Bulletin of Scientific Contribution

ABSTRACT

This paper shows how to model the 3d complex carbonate reservoir by combining deterministic and stochastic method. 3d facies model is the most important step in building reservoir static model because the distribution of another properties will depends on this model. a good facies model is needed in building a good model. The nature complexity of carbonate facies  itself makes the modeling are even more chalangging. Deterministic geological interpretation is  modelled by trend modeling while the rock type distribution is distributed inside each facies stochastically. This field is divided into five zones. These zones represent depositional cycle occurred within carbonate formation. The facies is divided into four facies; Reef, Lagoon, Platform, and slope. a reservoir rock type was done by using RT distributions.  According to Geological concept, reservoir quality distributions have different trend either vertical or horizontal. Horizontally, a good reservoir should be located in Reef facies and the poor reservoir quality should be located in slope facies. Vertically, reservoir quality should get better from bottom to top in every reservoir zone

Anna Conti, Elisa Sacchi, Marta Chiarle, Giovanni Martinelli, Giovanni Maria Zuppi, 1998. Geochemistry of the formation waters in the Po Plain (Northern Italy): anOverview. Applied Geochemistry. November 51-65, 1998.

Cathles, L. M., Smith, A. T., Thermal constraints on the formation of Mississippi Valley-type lead-zinc deposits and their implications for episodic basin dewatering and deposit genesis, Economic Geology, 1983, 78: 983—1002.

Deutsch, C.V. and Journel, A.G. 1998. GSLIB: Geostatistical Software Library and User’s Guide, second edition. Oxford, UK: Oxford University Press.

Deutsch, C.V. 2002. Geostatistics Reservoir Modeling. Oxford, UK: Oxford University Press.

Gresko, M., Suria, C., Sinclair, S., 1995. Basin evolution of the Ardjuna rift system and its implications for hydrocarbon exploration, offshore NW Java, Indonesia. In: Proceedings of Industrial Petroleum Association 24th Annual Convention, October 1995, pp. 147–161

Journel, A G, and Deutsch, C V, 1998. GSLIB Geostatistical software library and users guide, Second Edition, Oxford University Press, New York

Journel, A.G. and Ying, Z. 2001. The Theoretical Links Between Sequential Gaussian, Gaussian Truncated Simulation, and Probability Field Simulation. Mathematical Geology 33: 31.

Karsten Michael, 2001. Origin and Evolution of Formation Waters in the West Central Part Of Alberta Basin. Rock the Foundation Convention, June 18-22, 2001. Canadian

Society of Petroleum Geologists.

Lucia, F.J. and R.D. Conti, 1987. Rock fabric, permeability, and log relationships in an upward-shoaling, vuggy carbonate sequence. The University of Texas at Austin, Bureau of Economic Geology, Geological Circular 87-5, 22 p.

Noble, R.A., et al., 1997. Petroleum systems of Northwest Java, Indonesia. In: Howes, J.V.C., Noble, R.A. (Eds.), Proceedings of International Conference on Petroleum

Nurmi, R.D., 1984, Carbonate pore systems: porosity/permeability relationships and geological analysis: AAPG Bull. V. 68, no. 4, p. 513-514.

Systems of SE Asia and Australasia. Indonesian Petroleum Association, pp. 585– 600.9

Stave, K. A., and Cloud, S., 2000. Using system dynamics models to facilitate public participation in Water Resource Management: a pilot study using the Las Vegas, NV Water System. Proceedings of the 18th International Conference of the System Dynamics Society. August 77–10, 2000. Bergen, Norway.

Wang, R.F.P. and F.J. Lucia 1993. Comparison of empirical models for calculating the vuggy porosity and cementation exponent of carbonates from log responses. The University of Texas at Austin, Bureau of Economic Geology, Geological Circular 93-4, 27 p

Xie Xinong, Jiao J. Jiu, LI Sitian, and Cheng Jianmei, Salinity variation of formation water and diagenesis reaction in abnormal pressure environments, Science in China (series D), March, 2003. China