Non-Porous Lithology Triggers
Some sedimentary rocks have apparent porosity indicated by various
logs, but are truly non-porous. Such rocks as coal, anhydrite,
gypsum and salt fall into this category. In order to discriminate
these rocks, and set the porosity value to zero, specific
trigger levels are for each log to help identify these minerals. The
number of logs required to exceed their trigger level, before
the zone is described as non-porous, is also needed. It is called
the lithology trigger level.
For example, to formulate a logical operator from the above rules
for coal, select the individual trigger logic for each log type:
1: E = (RESD > RTTRIG + PHIN > NTTRIG + PHID > DNTRIG
+ DTC > DTTRIG + GR < GRTRIG)
2: IF E >= G
3: AND G # 0
4: THEN PHIe = 0
5: AND MinrlFrac = 1.00 - Vsh
6: AND MinrlCount = MinrlCount + INCR
7: IF MinrlFrac > 0.0
8: THEN Vmin1 = 0.0 AND Vmin2 = 0.0 AND Vmin3 =
0.0
Zone is defined as a sedimentary mineral (coal, anhydrite,
gypsum, salt, rtc) and PHIe = 0.00 if the positive triggers
(E) equal or exceed the trigger level (G). Otherwise, PHIe = porosity from whichever
porosity method was used in the calculation. The MunrlCount term
accumulates the thickness, which is useful in evaluating, for
example,
coal bed methane projects.
Where:
MinrlCount= cumulative mineral thickness (feet or meters)
MinrlFrac = fraction of rock volume that is not shale (for
plotting
on depth plots (fractional)
DTC = sonic log reading (usec/ft or usec/m)
DNTRIG = density trigger (fractional)
DTTRIG = sonic trigger (usce/ft or usec/m)
E = sum of triggers which are exceeded
G = coal trigger level (0 = don’t check, 1 to 5 = number
of triggers needed to indicate specified lithology)
GR = gamma ray log reading (API)
GRTRIG = gamma ray trigger (API)
INCR = digitizing increment (feet or meters)
NTTRIG = neutron trigger (fractional)
PHID = density log reading (fractional)
PHIe = effective porosity assigned to this zone
PHIN = neutron log reading (fractional)
RESD = resistivity log reading (ohm-m)
RTTRIG = resistivity trigger (ohm-m)
COMMENTS:
The expected lithology in a zone will determine which zero porosity
rocks should be triggered. The logic level is determined by how
many logs are available and how well they resolve the lithologic
problem.
Logical triggers can also be used when porosity is not zero. For
example, in a limestone-dolomite-anhydrite sequence with only
density and neutron data, the two mineral model could be used to
obtain limestone and dolomite fractions, and an anhydrite
trigger could be used to define pure anhydrite beds. This would
eliminate the need for manual zoning.
RECOMMENDED
PARAMETERS:
* |
COAL |
ANHYDRITE |
GYPSUM |
SALT |
|
|
|
|
|
RESD |
>RTTRIG |
>RTTRIG |
>RTTRIG |
>RTTRIG |
PHIN |
>NTTRIG |
<NTTRIG |
>NTTRIG |
=NTTRIG+/-NTX |
PHID |
>DNTRIG |
<DNTRIG |
>DNTRIG |
>DNTROG |
DTC |
>DTTRIG |
=DTTRIG+/-3 |
=DTTRIG+/-3 |
=DTTRIG+/-DTX |
GR |
<GRTRIG |
<GRTRIG |
<GRTRIG |
<GRTRIG |
PhiFLAGS |
"C" |
"A" |
"G" |
"S" |
|
NUMERICAL EXAMPLE:
1. Assume the trigger levels as for coal in the above table, and
data as follows:
RESD = 350 ohm-m
PHIN = 0.45
PHID = 0.45
DELT = 328 ohm-m
GR = 15
LITH = COAL
RTTRIG = 200 ohm-m
NTTRIG = 0.40
DNTRIG = 0.40
DTTRIG = 300 ohm-m
GRTRIG = 50
Then all five tests are true and zone is coal.
2. If RESD = 180, then four tests are true and one is false. Zone
is coal, if G = 4 and not coal if G = 5.
3. Assume instead:
RESD = 180
PHIN = 0.30
PHID = 0.45
DELT = 300
GR = 20
Then only two tests are true and three are false. If G > 2,
then the zone is not coal, and is probably a zone with bad hole
conditions.
4. If G = 0; then zone is not coal, regardless of the number of
true tests.
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