Theme 6: INTEGRATION OF STRUCTURAL DATA AND RESERVOIR MODELS - PowerPoint PPT Presentation

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Theme 6: INTEGRATION OF STRUCTURAL DATA AND RESERVOIR MODELS

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Reservoir models of entire field ( full-field') or part of a field ... Flow across a fault in reservoir models follows Darcy flow: The rate for linear flow is: ... – PowerPoint PPT presentation

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Title: Theme 6: INTEGRATION OF STRUCTURAL DATA AND RESERVOIR MODELS


1
Theme 6INTEGRATION OF STRUCTURAL DATA AND
RESERVOIR MODELS
2
Basis of fault modeling in reservoir simulations
  • Reservoir models of entire field (full-field)
    or part of a field (sector)
  • Faults considered as single plane
  • Modelled flow path as part of cross-cell flow
    calculation
  • Use modifiers of transmissibility between cells

3
Manzocchi et al. (2002)
4
Fault zone transmissibility
Fault Rock Thickness
Fault Rock Permeability
Transmissibility (Perm x Fault rock
thickness) Hydraulic Resistance (Fault rock
thickness / Perm)
Matrix Properties Cell Size
5
Transmissibility multipliersand flow modeling
Only Cross-fault cells used - No along fault
flow considered. - No Threshold Capillary
Pressure considered.
Separate cells for faults allows along fault flow
evaluation.
6
Fault zone hydraulic resistance
  • Flow across a fault in reservoir models follows
    Darcy flow
  • The rate for linear flow is
  • q (k/L) (A/h) (f1 - f2)
  • For a given cross-sectional area, A, across the
    fault and a constant pressure gradient and fluid
    viscosity, the flow rate is dependent on the
    fault zone hydraulic resistance or, (k/L), where
    L is the fault rock thickness.

7
Transmissibility no fault
  • Fault zone properties are introduced into
    reservoir models as transmissibility multipliers.
  • Average permeability for flow between adjoining
    cells with no fault is
  • k undeformed L / (0.5L1/ k1) (0.5L2/ k2)
  • And transmissibility (T trans) is K undeformed /L

No fault
8
Fault transmissibility with fault
  • Average permeability for flow between adjoining
    cells with a fault is
  • k faulted L / 0.5 (L1 - Lf) / k1 0.5 (L2 -
    Lf) / k2 Lf / kf

With fault
9
Transmissibility multiplier - T
  • Transmissibility with a fault is altered by
    transmissibility multiplier, T
  • Ttrans T (kundeformed/L)
  • for no fault T1 and for a completely sealing
    fault T0
  • The transmissibility multiplier is the ratio of
    the faulted permeability to the undeformed
    permeability that is
  • T kfaulted/kundeformed

This is the key relationship introduced into
reservoir models.
10
Transmissibility multiplier - T
  • The transmissibility multiplier is
  • T kfaulted/kundeformed
  • where,
  • k faulted L / 0.5 (L1 - Lf) / k1 0.5 (L2
    - Lf) / k2 Lf / kf
  • is a function of the fault permeability, kf and
    fault rock thickness, Lf.
  • The fault rock thickness is associated with the
    fault throw, Lf.

11
Fault rock thickness
Fault rock thickness scales with fault
displacement
12
Manzocchi et al. (2002)
13
Fault rock permeability vs. clay content
14
Fault Zone Flow
Transmissibility depends on cell size
15
Fault Zone Flow
Transmissibility depends on cell size
16
Fault Rock Prediction Heidrun field
Knai Knipe (1998)
17
Fault rock thickness
Geocellular models for reservoir modeling
18
Fault rock permeability
Geocellular reservoir models
Geologists provide reservoir engineers input
along faults for modeling.
19
Threshold Pressures and Flow Modeling
Constant Fault Rock Properties
P gt Pth Fault leaks
Sealing Capacity
P lt Pth Fault seals No Flow. Permeability based Tr
ansmissibility not applicable, Water filled fault.
Base Hydrocarbon
20
Fault zone flow effectiveness
  • Fault zone complexity cannot be explicitly
    modelled in current reservoir simulators.
  • Capture essential details by determining
    effective fault rock thickness.
  • Minimise fault rock thickness on all pathways -
    assumed to be most efficient flow path.

21
Cumulative fault rock thickness
Cataclastic faults in porous sandstones build up
cumulative fault rock thickness
22
Fault Transmissibility Assessment
23
Fault transmissibility evaluation workflow
1. Define number of faults crossed along critical
flow paths through fault zones by-passed ?
2. Define total thickness of fault rocks present
along the critical flow path
4. Calculate the effective transmissibilities,
and threshold pressures of fault zones
3. Define permeabilities and threshold pressures
of the different fault rocks along pathways
24
Complex fault modelling
  • Study impact of 3D spatially distributed faults
    on flow properties of complex fault zones.
  • Analyse tortuosity and connectivity in terms of
    fault zone geometry.
  • Analyse spatial clustering techniques (core,
    outcrop seismic scale).
  • Model influences of host rock and fault rock
    permeability ratio.
  • Results accessible to reservoir simulation
    packages - fault rock thickness, transmissibility
    multipliers.

25
Model attributes
  • Position, length, width, strike, dip, aspect
    ratio
  • Clustering technique hierarchical
  • Throwthickness and throwlength ratios
  • BASIC ASSUMPTIONS
  • Fault lengths are members of power law
    size-frequency distribution
  • Faults elliptical and planar orientation
    unrestricted
  • Damage zone of clustered faults around major
    faults

26
A Two-Dimensional Illustration
27
Collapsed Fault Rock Thickness
  • Hierarchical Clustering Technique

28
Two-Dimensional Horizontal Slices
  • Hierarchical Clustering Technique

Fault Spacing Along 1D Traverse
29
Modelled Volume of Interest
30
Controls on Pathway Length and Fault Rock
Thickness
  • Direct Path (low frequency) Low connectivity of
    fault array, low fault rock thickness.
  • Tortuous Path (medium frequency) Increased
    connectivity, long pathways, low fault rock
    thickness.
  • Direct Path (higher frequency) Effective
    barriers, low tortuosity pathways, significant
    increase in fault rock thickness.

31
Impact of permeability ratio of host rock and
fault rock
  • Permeability ratio controls host rock pathway
    lengths which can be traversed before faults are
    crossed.
  • Modelled by adding a background value to each
    cell in addition to fault rock thickness values.

32
Transmissibility Multiplier
  • Permeability ratio ? 3334
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