Advanced Facies Modelling Presentation PDF

Summary

This presentation discusses advanced facies modelling techniques in Roxar RMS, including pixel-based and object-based methods, petrophysical modelling, and facies analysis. The presentation includes details on different techniques, considerations, and methods to create realistic reservoir models.

Full Transcript

Advanced Property
Modelling in Roxar RMS
Advanced Facies Modelling
Petronas Roxar Academy 2016

Ruslan Nasibullin
Senior Geologist Roxar Software Solutions AP

www.roxarsoftware.com

RMS Facies Modelling Techniques
Pixel based methods
Transitional facies
Fluvial facies (same OWC’s)
Carbonates
Delta
Regional heterogeneity

Object based methods
Channels & Levee
Fluvial facies (different OWC’s)
Carbonates
Turbidities

Emerson Confidential • 4/30/2018 • Slide 7

RMS Petrophysical Modelling Techniques
Deterministic Methods
Quick & Simple Models
Interpolation Algorithm
Trend Modelling

Stochastic Methods
Realistic 3D Models
Facies Heterogeneity
Random samples of
probabilistic descriptions

Emerson Confidential • 4/30/2018 • Slide 9

RMS Facies Modelling Methods
Facies:
Belts

Facies:
Indicators
Pixel-based methods

- F*: Facies proportions

- VPC
- F: Facies proportions
- FPF

Method
Characteristic property
Well Data
1D

Trends

- Facies proportions
2D

- Facies proportions
- Intensity trends, etc

Facies:
MPS

Facies:
Facies:
Channels
Composite
Object modelling methods
Interpreted facies log (discrete type)
- FPF
- FPF
- FPF
- VPC
- F: Facies proportions - F: Facies proportions
- F: Facies proportions
- Size and shape of
- Size and shape of
objects
objects
- Facies proportions
- Facies proportions
- Facies proportions

- Seismic data

- Seismic data

- Facies proportions
- Azimuth directions

- Facies proportions
- Training image

- Variogram ranges
- Seismic data

- Azimuth directions
- Seismic data

3D

Polygons, Points

- Facies proportions
- Accuracy of the
seismic
data
- Seismic data

Facies:
SedSeis
Pixel-based/Object

- Thickness of the
objects

- Facies proportions
- Size and shape of
objects
(continuous / discrete)
- Seismic data

Changing of facies belts
boundaries

Possibility specify any
discrete parameter as
hard data

Additional original data

Local update modelling mode

−

+

+

Body correlation between wells
Possibility to use shape of objects, which have
been
created manually
Possibility to set
Object height limitation
distance to channel
by surfaces
edges
+
+
−

Note: * F - function, which can reflect the variations of different variables (e.g. facies proportion, object's orientation, resizing objects with depth, etc.).

Vertical proportion curves (VPCs)
show vertical variations in the volume
fractions for different facies. A single
data object stores information on the
vertical trends for each facies for
(optionally) each zone.

Emerson Confidential • 4/30/2018 • Slide 18

Facies Probability Functions
(FPFs) give a probabilistic
relation between facies types
and seismic attribute values.
They are estimated using the
following seismic data types,
in combination with a bias
facies log or parameter

RMS Facies Pixel Based Methods

Facies Belts
Input Data

•

Definition of the facies
belts and their ordering

•

Information on migration
directions and other
geometric attributes

•

Interfingering variograms

•

Interpreted facies log

Emerson Confidential • 4/30/2018 • Slide 19

Applications

Benefits

Shoreface
Carbonate reef deposits
Deltaic

Output parameters can be
used as trends

Facies Belts: Geometry

Depositional direction
Aggradation Angle

Coordinates of boundary

Emerson Confidential • 4/30/2018 • Slide 20

Facies Belts: Facies Boundary Types
Your choice of cross sectional geometry should be
based on the general, large-scale facies architecture
of the reservoir grid model
• Parallel

• Pinch out

• Curved
Emerson Confidential • 4/30/2018 • Slide 21

Facies Belts: Interfingering
Modelled using a Gaussian field with a specified
standard deviation and range
• Large Standard deviation

• Large variogram range

• Short variogram range
Emerson Confidential • 4/30/2018 • Slide 22

Facies Belts: Stacking Angle
Ac  S

Retrograding
system

Ac  S

Aggrading
system

Ac < S
Ac = Accommodation space
Emerson Confidential • 4/30/2018 • Slide 23

S = Sediment supply

Prograding
system

Facies Belts: Extra Tips (Algorithm)
Trend algorithm equivalent to
Kriging without well conditioning
(even if well conditioning is
toggled on!)
It can be used for a quick result
to check that the settings are
adequate
Only the Simulation algorithm
will produce interfingering (using
the variogram)
Emerson Confidential • 4/30/2018 • Slide 25

Facies Belts: Extra Tips (Algorithm)
Trend

▪
▪

Well data not
honoured
Trend is used only to
run a quick check on
the geometry settings

Emerson Confidential • 4/30/2018 • Slide 26

Kriging

▪

▪

Kriging option is
equivalent to Trend
with honouring Well
data if specified
No interfingering

Simulation

▪

Honouring Well data if
well conditioning
toggled ON and
interfingering

Facies Belts: Extra Tips (Simulation sSettings)
Save memory option in order to
run the simulation faster in big
fields
User defined values:
0.01 = 1% of blocked well cells
might not be honoured, but fast
simulation
0.1 = 10% of blocked well cells
might not be honoured, but very
fast simulation

Emerson Confidential • 4/30/2018 • Slide 27

Facies Belts: Extra Tips (Proportions Mode)
Good for modeling lensoid
shapes
The ordering of facies is
important (if more than 2 facies),
the succession will always be
honoured
This option is also very useful
when trying to model big shale
barriers

Emerson Confidential • 4/30/2018 • Slide 28

Facies Belts: Extra Tips (Proportions Mode with
Trends)
1D Trend
Very useful to reproduce
exactly 1D trends like VPC with
very low or high values
The facies ordering will be
honoured as well
3D Trend
3D facies proportions trends
have to be created first, and this
is not trivial and may be time
consuming
Emerson Confidential • 4/30/2018 • Slide 29

Facies Belts: Extra Tips (Trends & Threshold)
Trends and threshold option used to produce very basic
seismic conditioning

Emerson Confidential • 4/30/2018 • Slide 30

Facies Belts: Extra Tips (Pinchout Polygons)

Emerson Confidential • 4/30/2018 • Slide 31

Facies Belts: Extra Tips (Interfingering)
It is recommended to use the General
Exponential variogram (very stable) for
the interfingering, and to play with the
value of the exponent for a more
cosmetic result, and more continuous
facies (important if connectivity issues)
The default variogram (Spherical) for
noisier boundaries
If an even more smooth effect is
needed, use General exponential with
a high exponent ~1.9) instead of a
Gaussian, which can be less stable

Emerson Confidential • 4/30/2018 • Slide 32

Facies Belts: Extra Tips (Interfingering)
Example of proportion mode with fixed Ranges 3000x3000,
but different variograms
Spherical

noisy

General Exponential
exponent=1

(~ equivalent to Exponential
variogram, very noisy, like
the Spherical variogram)

Emerson Confidential • 4/30/2018 • Slide 33

General Exponential
exponent=1.5

Smoother boundaries

General Exponential
exponent=1.9

Very smooth (close to
Gaussian variogram)

Facies Belts: Extra Tips (Interfingering)
To determine XY ranges use
geological understanding together with
well information and trial and error if
you have few wells
Depth range : use the BW statistics
– Start with the average facies thickness
– Run the Facies Belts job
– Once this is done, create a new log from

the created facies parameter on the BW
– Check if the statistics are compatible with
the original ones. If not, modify the depth
range and run the job again

Emerson Confidential • 4/30/2018 • Slide 34

RMS Facies Pixel Based Methods

Facies Indicators
Input Data

Applications

Benefits

•

Definition of the facies

•

1D, 2D or 3D trends

•

Vertical proportion
trends

The generation of very
flexible facies patterns, for
any number of facies

Flexible trend incorporation
• Seismic constraints
(cosimulation and seismic
as probability trends)

•

Facies probability
functions

•

Depth converted seismic
attribute (optional)

Emerson Confidential • 4/30/2018 • Slide 35

Facies Indicators: Handling of Mature Fields
Performance is independent of number of wells and use of seismic data
Well data

Facies realisation

Important complement to the object modeling techniques in RMS which
are more suitable for fields with less data

Emerson Confidential • 4/30/2018 • Slide 39

Facies Indicators: Flexible Trend Incorporation
A wide variety of 1D, 2D and 3D volume fraction trends can be used as
input
Can model any number of facies

Cross-section through Indicator realisation
Vertical
proportion
curves

Emerson Confidential • 4/30/2018 • Slide 40

Facies Indicators: Vertical Proportion Curves
Input Vertical Proportions

Upwards - fining,
Coal at top

Emerson Confidential • 4/30/2018 • Slide 41

Upper layer

Shale layer

Lower layer

Facies Indicators: Seismic Constraints
Two main methods for incorporation of seismic data

•
•

Cosimulation
Seismic as trend

Vshale map
from
seismic
attributes

Emerson Confidential • 4/30/2018 • Slide 42

Slice
through
facies
model

Net sand
map

RMS Facies Object Based Methods

Facies Channels
Input Data

Applications

Benefits

•

Definition of the
background and object
facies

Variety of channel
depositional settings (fluvial
• delta plain • deep marine)

Modelling highly complex
channel systems (single- &
multi-channel-belts)

•

Volume fraction of the
different facies

•

Information on the
geometry dimension an
orientation of the object
facies

Emerson Confidential • 4/30/2018 • Slide 45

Facies Channels
Models fluvial or tidal systems

Models crevasses attached to
the channels

Models barriers within the
channels

Emerson Confidential • 4/30/2018 • Slide 46

Facies Channels: Different Fluvial Systems

Two Main Operating Modes
“Sandbody” mode

“Multi-channel” mode

For single cut-and-fill
channel sand bodies and
direct modeling of channelbelt geometry

For modeling multiple
channels within channel
belts

Requires minimal user
input

Requires more complex
user input

Emerson Confidential • 4/30/2018 • Slide 47

Facies Channels: Extra Tips
Common mistake : Algorithm is not suited to model internal channel
bodies (point bar, sand bar…). It should be used to model the main
channel belts
Same with crevasses : designed to model overbank complexes, not
splays
Object modeling algorithm :
•

•
•
•

First channel is drawn randomly in the simulation box
Calculate its probability according to all constraints (wells, seismic,
geometry…)
If probability is high, the channel is kept,
Next iteration tries with another object

Iterative technique avoids bias at the wells, and takes into account that
the wells are more likely to reach wide channels than narrow ones

Emerson Confidential • 4/30/2018 • Slide 57

Facies Channels: Extra Tips (Volume Fraction)

Emerson Confidential • 4/30/2018 • Slide 58

Facies Channels: Extra Tips (Volume Fraction)

Emerson Confidential • 4/30/2018 • Slide 59

Facies Channels: Extra Tips (Geometry Settings)
Typical channel width distribution

Azimuth direction : always allows
some variability
Sinuosity : remember you are
modelling the channel belts, not
the meandering intra channel
bodies
Maximum recommended sinuosity
value is 1.8

Emerson Confidential • 4/30/2018 • Slide 60

RMS Facies Object Based Methods

Facies Composite
Input Data

Applications

Benefits

•

Definition of the
background and object
facies

High perm thief grid models
• Shale baffles • Deltas
lobes • Calcite layers

•

Volume fraction of the
facies / Target number of
bodies

Conditioning to a large
number of wells • Multiple
well-to-well correlation •
Modelling with multiple
trends

•

Information on the
geometry, dimension
and orientation of the
facies

Emerson Confidential • 4/30/2018 • Slide 62

Facies Composite
Advanced object based
Multi-well conditioning
Object Interactions
Implicit Erosion Rules
3D Seismic Conditioning
Powerful Trend Control
Local Volume Fractions

Emerson Confidential • 4/30/2018 • Slide 63

Facies Composite: Objects
Rectangle

Axial

Ellipsoid

Angular

Cone

Backbone

Note : a variant of the axial shape,
where the object is deformed locally to
follow a direction parameter

Emerson Confidential • 4/30/2018 • Slide 64

Facies Composite: Example of User Defined
Shapes
General channel (Axial)

Lobe (Axial)

Turbidite channel (Axial)

• Fluvial and deltaic channels

• Delta mouthbars
• Turbidite lobes

• Typical “Detailed Shape” settings
− Centre-line amplitude: 0.1 - 1.0
− Width rel. amplitude: 0.05 - 0.25
− Relative wavelength: 0.1 - 1.0

• Typical “Detailed Shape” settings
• Typical “Detailed Shape” settings
− Centre-line amplitude: 0.05 - 0.25
− Centre-line amplitude: 0.1 - 0.5
− Width rel. amplitude: 0.05 - 0.25
− Width rel. amplitude: 0.05 - 0.25
− Relative wavelength: 0.5 - 1.0
− Relative wavelength: 0.1 - 1.0

Emerson Confidential • 4/30/2018 • Slide 65

• Fluvial and deltaic channels

Facies Composite: Example of User Defined
Shapes
Arcuate bar (Axial)

“Flexible” ellipsoid (Axial)

• Wave reworked mouthbars

• Wide spread shale, calcite or coal barriers
• Flexible and realistic geometries for multi-well
conditioning of widespread barriers

• Typical “Detailed Shape” settings
− Centre-line amplitude: 0.05 - 0.25
− Width rel. amplitude: 0.05 - 0.25
− Relative wavelength: 0.5 - 1.0

• Typical “Detailed Shape” settings
− Relative amplitude: 0.1 – 0.5
− Relative wavelength: 0.5 - 1.0

Emerson Confidential • 4/30/2018 • Slide 66

Facies Composite: Trends
1D, 2D or 3D trends for:
– object sizes

– orientation
– volume fractions
– distribution

Control of facies distribution by 2D or 3D seismic attributes
Large scale facies realizations can be input as intensity
functions to control smaller scale facies distribution

Emerson Confidential • 4/30/2018 • Slide 67

Facies Composite: Reference Point of Objects
To position an object, the algorithm consider the reference point to start
with

With reference point is 0,0,0 (default) in the object, it means that it is
exactly at the centre of the object shape
Reference
point
specification

For turbidites, put the reference
point at the proximal end of the
shape, to force bodies positioning
even more
Emerson Confidential • 4/30/2018 • Slide 68

Facies Composite: Extra Tips (Volume fraction)
Volume fraction:
– Global → no systematic trends

in the volume fraction, but
relative intensity trend can be
used

– Local → used to introduce

trends in the volume fraction.
The settings are specified as
attribute distribution

Emerson Confidential • 4/30/2018 • Slide 69

Facies Composite: Extra Tips (Geometry
settings)
Standard deviation of object size : can use 1/5th of the average, up to
the average value itself

Height : it is the maximum thickness of the object, related to the
reference point
There is a lot of uncertainty on the bodies height :
– Can easily add 20-25% more to the average observed at BW
– Dip : leave the default value ! If thin objects, a higher dip will produce lateral

discontinuity

Emerson Confidential • 4/30/2018 • Slide 70

Facies Composite: Extra Tips (Simulation
settings)
High T0 → much more variability
in volume fraction at the
beginning of the simulation
Low T0 → less variability

If volume fraction is difficult to
reach, then reduce T1 (but not
recommended)

Emerson Confidential • 4/30/2018 • Slide 71

Facies Realisation Merging
Used to create complex environments
Hierarchical modeling (by defining ’erosion’ rules)

Emerson Confidential • 4/30/2018 • Slide 72

RMS Facies Object Based Methods

Facies SedSeis
Input Data

Applications

Benefits

•

Digitized Polygon or
Point Data information

•

Seismic data

Two different methods can
be run as one job: Pixel
Based / Object Based

•

Facies log

High-permeable flowregions • Facies bodies
identified on good resolution
seismic

Emerson Confidential • 4/30/2018 • Slide 73

RMS Facies Pixel Based Methods

Facies Multipoint Statistics (MPS)
Input Data

•

Training Images (TI)

•

Discrete parameter
representing different
areas (region parameter)

•

Volume fractions for
each facies type / region
/ trend

•

Seismic data (attributes)

Emerson Confidential • 4/30/2018 • Slide 74

Applications

Benefits

Tool for creating realistic
facies architectures in 3D
reservoir models

Flexibility & Speed • Multiple
sources of hard data such
as well data, seismic,
trends, regions

RMS Facies Object Based Methods

Facies Elementary
Input Data

•

A 3D grid layout (volume
and resolution)

•

Well data (facies body
distribution)

•

Trend lines / surfaces

Emerson Confidential • 4/30/2018 • Slide 75

Applications

Benefits

Stochastic reservoir
modelling during the
exploration stage • Include
deterministic elements when
moving from appraisal to
production

Combines both deterministic
and stochastic approaches
with object modelling.
Integrated with the internal
programming language IPL.

Exercises#1
Facies Modelling – Fluvial Environments
• Case 1 : High NTG, few wells, basic sand / shale facies
interpretation
Project : Ruby.pro, Grid Model → Fluvial
• Use of Facies Belts as a first pass model with Proportion mode
• Use of Facies Channels with a conceptual model

• Case 2 : Extensive well data, seismic attribute available
Project : Sapphire.pro, Grid Model → Mod_Grid Zone. Zone 2
• Use of Facies Indicators with VPC trend, seismic conditioning

Emerson Confidential • 4/30/2018 • Slide 76

Case 1 : High NTG, few wells, basic sand/shale facies interp.
Project : Ruby.pro, Grid Model → Fluvial
Use of Facies Belts as a first pass model with Proportion mode
Use of Facies Channels with a conceptual model

Background & Available Data:
• 4 wells with GR, PHIE, Facies_Fluvial logs
• Facies interpretation kept simple – based on PHIE cutoff
• Sand [>7.5% PHIE] ~ combines poor & good sands
• Shale

• Environment: coarse braided fluvial system (from regional studies)
• Channel orientation: SE-NW [N300]
• Well statistics: relatively high NTG [46% of facies is sand]

Emerson Confidential • 4/30/2018 • Slide 77

Case 2 : Extensive well data, seismic attribute available
Project : Sapphire.pro, Grid Model → Mod_Grid Zone. Zone 2
Use of Facies Indicators with VPC trend, seismic conditioning

Background & Available Data:
• Structure: simple rotated fault block, depth around 2000 m
• 2 main reservoir zones bounded by 2 thick field-wide marine shales

• 57 wells with GR, RHOB, Por, Perm, Facies logs
• Upper zone: good, relatively homogeneous sands deposited in
•
•
•

•
•

shoreface environments
Lower zone: heterogeneous fluvial environment, with available Vsh
map
Paleogeographic setting: widespread alluvial floodplain with a
hinterland to NNE
Four main facies: shales, clean sands, shaley sands, coals
Field-wide FS separates the 2 reservoir units
Common OWC at 2290 m

Emerson Confidential • 4/30/2018 • Slide 78

Emerson Confidential • 4/30/2018 • Slide 79

Exercises#2
Facies Modelling – Shoreface & Delta
• Case 1 : Simple shoreface environment with stacked
belts
Project : Ruby.pro, Grid Model → Shoreface
• Use of Facies Belts to model the transitional units
• Use of Facies Composite to represent the spit deposits, using trends
• Merge facies realisations

• Case 2 : Complex fluvial dominated delta with stacked
belts, fluvial channels and mouthbar facies
•
•
•
•

Project : Sapphire.pro, Grid Model → Delta
Use of Facies Belts for the large scale deltaic belts
Model the fluvial channels using Facies Channels
Model the mouthbars using Facies Composite
Merge facies realisations

Emerson Confidential • 4/30/2018 • Slide 80

Exercises#3
Facies Modelling – Turbidite Environment
• Case : Turbidite Reservoir
Project : Ruby.pro, Grid Model → Turbidite
• Basic Facies Composite job set up
• Use of trends in Facies Composite
• Model the turbidite objects using the backbone shape

Emerson Confidential • 4/30/2018 • Slide 81

Exercises#4
Turbidite modelling with SedSeis
• Case : Turbidite Reservoir
Project : SedSeis.pro, Grid Model → Sedseis
• Pixel mode
• Parametric mode
• Turbidite modelling with intra body trends

Emerson Confidential • 4/30/2018 • Slide 82

Case Study : Ruby Field
•

There are 3 main reservoir zones in the Ruby
Field
− An upper zone deposited in a coarse braided
fluvial system
− An intermediate zone deposited in a shallow
marine environment
− A lower heterogeneous zone deposited in a
deep-water turbidite environment

•

Two reservoir lowest units are separated by
a thick mud-rich slope sequence

•

There are different OWCs in the two
reservoirs
− 2010 m in the upper shoreface unit
− 2270 m in the lower turbidite unit

•

Two main faults have been mapped within
the field

Emerson Confidential • 4/30/2018 • Slide 83

Case Study : Sapphire Field
•

•

The structure of the Sapphire field is a
simple rotated fault block that lies at a depth
of around 2000 m
There are two main reservoir zones bounded
by two thick field-wide marine shales:
− The upper zone comprises good, relatively
homogeneous sands deposited in shoreface
environments
− A lower heterogeneous zone has been
deposited in a fluvial environment.

•

•

•

•

The paleogeographic setting for the unit is a
widespread alluvial floodplain with a
hinterland to the NNE
Four main facies have been identified in this
zone: Shales, Clean sands, Shaley sands
and Coals
A field-wide flooding surface separates the
two reservoir units
There is a common OWC for both reservoirs
at a depth of 2290 m

Emerson Confidential • 4/30/2018 • Slide 84

Case Study : Turbidite (Gulf of Mexico)
• Synthetic example
• Fault bounded structure
• 6 exploration and appraisal wells
• Reservoir interval 30-150 m thick
• Focused entry point for turbidites
• Basin floor topography reflected in isochore

OWC

Emerson Confidential • 4/30/2018 • Slide 85

Thickness map

Entry
point
for
turbidites

Better Decisions.
Better Returns.
Ruslan Nasibullin
Senior Geologist
[email protected]

www.roxarsoftware.com