PETROPHYSICAL ROCK TYPE-BASED RESERVOIR CHARACTERIZATION OF EARLY MIOCENE CARBONATE RESERVOIRS OF BATURAJA FORMATION, RAMA FIELD, SUNDA BASIN
Rama Field is located in the southern part of Sunda Basin. Its main reservoir, the Upper Baturaja Unit carbonate contains most of the oil resources in Rama Field, yet, only 12% of these have been produced to date. Future water injection and redevelopment plans of this field, as the consequence,...
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| Format: | Theses |
| Language: | Indonesia |
| Subjects: | |
| Online Access: | https://digilib.itb.ac.id/gdl/view/73048 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Rama Field is located in the southern part of Sunda Basin. Its main reservoir, the
Upper Baturaja Unit carbonate contains most of the oil resources in Rama Field,
yet, only 12% of these have been produced to date. Future water injection and redevelopment plans of this field, as the consequence, require detail analysis
through static and dynamic approaches. This thesis focuses on the petrophysical
rock type–based static reservoir characterization through the identification of rock
type, its composition and distribution. Hence, the main goal to obtain a
comprehensive understanding of the petrophysical properties of the reservoir can
be achieved.
Core data with a total length of 410 ft from four wells, 305 core plugs, each of
them is measured for its porosity and permeability and sampled for thin section
analysis, combined with 108 well data are used in this study. Facies, facies
association and diagenetic history analyses are performed to understand the
influence of facies, depositional environments and diagenesis to the development
of petrophysical rock types (PRT). Petrographic analysis plays important role in
the identification of rock types through the observation of pore types, pore sizes
and pore associations. Six rock types are identified, (1) PRT 1–vuggy porosity and
moldic macropore association, (2) PRT 2–mudstone micropore and moldic
macropore association, (3) PRT 3–intergrain meso-macropore association,
(4) PRT 4–mudstone micropore and moldic mesopore association, (5) PRT 5–
mudstone micropore and intergrain micro-mesopore association, and (6) PRT 6–
mudstone micropore.
Three-dimensional reservoir characterization through 3-D reservoir modeling is
performed for facies, PRT and PRT-constrained porosity and permeability models.
The modeling results show strong consistency between petrophysical properties
and the underlying rock type models. High porosity and permeability values are
mostly in association with reservoir quality rock types, those are PRT 1, PRT 2
and PRT 3. Reservoir quality evaluation reveals a strong relationship between the
types, composition and spatial distribution of PRT and well’s productivity. PRT
1-dominated wells in majority exhibit high productivity (> 1,000 bfpd), PRT-2
dominated wells mostly show moderate productivity (500–1,000 bfpd), whereas
the low productivity wells (< 500 bfpd) are commonly dominated by PRT 3. |
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