Deterministic Petrophysics

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Deterministic Petrophysics

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Title: Deterministic Petrophysics

1
Deterministic Petrophysics
2
Log Evaluation Workflow
Lithology
Clay Volume Estimation
Porosity Computation
Water Saturation Calculation
Fluid Zones
Permeability Determination
Net Pay / Net Reservoir Quantification
Reality check
3
Log Evaluation Workflow

Lithology
Clay Volume Estimation
Porosity Computation
Core calibration
Water Saturation Calculation
Core derived parameters
Comparisons with core
Saturation-height
Fluid Zones
Fluids present
Fluid contacts
FWL
Permeability Determination
Core derived predictors
Net Pay / Net Reservoir Quantification
Reality checks
Uncertainty Analysis

Reasons for iteration
Part or Total iterations
4
Log Evaluation Workflow Reality Checks 1

Look for consistency
Between parameters from different data types.
Different data types may not all tell the same
story but any conflicts should be explained.
Lithology, hydrocarbon shows and core data should
be identified prior to log evaluation.
Lithology and Clay volume
Compare with clays and other minerals seen in
core.
Use core grain density as guide to main matrix
material.
Compare with core mineralogy (XRD, thin section).
Porosity
Porosity Differences or similarity of different
log porosities.
Log to core comparison or calibration.
Sense check magnitude of porosity.

5
Log Evaluation Workflow Reality Checks 2

Log derived water saturation should be compared
with
Capillary pressure curves.
Core fluid saturation measurements (Dean Stark).
DST and WFT samples.
Discrepancies may point to the need for modified
interpretation.
Log derived permeability should be calibrated to
core data.
Compare cumulative log permeability with
production log inflow profiles.
Compare permeability-height (KH) from log
permeability with KH from well tests.
Net Pay and Net Reservoir should be compared to
permeability indicators and core if available.
Effective formation evaluation is a process of
integration of different data types in order to
provide a robust interpretation.

6
Deterministic Petrophysics Lithology Clay
Volume
7
Basic Interpretation Workflow Lithology
Interpretation

The Gamma Ray log responds to natural
radioactivity in rocks. Contrast between sand
and shale.
Exceptions Feldspathic (potassium feldspars),
micaceous, or glauconitic sands will show an
atypical, high gamma ray response. Source rock
shales can have very high GR values often a
characteristic of the Kimmeridge Clay Formation
in the North Sea.
Neutron and Density logs when run together are,
by convention, displayed with the curves
superimposed in the same log track, on standard
scales such that curves overlay in water-bearing
limestones. The curves shift according to
lithology and porosity.
Some minerals have characteristic D/N responses
and cross-plots can be used to determine these.
Calcite, Coal, Salt, Anhydrite, Gypsum etc
The photo-electric curve (PE or PEF) can also be
used.

8
Typical Log Responses to Lithology and Gas
Density
Neutron
Sonic
Log response Decreases with Increasing Porosity
Log response Increases with Increasing Porosity
Log response Decreases with Increasing Porosity
Reservoir Rock
Low
High
High
Low
High
Low
Limestone (Reference)
2.71 g/cc
0
47.5 us/ft
52.5 55.5 us/ft Variable with Compaction
2.65 g/cc
Sandstone
- 4
2.83 to 2.87 g/cc
42.5 us/ft
Dolomite
6 to 8
Non Reservoir Rock
2.98 g/cc
50 us/ft
Anhydrite
- (1 to 2)
2.33 g/cc
52 us/ft
Gypsum
48
Salt
2.08 g/cc
67 us/ft
0
130 175 us/ft Variable with Compaction
Wide Range 2.3 2.7 g/cc Variable with Clay
Density
Reads High Increases with Clay Bound Water
Shale
Hydrocarbon
Gas Effect
Reads Low
Reads High
Reads Low
9
Lithology Example 1
Minerals Determined from D/N Cross-plot Salt ? ?
Dolomite ? ? Anhydrite ? ?
10
Lithology Example 2
Minerals Determined from D/N Cross-plot Limestone
Claystone-sandstone
11
Clay Volume Determination from Wire-line Logs

Clay Volume (Vclay)
The clay content reflects the amount of clay
minerals present in a rock. The term SHALE
normally denotes assemblages of clay grade
particle sizes which include clay minerals as
well as other minerals such as quartz, mica etc.
The proportion of clay in shale can range from
50 to 100.
Clay volume is estimated to determine
Shale / Sand ratios.
Shale corrections in porosity determination.
Shale corrections to Sw .
Log facies.
Reservoir Delineation.

12
Clay Volume Determination from Wire-line Logs

Commonly used Clay Indicators are
GR.
SP.
Resistivity (in hydrocarbon-bearing reservoir).
Neutron-Density log Cross Plot.
Typically determine Vclay using several
alternative methods and use either the minimum
or average value of them
Care required
If radioactive minerals (other than clays) occur
in sands VclayGR is an overestimate.
If hydrocarbon type is gas VclayDN is an
underestimate.
The Vclay from logs should be calibrated or
compared with core data where possible
Shale count observed in core.
Thin section point count data.
XRD data.

13
Clay Volume from Gamma Ray VclayGR

Normally shales contain radioactive minerals and
sands do not.
Sands may contain radioactive minerals e.g.
Biotite, Potassium feldspars or Glauconite. Need
corroboration with other clay indicators.
Select clay and clean sand lines.
A linear relationship is normally assumed
(non-linear versions Larinov or Clavier used in
FSU for older rocks).
Vclay is obtained from the following
equationWhere, VclayGR Clay volume from
GR (v/v) GRlog Log GR (GAPI) GRsand
GR in clean sand (GAPI) GRclay GR in
clay/shale (GAPI)

14
Clay Volume from Gamma Ray Thin Beds

Heterogeneity Thin Bed Problem
In rock beds less than 2 feet thick, log
resolution starts to have an impact by being
strongly influenced by adjacent beds.
Thinly laminated sand-shale sequences can have
clean sands, which are not resolved and are
interpreted as shaley sands or shales.
Note This problem is not limited to shale
volume detection and the GR log. Similar effects
with respect to non-resolution of thin beds also
occur with porosity and resistivity tools.

15
Clay Volume from Gamma Ray Plot illustrating
picking sand and clay GR

It is often difficult to decide which shales are
characteristic of the clays dispersed in the
sands
This will depend on the mode of deposition of
sands and shales.
Talk to the project geologist to get his
insights!
Other considerations
It is likely that different parameters will be
required in different intervals in the well.
Take care to note changes of hole diameter or
presence of casing. Both will change the
attenuation of the GR.
Parameters are chosen by one of several
methods
By eyeballing sand and clay GR.
Using sand and clay lines in a depth plot.
Note GRsand lt the smallest Log GRlog and
GRclaylt largest GRlog .

16
Clay Volume from Gamma Ray Histogram
illustrating picking sand and clay GR

In some cases to render the process of choosing
less subjective or to facilitate fast
interpretation in a large number of intervals the
parameters may use specified percentile points
in histogramsof GR.
Typically 5 and 95 percentile values of GR are
adopted as GRsand and GRclay respectively.

17
Clay Volume from SP VclaySP

Responses in clay and sand sand line and clay
line.
Select clean and clay lines (methods for
choosing parameters are essentially the same as
for GR).
Vclay calculated using the following
equation
Where, VclaySP Clay volume from SP
(v/v) SPlog Log SP (mV) SPsand SP in
clean sand (mV) SPclay SP in clay/shale
(mV)

18
Clay Volume from SP

SPsand and SPclay are picked in a similar manner
to the GR equivalents
Considerations
SP deflection is suppressed (reduced) in
hydrocarbon-bearing sands.
SP deflection varies with Formation Water
Salinity changes.
Hence require different parameters in different
zones of the well if formation (or mud-fluids)
salinity changes.
SP is not effected by non-clay radioactive
minerals.
SP has poor vertical resolution lazy response
compared with GR.

19
Clay Volume from Neutron-Density VclayDN

Typically VClayDN is determined using
Density-Neutron cross-plots
Choose appropriate lithology line by observation
and hence select clean points.
Choose a clay point as a SE point in the data
distribution.
Parameters are likely to vary by zone in a given
well and between wells.
Clay volume determined based on location of data
points in the cross-plot.

20
Clay Volume from Neutron/Density Cross-plot
Clay Point
21
VClay Comparison of Methods
Pros Cons Pros Cons Pros Cons
Insensitive to borehole conditions Radioactive Minerals in sands Insensitive to borehole conditions Requires water based mud Not as sensitive to radioactive minerals as GR Sensitive to Borehole Conditions
Available through casing Radioactive Mineral variation in shales Not affected by radioactive minerals Poor Bed Resolution Mineral typing Sensitive to presence of gas
Not affected by hydrocarbons Affected by Hydrocarbons
22
Clay Volume Calculation in IP
23
Clay Volume - GR

GR minimum picked in clean zones. Minimum value
in the cleanest zones.
GR max picked in shales. Value picked to give a
maximum of about 80 clay in the shale. Note that
shales hardly ever have 100 clay. 60-80 normal
range.
Can overestimate clay volume due to radioactive
minerals in the sands

24
Clay Volume GR

Non linear GR methods have been designed to work
under specific conditions certain ages of rocks
or certain formations in certain fields. Usually
developed in zones that have radioactive minerals
associated with the sands (feldspars, micas, some
heavy minerals).
They generally need some sort of calibration to
verify their validity.

25
Clay Volume - Neutron

The neutron Vcl nearly always overestimates clay
volume and the tools have a non-linear response.
It is useful for tight streaks and gas sands
where other indicators may overestimate.
Neutron clean is generally left at zero. Anything
greater than that you risk underestimating Vcl.
Neutron clay set to calculate 60-80 Vcl in the
shale zones. Set to give same sort of results as
the VclGR in the shales.

26
Clay Volume - Resistivity

Can work well in hydrocarbon bearing zones. Does
not work in shales or wet zones. Since it depends
on the deep resistivity there are potential
problems of vertical resolution. Needs to be used
with care.
Usually used as a last resort when all else
fails.
Res clean picked at maximum value in the
hydrocarbon interval.
Res clay picked in the shale zones.

27
Clay Volume - SP

The SP quite often has a very lazy shape and does
not respond quickly to bed boundaries. Will only
work with high salinity contrasts between Rmf and
Rw. The example shows a poor SP Vcl indicator and
should not be used.
SP will probably need to be base-lined before use
SP response is suppressed by hydrocarbon
SP response is suppressed by thin beds
SP clean picked in thick, clean zones.
SP shale picked in the shales.
Use with great care.

28
Clay Volume - Neutron Density

One of the best clay indicators since the neutron
and density tools respond linearly to increasing
amounts of clay. The light hydrocarbon effect on
the logs will mean an underestimation of Vcl
unless this is adjusted for with the clean line.
The indicator does not work well in complex
carbonates (dolomite and shale can have similar
responses).
Clean line and clay point normally picked using
cross-plots. Clean line must be adjusted for
matrix type (sand, lime) and also hydrocarbon.
The hydrocarbon correction is made by changing
the slope on the clean matrix line.
The Clay point is normally picked so that the N/D
Vcl gives about 60-80 clay in the shales.

Above plot shows the picks in the light
hydrocarbon zones Note the Active Zones are 2
and 4
29
Clay Volume - Sonic Density

Can work well as a clay indicator, but generally
is similar to the N/D Vcl.
Clean line is adjusted to fit the data in the
clean zones. Hydrocarbon effects will be smaller
than the N/D Vcl since gas has the effect of
increasing both the sonic and density porosity.
Clay point is adjusted to give about 60-80 clay
in the shales.

30
Clay Volume - Sonic Neutron

The S/N Vcl is generally not very effective
since the response to clay is to increase both
the neutron and sonic readings. However can be
useful in situations where nothing else works.
Clean line and clay point are adjusted similar to
the other double clay indicators.

31
Clay Volume
32
Deterministic PetrophysicsPorosity
33
Basic Petrophysical Properties Porosity

Defined as the ratio of Void space to Bulk Volume
of the rock
Porosity is a measure of the space available for
storageof fluids
Where, Ø Porosity Vp Pore Volume Vt
Total Volume
Expressed as Percentage () or Decimal (v/v)

34
Basic Petrophysical Properties Porosity Types by
mode of formation

Types of porosity
Primary originating as the sands were laid down
Inter-granular or inter-particle
Intra-granular
Inter-crystalline
Bedding planes
Secondary formed by various processes after
sands were formed
Solution porosity or Dissolution
Dolomitisation
Fractures
Vugs
Shale Porosity
Secondary porosity is generally far more
important in carbonates than sandstones
For clean sandstones and carbonates,
Porosity can readily be derived from logs
For complex formations porosity data from core is
required to calibrate the log response

35
Basic Petrophysical Properties Porosity Types
Total versus Effective

Total Porosity Øt
Ratio of all pore space (and clay structural
water seen by some tools) to bulk volume.
Includes all pores regardless of the degree of
connectivity or pore size.
Includes water in clay structure.
Effective Porosity Øe
Ratio of interconnected pore volume to the bulk
volume.

36
Basic Petrophysical Properties Volumes and
Porosity
Often assumed negligable in Carbonates Usually
significant in Clastics
37
Basic Petrophysical Properties Porosity Ranges
Note Theoretical maximum inter-granular porosity
for cubic-packed spherical grains is 47.6
38
Basic Petrophysical Properties Porosity
measurements

Core porosity
Measure two of pore volume, grain volume and
bulk volume of core plug and ratio them.
Direct measurement but
Measure Øt or Øe (or something in between)
depending on pore types present, clay content and
method of cleaning and drying.
Measured under laboratory conditions rather than
reservoir stress. Require correction to
reservoir conditions for comparison with or
calibration of log porosity.
Log Porosity
Sonic, Density, Density/Neutron, NMR.
Porosities measured differ.
No log measures porosity directly.
Calibrate to core when possible.

39
Basic Petrophysical Properties Porosity and
measuring techniques
Log and core Porosity Measurements
Total Porosity, Sonic Log
Total Porosity, Neutron Log
Total Porosity, Density Log
Absolute or Total Porosity

Oven-dried Core Porosity
Matrix

Humidity-dried Core Porosity
VSHALE
Clay Layers
Clay surfaces Interlayers
Small Pores
Quartz
Large Pores
Isolated Pores
Hydrocarbon Pore Volume
Capillary Water
Hydration or Bound Water
Structural Water
Irreducible or Immobile Water
If sample is completely disaggregated (after
Eslinger and Pevear, 1988)
40
Which Porosity Log Should I Use ?

Where possible all porosities should be
calibrated to core data.
Density porosity Ød is preferred provided that
The well is in gauge.
The matrix density is known and reasonably
uniform.
The reservoir fluids are liquids.
Sonic porosity Øs (using RHG equation) is used as
an alternative to Ød if
The borehole is washed out or DRHOgt0.05 gm/cc.
Density/Neutron porosity Ødn is substituted for
Ød if
Gas is present in the formation.
The lithology is unknown or variable (exploration
wells)
NMR porosity ØNMR is of similar quality to Ød
except in some carbonates and in gas zones. It
is a specialised log used most often to address
complex porosity issues
Measure effective porosity in complex pore
structures.
In many instances there will only be one porosity
log available in which case the best
interpretation possible must be made with that
available
Early exploration wells using single detector
neutron or sonic log.

41
Porosity from Sonic -Wyllie Time Average (WTA)
Equation
For much of the depth interval drilled in any
well, the sonic log is likely to be the only
means of deriving porosity. There are two
equations (Wyllie time average and
Raymer-Hunt-Gardner) In the Wyllie Equation, or
the Time Average equation, porosity is assumed
to be a linear function of the interval transit
time Where, Øs Sonic porosity
(v/v) ?tlog Interval transit-time measured by
the sonic log (µsec/ft) ?tma Matrix
transit-time (µsec/ft) ?tfl Transit-time of
fluid contained in the formation
(µsec/ft) Bcp Compaction factor determined by
comparison with core or regional experience.
Often assumed to be 1.
41
42
Porosity from Sonic Comparison of WTA RHG
equation with Porosity

Experience with WTA showed that it overestimated
porosity at high transit times or in
unconsolidated formations.
Comparison of core and other log porosities with
WTA confirmed
Overestimation of ØS at high transit times.
Underestimates ØS at intermediate transit times
RHG derived an alternative equation for ØS that
better fits porosity over the whole range of
magnitude.

Comparison of WTA and RHG equations with Field
Data. After Porosity Reference1.
43
Porosity from Sonic- Raymer-Hunt-Gardner (RHG)
Equation
The Raymer-Hunt-Gardner relationship is an
empirically-based Porosity solution using the
comparison of sonic log transit times, core
porosities and porosities from other logs. It
provides more realistic values than the Wyllie
equation particularly at high porosities and in
poorly consolidated formations. In simplified
form it is
Where, Øs Sonic porosity (v/v) ?tlog Interval
transit-time measured by the sonic log
(µsec/ft) ?tma Matrix transit time
(µsec/ft) x A lithology dependant
constant This equation has the advantage that it
does not require ?tfl as input.
44
Porosity from Density

The Density measurement is the most reliable
means of deriving porosity from logs given
Good hole conditions
Fairly constant grain density
Density porosity is calculated using

Where, Ød Density porosity (v/v) ?b Log
bulk-density (gm/cc) ?ma Matrix density
(Sandstone 2.65, Limestone 2.71, Dolomite 2.88
gm/cc) ?fl Apparent fluid density
(Approximate using Fresh water-based mud
1gm/cc, oil-based mud 0.85 gm/cc)
45
Porosity from Density-Neutron Combination

Neutron porosity is seldom used independently
However neutron porosity may be the only porosity
log in some early wells.
Usually used in combination with the density
log.
Weighted average porosity
Oil/water
Gas
Density-Neutron Cross-plot porosity
Density-Neutron combined porosity is particularly
useful in gas zones where Ød and Øs tend to be
overestimates unless core is available to
calibrate them.

If neutron was logged in Limestone units convert
to actual matrix before use in weighted average
Ønd
46
Porosity and Clay Volume Estimation from Density
/ Neutron Cross-plot in shaly sands

Porosity-Clay volume D/N Overlay construction
Establish the (Wet) Clay point in the SE of
Density-Neutron Cross-plotted data.
Matrix line.
Defined by a line joining the matrix point
(porosity 0) to the fluid (water) point (porosity
of 1).
Scaled linearly in porosity.
Matrix-Clay line.
Defined by Matrix and (Wet) Clay points.
Effective porosity 0 along this line.
Scaled linearly in clay volume.

46
47
Effective Porosity

Effective porosity
Where, Øe Effective porosity (v/v)
Øt Total porosity (v/v)
Øtcl Total porosity of clay (v/v)
Vcl clay volume (v/v)

48
The Borehole Environment

Invasion
The depth of invasion is controlled by the
formation
porosity and permeability and the mud
characteristics
(pressure differential between mud column and
formation,
viscosity and fluid loss).
High permeability beds generally tend to show
less
invasion, due to fast mudcake build-up, while
lower
permeability beds tend to have more invasion.
As mud invasion is a volume system, the depth of
invasion in high porosity beds is shallow and
correspondingly the depth of invasion in low
porosity beds is deep.
The effect of invasion will decrease away from
the wellbore so that there is a transition zone
developed, from mud filtrate at the well, through
a zone of mixed filtrate and formation fluid, to
the non-invaded zone where original formation
fluids are found.

49
The Borehole Environment
50
Mud Filtrate Invasion
Water-Based Mud System
Oil-Based Mud System
(c) Water-bearing formation
(d) Oil-bearing formation
51
Fluid Parameter Determination for Porosity
Calculation

All porosity calculations require a fluid
parameter
Ød fluid density ?f
Øs fluid transit time ?tf
Øn fluid hydrogen index HIf
It can be assumed that the porosity logs measure
predominantly in the in the flushed zone.
Hence the fluid parameter will be a weighted
average of mud-filtrate, formation water and
where present hydrocarbon properties dependent on
the saturations of those fluids in the invaded
zone.
For this reason porosity and saturation
calculations are linked in IP.

52
Fluid Density Determination for Porosity
Calculation in wells drilled with WBM

In the hydrocarbon leg
In the water leg
Flushed zone saturation Sxo can be calculated
using the Archie water saturation equation
Where
Rmf is the mud-filtrate resistivity
Rxo is measured by the micro-resistivity log
(MSFL or MLL)
Ø is the porosity

53
Fluid Density Determination for Porosity
Calculation in wells drilled with OBM

In the hydrocarbon leg
In the water leg
No log measurement of Rxo is made in OBM.
The iterative method used in WBM wells is not
possible!Instead
Estimate the invasion factor I
Assume Sxo is the minimum of Sw or I

54
Porosity Calculation in IP
55
Equations

As much as possible the complete tool response
equations are utilised within IP.
This Means That
We dont just consider a single fluid parameter
(e.g. Fluid Density) but we split this up into
the single components (e.g. flushed zone water
and hydrocarbon).
Excavation effects on the neutron log and
apparent hydrocarbon electron density corrections
are considered.
The equations are solved simultaneously and
iteratively.
This Results In
A superior and more believable interpretation
result that tends to match core results better.

56
Equations

Flushed Zone Water properties as seen by the
Porosity tools are calculated from water
resistivity values.
Alternatively these values can be entered by zone
or a trend curve can be used.

57
Equations

If not entered then hydrocarbon density and
neutron HI values are calculated using
Gaymard-Poupon equations from an entered input
true hydrocarbon density value for each zone.

58
Porosity Models - Density
59
Porosity Models - Density

Easy to use but assumes complete understanding of
fluid and matrix types.
In gas errors in gas density and flushed zone
(Sxo) saturation can cause large porosity
errors.
Matrix density entered as curve or fixed
parameter.
Used in Multi-mineral analysis for porosity.
Lithology is used to calculated the matrix
density

60
Porosity Models - Neutron
61
Porosity Models - Neutron

Non linear response equation to minerals and
hydrocarbons
Equations are tool specific
IP allows the selection of the tool type
Tools are very sensitive to borehole
corrections.
Large gas correction required
Gas correction reverse of the density
The neutron is rarely used by itself. Normal used
in conjunction with the density to calculate a
neutron / density porosity.
To use non linear matrix enter Rho matrix for
required mineral (2.65 for sand) otherwise enter
the matrix neutron porosity

62
Porosity Models - Sonic

Two empirical relationships in IP
Wyllie
Raymer Hunt
Input parameters are hard to pin down and best
set by calibrating to another porosity
Gas effects can be large in high porosity
Hard to correct for
Sonic used when
No density available
Density effected by hole washout
Unusual lithology where density matrix is not
known
Volcanics

63
Porosity Models Neutron / Density
64
Porosity Models Neutron / Density

Preferred method in IP
Two input equations so can calculated two outputs
Porosity Hydrocarbon Density
Porosity Matrix Density
Porosity Clay Volume
Three methods for controlling the logic
Calculate hydrocarbon density using a fixed
matrix density
Calculate matrix density using a fixed
hydrocarbon density
Calculate clay volume using a fixed hydrocarbon
and matrix density

65
Porosity Models Neutron / Density
66
Porosity Models Neutron / Sonic

Used similar logic to Neutron / Density
Rarely used since the N / D is more accurate and
easier to understand and control
Sonic parameter selection

67
Porosity and Water Saturation
68
Porosity Models Pass through Porosity

For users who want to calculated Phi outside the
normal routine
Regression against core data
NMR porosity
Program needs to know if input porosity is a
total or effective porosity
All normal logic is applied
Sw calculations
Bad hole logic

69
Deterministic PetrophysicsWater Saturation
70
Water Saturation in clean sands - The Archie
Equation

Archie Equation
Six unknowns
True formation resistivity Rt is taken as the
most suitable deep reading resistivity,
environmentally corrected if necessary.
Formation water resistivity Rw
SP interpretation
From Rwa in a water leg
Pickett plots
Water samples
Porosity log total porosity
Tortuosity constant (a), Cementation exponent (m)
and Saturation exponent (n)
Preferably determined from Core measured
Formation Factor (FR) and Resistivity Index (I)
respectively.
In Sandstones if lacking core choose from
Archie Parameters a1, mn2

71
Determination of Rw and m from a Pickett Plot

From the Archie equation
Rearranging and substituting for resistivity
Index
Taking Logs
This equation describes a family of parallel
lines, in a log-log plot of Rt versus Ø, for
different resistivity indices whose slope is m.
The line for I1 (and Sw1) is the water line
with an intercept a.Rw at a porosity of 1.
Such a log-log plot of Rt versus Ø of this form
is called a Pickett Plot.

72
Water Saturation Models

Effective Porosity models
Archie
Indonesian (Poupon-Leveaux)
Simandoux
Modified Simandoux
Total Porosity models
Archie Total porosity
Dual Water
Juhasz (Waxman-Smits)
Waxman-Smits

73
Shaly sands the effect of clay on the
conductivity
The additional conductive path reduces the
resistivity of the formation. If this effect is
not taken into account this has the effect of
increasing the calculated water saturation above
its real value. Shaly sand interpretation
corrects for this effect to calculate Sw.
The negatively charged clay surfaces provide an
additional conductive path.
74
Clean and Shaly Sand Saturation Equations

Clean sands Archie equation
Assumes that the only conducting component in the
reservoir is water.
In shaly sands the clays provide a parallel
conductive path hence Rt is lower than it would
be with the same Sw in the absence of clays.
Shaly sand saturation equations account for the
extra conductivity provided by the shales.

75
Measures of Shaliness

The number of positive ions (cations) attracted
to the clay surface depends on the amount of clay
and the type of clay. The number is called the
Cation Exchange capacity (CEC), also denoted by
Qv.
CEC is expressed in milli-equivalent of
exchangeable ions per hundred grams (meq/100gm).
Qv is expressed in milli-equivalent per
milli-litre (cc) pore volume
The conversion between the two is
The Qv is indicative of the degree of shaliness
of a formation
Qvlt0.1 Clean sands
0.1ltQvlt0.2 Slightly shaly sands
0.2ltQvlt0.3 Moderately shaly sands
0.3ltQvlt0.5 Shaly sands
Qvgt0.5 Very shaly sands
Clays vary in their electrical activity as
indicated by their CEC
Kaolinite 3-15 meq/100gm
Illite and Chlorite 10-40 meq/100gm
Montmorillinite 80-150 meq/100gm
The GR is not a good indicator of CEC , for
instance montmorillinite contains no potassium
and hence has a low GR response but high CEC.

76
Shaly sands

The Archie equation assumes that the matrix is
non-conducting.
In shaly sands the resistivity is lower than in
clean sands for the same Ø and Sw. This is
caused by the additional electrical conductivity
of the clay.
Hence use of the Archie equation in shaly sands
will result in too low a hydrocarbon saturation.
There are a large number of shaly-sand Sw
equations.
All have the basic Archie form with an additional
term to account for the extra conductivity of the
clay.
The clay-distributions for which the equations
are intended are not always clear.
Two equations will be described here
The Indonesia Equation well adapted for
application without supporting core analysis
data.
The Waxman-Smits equation which is intended for
application where the clays coat the matrix
grains (dispersed shale). This equation performs
well when core measurements of the clay
properties are available.

77
Alternative Shaly Sands Water Saturation
EquationsComparison

Several equations are shown at right in
conductivity form which facilitates comparison.
The similarities and differences between
equations are apparent.

77
77
78
When do I Need to use a Shaly Sand Interpretation?

If possible treat sands as clean non-shaly
because it is much simpler to do so!
In that case Øt Øe and the Archie equation can
be used to determine Sw.
How can you tell if you need to use a shaly sand
approach or not?
If the formation has high shale volumes as seen
in core.
If CEC or Qv measurements on core indicate high
values.
Compare wetting phase saturations from
air-mercury and air-brine Pc data. If the latter
are significantly larger than the former then the
difference is due to clays (which do not
influence air/mercury saturations) and the need
for shaly sand interpretation is indicated.
The fresher the formation water the more
significant will be the effect of shale content.
At high salinity (100s of kppm) shale effects
become negligible even with substantial clay
content.
Examine the formation resistivity in sands if it
shows a dependence on shale volume you need to
use Shaly sand interpretation.
If in doubt as to the significance of shales
calculate Sw using the Archie equation and a
simple shaly sand equation (suggest the Indonesia
equation) and see how much difference the two
approaches make to Sw (and Sh)

79
Indonesia Equation

Has the advantage that it can be used without
core derived parameters (although core derived m
and n are preferred).
Equation developed by Poupon Leveaux)
Where, Swe Effective water saturation
(v/v) Øe Effective porosity
(v/v) a Tortuosity constant m Cementation
exponent
n Saturation exponent
Rw Formation water resistivity (ohm.m)
Rcl Clay resistivity (ohm.m)

80
Use of Indonesia Equation

Calculate Vcl from logs.
Use conventional methods for Vcl (typically GR
and D/N)
Calculate Øe from logs.
Effective porosity from density, sonic or
density/neutron logs
Cross-plot Rt versus Vcl to determine Rcl.
Determine Rcl as the value of Rt as Vcl tends to
1.
Investigate the need for Rcl variation by zone.
Compare saturations with Swirr from Pc data and
Dean-Stark saturations if available. Tune
parameters as necessary.

81
Waxman Smits Equation

Has the advantage that it does not require Vcl as
input and uses Øt rather than Øe. However it is
best applied when core measurements of Cation
Exchange Capacity (CEC) or Qv are available.
Equation developed by Waxman Smits
Where, Swt Total water saturation
(v/v) Øt Total porosity (v/v) a WS
Tortuosity constant m WS Cementation
exponent
n WS Saturation exponent
Rw Formation water resistivity (ohm.m)
B Cation Mobility (mho cm2/meq)
Qv Cation Exchange Capacity (meq/ml)

82
Use of Waxman Smits Equation

Calculate Øt from logs.
Calculate B using the Thomas equationWhere, B
Cation Mobility (mho cm2/meq) T Formation
temperature (ºC) Rw Formation water
resistivity _at_ T (ohm.m)
Obtain a relationship between Qv and Øt using
special core analysis data.
a m and n are best determined from SCAL.

83
Comparison of Total and Effective Saturations

If saturations are determined by a number of
different methods are to be compared care is
needed if water saturation is calculated with
reference to total porosity Swt is to be compared
with that calculated relative to effective
porosity, Swe.
Conversion from Swe and Swt is achieved by

84
Example of the Effect of Shaly Sand Analysis

Water salinity 11,000ppm Rw 0.2 ohm.m _at_ 200ºF
Hence from Thomas equation B 10.5
a1, m1.78, n1.33
Qv-2.086Ø0.55
Moderately shaly formation but relatively fresh
water.
Hence treat as shaly sand.
Comparison of log derived Sw with Sw/Height
Function and Dean-Stark data much improved.

85
Water Saturation Calculation in IP
86
Water Saturation Models

Selecting the default Sw equation on the Phi/Sw
setup window changes the default plot.
The interactive default plot has special
interactive parameter lines and crossplot
depending on the setup.
Changing the default Sw equation will not change
the Sw equation for any already created zones.

87
Water Saturation Effective Phi Models

Resistivity clay can be interactively picked from
the Rt / VWCL crossplot. Right mouse click in the
resistivity track to access this cross-plot.
Resistivity clay is adjusted to make Sw average
100 in the shaley wet zones.
Rxo clay is adjusted the same way so that Sxo is
100.

88
Water Saturation Total Phi Models

Total porosity
øt øe Vcl x øtclay
Clay porosity Øtclay
Entered as a fixed parameter
Calculated from density dry and wet clay
parameters
Best method of obtaining this is from core
analysis data

89
Water Saturation Dual Water

Rwb (Rw bound water) can be adjusted by moving
the Rwb parameter line in the Rwapp interactive
track.
Set the Rwf (Rw free water) parameter to give
100 water in the clean wet zones. Then set the
Rwb parameter to give 100 water in the shaley
wet zones.
Rmfb (bound flushed zone water) can be set in a
similar fashion.

90
Water Saturation Juhasz

The Cwapp / Qvn cross-plot can be created by
right clicking in the Rwapp track and selecting
from the drop-down menu.
Rw and the Bn parameter can be set interactively
by changing the end positions of the line. The
left edge sets the Rw. The slope of the line sets
the Bn parameter.
Adjust the Rw parameter to give 100 water in the
wet clean zones. Adjust the Bn parameter on the
crossplot to give 100 water in the shaley wet
zones.

91
Water Saturation Waxmann-Smits

The QVapp / PhiT_Recp cross-plot can be created
by right clicking in the Rwapp track and
selecting from the drop-down menu.
The interactive line is used to pick the a and
b parameters in the Qv equation. The user
should adjust the line to fit the data in wet
zones.
If the Qv value is correct then SwT should read
100 in the shaley wet zones.

92
Vsilt Index

For a given volume of clay we expect the
resultant Phie to be within a certain range.
If however the porosity is lower than this range
then something else must be reducing it.
This porosity reducing something else is what the
VSILT index represents.
It indicates that the porosity is lower than
expected and there must be something else other
than clay reducing it, This could be cement silt
or whatever.
It is purely for display purposes and does not
impact on porosity or Sw calculations.

93
Limits and Bad Hole

The effective porosity must be less than the
porosity limit line.
Phi Max and Delta Phi Max are entered parameters.
Phi Max is set to the maximum porosity in silt
free sand. It is used to calculate the silt
index. The Delta Phi Max parameter is adjusted to
remove unrealistic porosities.
The Vcl cutoff parameter will remove porosity in
shale zones. It is very useful for cleaning up an
interpretation.
The Vcl cutoff parameter can also be used to
boost the m Archie parameter in shales. This
has the effect of removing unlikely hydrocarbon
saturations in shales.

94
Limits and Bad Hole

Bad hole discriminator curves can be used (e.g.
caliper, den correction).
If the hole is flagged as bad then sonic porosity
is calculated.
Porosity will be the minimum of normal porosity
or the sonic porosity.
Normal porosity limits are still applied.

95
Linking Parameter Sets.

When you first run the Por/Sw the following
window will appear.
Ticking all three effectively joins the VClay and
Por/Sw parameters together as one.

96
Optional Comparison Curves

Optional porosity and Sw curves using differing
methods can be created.
This will add a comparison track to the
interactive log plot.
These comparison curves should not be used as
final output curves as they are not limited and
are also not solved iteratively.

97
Deterministic Petrophysics Net and Pay
98
Basic Interpretation Workflow Net and Pay
Definition

Gross Rock
Comprises all rock in the evaluation interval.
Net Sand
Comprises those rocks which may have useful
reservoir properties.
Sand is a generic oilfield term for
lithologically clean sedimentary rock.
Determined using a Vclay cut-off.
Net Reservoir
Comprises those rocks which do have useful
reservoir properties.
Determined using a porosity cut-off on Net sand.
Net Pay
Comprises the net sands that contain hydrocarbon.
Determined using a water saturation cut-off on
Net Reservoir

99
Net Reservoir Determination

Western Petroleum Industry Practice
Traditionally adopts rule of thumb cut-offs for
the evaluation of net pay.
The arbitrary nature of the cut-offs is
recognised.
Usually the cut-offs have been selected to
correspond to fixed permeability values
0.1 mD for gas reservoirs
1.0 mD for oil reservoirs
These nominal cut-offs are still commonly used.
Because permeability is not measured by logs the
normal practice is to relate core permeability to
porosity and/or other log-derivable parameters.
The precise type of permeability used to specify
the cut-off is not defined.

100
Determining Net Sand cut-offs

Determine using a Vcl cut off.
The cut off is generally arbitrary and of the
form Vcllt Cut-off.
The sensitivity of Net Sand count to the cut-off
is generally examined by determining the net-sand
for a range of cut-offs. The cut off should be
determined in an insensitive region of the
sensitivity plot if possible.
Cut-offs should be validated by comparison of
resulting Net sand with that observed in core.
If sands with laminations below log resolution
are encountered it is possible no net reservoir
will be resolved. In these cases cut-offs may not
be appropriate

101
Determining Net Reservoir cut-offs

Determined by applying an additional cut-off to
intervals that have passed the Net Sand critera.
Determine cut-offs equivalent to appropriate
permeability
Oil field k1mD
Gas field k0.1mD
Usually use a porosity cut-off equivalent to the
appropriate permeability cut-off in a cross-plot
of core permeability versus core porosity.
Permeability and porosity corrected to down-hole
conditions should be used.
Hence the Net Reservoir Criteria are of the form
VclltCut-off and ØgtCut-off.
The sensitivity of Net Reservoir count to the
cut-off is generally examined by determining the
Net Reservoir for a range of cut-offs. The cut
off should be determined in an insensitive region
of the sensitivity plot if possible (see next
slide).
Where reservoir can easily be identified in core
the net reservoir should be measured and compared
with the log net reservoir to tune the
cut-off(s).
Core photographs in natural and UV light may
assist the picking of net reservoir in the core.
Variation of the Net sand Vcl cut-off may be
useful to achieve this match.
If core data is not available it may be useful to
plot DensityVersus GR. A transition to a shale
density can sometimes be observed which serves to
define a GR or clay volume cut-off. See
cross-plot overleaf.
Comparison of net picked from logs with the
intervals seen to be flowing in the production
profile from a PLT can also be used to validate
the cut-offs adopted. Such comparison is not
however definitive since factors other than
reservoir quality influence which intervals will
flow.

102
Net Cut-offs Useful Plots
103
Determination of Net Cut-off using
Porosity/Permeability cross-plot

Determination of porositycut-off equivalent to a
1mDpermeability cut-off in an oil reservoir.

103
104
Determination of Net Pay

Net Pay is determined by the addition of a water
saturation cut off to the Net Reservoir
Criteria VclltCut-off and ØgtCut-off.
Net Pay defines the potentially productive
portion of the reservoir.
The cut off Sw is in most cases largely arbitrary
(typically 50 - 60).
Relative permeability curves can be used to
inform the choice of Sw cut-off Sw Critical.
Net Reservoir and Net Pay are used to determine
Reservoir summary zonal averages.
Versions of the log interpreted curves, set to
null outside the net sands, are often generated.
Numerical Flags are usually created for Net Sand,
Net Reservoir and Net Pay.

105
Reservoir Summaries in IP
106
Cutoffs and Summation Input Curves

Specify
Cut-off names
Short names
Interpreted curves to use
For each cut-off specify its type or logic.
Specify the type of averaging to be used.
TVD or TVT outputs can be selected by checking
the appropriate box and specifying the required
depth curve.
Note that additional curves can be selected for
averaging without being used as cut-offs.

107
Cutoffs and Summation Report Setup

Define Reports Required
Reservoir
Pay
Specify the cut-off values to be used for each
cut-off curve.
Specify which cut-offs are to be used for each
report using ?.
Can load formation tops to be used in averaging
via Load/Save ParameterSets

108
Cutoffs and Summation Output Curves

Specify output set
Specify Reservoir and Pay flags.
Specify names for curves to be cumulative in the
summaries

109
Cutoffs and Summation Run

Select Run
Select Yes to initiate Cutoff plot.
Cut-offs can be adjusted
Changed using sliders.
Enabled or disabled in individual zones by right
clicking in a track and selecting.
Zones can be adjusted
Click and drag boundaries in zone track.
Zones can be deleted if required.

110
Cutoff Parameters

Zone Depths
Displays Zone names and depths
Reservoir Pay Cutoffs
Displays cutoff curves and values.
Cutoffs can be selected or adjusted by zone.

111
Cutoff Sensitivity

Select Wells can be multiple
Cutoff
Curve
Lower Limit
Upper Limit
Step
Select Summary Parameter.
In this case Net Reservoir.
Select Zones for sensitivity analysis.
Make Plot.

112
Parameter Sets
113
Parameter Sets

Parameter Sets are created when any of the
zonable interpretation modules are run.
Clay Volume
Porosity and Water Saturation
Cutoffs and Summation
Mineral Solver
Basic Log Analysis
NMR Interpretation
TDT Standalone
TDT Time Lapse
Pore Pressure Gradient
User Programs

114
Parameter Sets

Each module when run is populated with a set of
parameters.
These starting parameters are then adjusted in
order to provide your interpretation.
The last set of Parameters run is stored in the
program memory for each module.
Alternative Parameter sets can be saved and later
recalled.
They can be saved into the database well .dat
files or out of the database into external ASCII
disk files.

115
Parameter Sets

As Parameter Sets share the same structure as
Tops Sets with name, top and bottom they can also
be displayed and used like tops sets.
Also tops sets can be used to populate Parameter
Sets.

116
Delete Parameter Sets Well

Selecting the Well gt Delete Parameter Sets'
option will delete an interpretation 'Parameter
Set' from the current, active well.
This is helpful if the current 'Parameter Set' is
found to be incorrect and the user wants to start
an interpretation again from the beginning.
This will not delete any Parameter Sets saved on
the hard disk.
Only the 'Parameter Sets' associated with the
currently-active well can be deleted.

117
Multi-well Parameter Distribution Multi-Well

Allows you to interpret one key well.
Then distribute the parameters you used in that
well to other wells in memory.
The parameters are distributed based on a common
set of formation tops.

118
Multi-well Parameter Distribution Multi-Well

'Copy using zone names' - If 'checked', will
allow the user to more-accurately distribute
'Parameter Sets' to multiple wells in an IP
project or to distribute parameters to multiple
penetrations of reservoir zones in a single
horizontal well.
Note this is a special case as the user is
required to be more rigorous in setting up the
zones in the interpretation modules. It is only
useful if the names of all zones are defined in
all the Sets being distributed and in the common
'Tops Set'.
The Distribute' button will distribute the
'Parameter Sets'. The user will be asked to
confirm whether or not to overwrite existing Sets.

119
Multi-well 3-D Parameter viewer

Viewgt3-D Parameter Viewer.
Allows interpretation parameters, such as Rw, and
Cut-off and Summation results, such as Average
Sw, to be mapped between wells and layers

120
Curve History

CHgt History Tab
Shows curve history
Origin
Author
Date of creation
Last update
Show Parameters Tab
Shows multiple interim steps
Tabulates Parameters Used
Can compare parameter differences between
multiple curves.
Can be output as text file

121
Movie

On the IP installation disk we supply a movie
file which takes the user through a quick look
Petrophysical interpretation.

122
Summary

Over the past few days you should have learnt
How IPs Database is structured
Loading data in from external files (LAS etc)
Presenting Data (Logplots, Crossplots,
Histograms)
Editing Data (Depth shifting, splicing etc)
How to Run calculations (single or multi-line
formulas etc)
Use the clay volume, Por/Sw and Cutoff
deterministic petrophysics modules to derive
Vclay, Porosity, Sw and N/G
Understand parameter sets (how to save and recall
them)
Use Multi-Well workflows
We hope you have enjoyed this insight into the
basic functionality of IP.
Thank You

123
Interactive Petrophysics (IP4)Advanced
124
Interactive Petrophysics Advanced Contents

Statistical Curve and Facies Analysis Fuzzy
Logic in IP
Statistical Curve Prediction Multi-linear
Regression in IP
Statistical Curve Prediction Neural Nets in IP
Facies Prediction Cluster Analysis in IP
Monte Carlo Analysis in IP
Capillary Pressure and Saturation-Height
Principals
Execution in IP
Pore Pressure Calculations in IP

125
Statistical Curve Facies Prediction

Fuzzy Logic

126
Fuzzy Logic

Fuzzy logic is the logic of partial truths
The statement, today is sunny
100 true if there are no clouds
80 true if there are a few clouds
50 true if it's hazy
0 true if it rains all day
This is mathematics of probabilities
If we can work out the probability of each event
outcome then we can predict the most likely
result
More details read The Application of the
Mathematics of Fuzzy Logic to Petrophysics -
Steve Cuddy

127
Fuzzy Logic