps

See also

References

External links

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