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The AAPG/Datapages Combined Publications Database
Houston Geological Society Bulletin
Abstract
Abstract: Agbami Field, Nigeria—Addressing Challenges and Uncertainty
By
ChevronTexaco Overseas Petroleum
Agbami Field was discovered in late 1998, approximately 105
km offshore Nigeria in the Gulf of Guinea. The field is located
in Blocks OPL216 and 217 in approximately 1500 meters of water.
The structure is a northwest to southeast trending detachment fold
anticline covering an area of 180 km2 at spill point. The discovery
well, the Agbami No. 1, was drilled by Star Deep, a wholly owned
subsidiary of Texaco, Inc. acting as technical advisor to FAMFA, an
indigenous Nigerian oil company. Star Deep brought Petrobras in
as a partner and followed the discovery with three appraisal wells
and one sidetrack in Block OPL216, plus Statoil drilled the Ekoli 1
well into the same structure in adjacent Block OPL217. In late 2003
and early 2004, drilling resumed with ChevronTexaco, also through
Star Deep, adding the first 2 wells from the development plan. After
a short drilling pause to acquire seismic
data, these wells will be
followed by further development drilling later in 2004. All wells to
date have penetrated oil bearing sands. The field is a world class
development opportunity with significant resources.
The pay intervals at Agbami field consist of two principal zones. The primary reservoirs are in the 17 million year old (MY) sands and contain about 80% of the reserves. These objectives include slope channel, slope fan, and basin floor fan facies that offer both stacked and isolated reservoir objectives. Secondary reservoirs are present in the 13MY/14MY/16MY sands. These shallower productive zones are comprised of channel and levee-overbank facies.
The seismic
reflections from the shallower, secondary reservoirs
occur above the water bottom multiple and are of relatively good
quality. Amplitude extractions of both near and far angle data
match predicted AVA models. We can interpret stratigraphic and
fluid changes from the
seismic
data at this level.
However, the seismic
data from the deeper, main pay intervals in
the 17MY interval suffer from several data
limitations. Principal among these is significant
multiple energy contamination.
Multiple generating surfaces exist not only at
the water bottom, but also at other shallow
horizons below mudline. The energy from
these multiples occurs at the same time as
the main pay interval primary reflections
over much of the field, seriously degrading
the data, especially in the pre-stack domain.
Earlier processing of the data during the
exploration and appraisal phases of the field,
while attenuating the multiples, did not adequately
resolve the problem. Consequently,
extracted amplitudes from the 3D
seismic
data did not follow expected Class II AVA
behavior. Recent reprocessing efforts by
ChevronTexaco using a Gaussian beam
Unnumbered Figure. Reservoir Model Framework.
End_Page 19---------------
method for attenuation of the multiples have given encouraging
results that should allow better characterization of the reservoirs
from seismic
in future reservoir models.
Additionally, wavelet estimations from the seismic
data indicate
that the frequency content is relatively low, limiting the ability of
the
seismic
to resolve pay sands. Multi-sand intervals tend to
image as low frequency, high amplitude far-angle reflectors with
typically two or three sands imaged by one peak-trough-peak
seismic
event. The minimum sand thickness detectable at the
main pay intervals in these data is about 30 meters.
Also, reflectors from the inboard limb of the fold at the northwest end of the structure have diminished stacked amplitude responses and in general, the inboard limb is less well imaged than the outboard limb. Shallow toe thrusts north of the field appear to be masking far offset traces that would normally contribute to the expected high amplitude far angle reflections of oil-bearing sands. To record higher angle traces in this area, and hence better map the sand distribution, we are proposing to re-acquire data parallel to this thrust front.
With the limited frequency content of the seismic
data, stratigraphic
information from
seismic
was restricted to the
identification of thick, sandstone-prone fairways that were
mapped throughout the field area as architectural elements in
the reservoir model. Tying to the low frequency inversion data
placed the
seismic
tops and bases of these architectural elements
in the shales above and below the corresponding sandstone unit
in the well logs. This architectural element interpretation
forms the basis for well-to-well correlation, field volumetrics and
reservoir
modeling
.
A channelized sheet system was selected as the most likely
depositional model for the 17MY reservoir based on the available
seismic
and well data. To fully capture the potential range
of depositional systems and associated in-place volumes and
connectivities caused by variable net-to-gross and reservoir
architecture, four end-member models were also created:
isolated channel, isolated sheet, amalgamated channel and
amalgamated sheet.
The resulting earth models (three hundred in all) were statically and dynamically ranked using streamline flow simulation to select low-, mid-, and high-case earth models for use within Experimental Design (ED) to supply probabilistic production forecasts. In addition to a range of earth models, a range of other geologic and petrophysical parameters were supplied for use in ED, including permeability, permeability contrast, number of faults and fault seal/transmissibility.
The limited number of wells and low resolution seismic
data
result in considerable uncertainty with respect to many elements
of the geological model. To fully understand the range and impact
of these uncertainties, probabilistic volumetric analyses were
completed using Crystal Ball. The P5-P50-P95 in-place probabilistic
volumes were used as a benchmark to verify that the range
of in-place hydrocarbons in the earth models was reasonable.
This workflow provided a methodology for testing the Agbami field development plan against a wide range of key uncertainties. Key challenges faced by the project team included:
- Building a robust range of earth models with low resolution
seismic
and limited well data.
- Finding suitable geologic analogs, including data on input parameters such as object geometries.
- Gaining consensus and buy-in with respect to input parameters and methodologies from a large subsurface team, peers and partners.
- Building the framework, both structurally (i.e., properly
modeling
a thrust fault in close proximity to the wells) and stratigraphically (i.e., architectural elements that laterally pinch-out).
- Model resolution (vertical and aerial) vs. model size.
Simulation and Results
Field data, laboratory data and analog data were incorporated
into a range of reservoir simulation models. The field data
included appraisal well logs, cores, 3D seismic
, fluid samples,
pressure data and drill stem tests.
Experimental Design was used throughout the evaluation to obtain the maximum information with the minimum computational effort. The results from this process facilitated the identification of the key uncertainties and provided direct input into economic models for decision analysis. During each phase of the process key parameters of uncertainty were identified and ranked in terms of project impact. Field development options were evaluated in distinct phases over the full range of uncertainty.
In Phase Two of the evaluation, the pressure maintenance schemes were selected. Crestal gas re-injection with peripheral water injection was chosen for the 17MY reservoir. Crestal gas re-injection only was selected for the 14MY and 16MY reservoirs. These approaches to pressure maintenance deliver an effective full-life gas disposition strategy for the Agbami Field. The facility capacity requirements were also selected during this phase.
In Phase 3 of the evaluation the well count parameter was investigated and the optimum number of 38 wells was selected. Production profiles were generated and presented in terms of P10, P50, and P90.
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