SIMPLE ROCK PHYSICS TEMPLATE: A MODIFIED FAWAD â MONDOL MODEL
The process of describing physical properties in reservoir characterization is generally done by estimating the two main target physical properties, namely porosity (????) and hydrocarbon fluid saturation (SFL). Fawad and Mondol provide a simple approach in creating an RPT (Rock Physics Template)...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/86834 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The process of describing physical properties in reservoir characterization is
generally done by estimating the two main target physical properties, namely
porosity (????) and hydrocarbon fluid saturation (SFL). Fawad and Mondol provide a
simple approach in creating an RPT (Rock Physics Template) as a quantitative
approach to perform the desired target physical property description. The RPT is
simply constructed using a combination of Wyllie's Time Average, bulk density, and
Lee velocity ratio equations and has the flexibility to fit the RPT in AI vs ????????/????????
domain to the data by adjusting the model parameters G (controls the vertical static
shift) and N (controls the slope). Despite its simplicity and flexibility, the RPT has
incompatibilities with the concept of rock physics. These include the relationship of
velocity ratio that only changes with porosity, the absence of critical porosity as
the end-point of the RPT model, and the lack of a workflow to obtain model
parameters, G and N, that fit the data. Therefore, this study focuses on modifying
the Fawad and Mondol RPT model to be more in line with rock physics concepts
and establishing a workflow to apply this approach appropriately. The research
results show a modified Fawad and Mondol RPT model that is consistent with rock
physics concepts. These include a modified velocity ratio relationship that
considers both porosity and fluid saturation in accordance with the Gassmann
concept, determination of critical porosity using the Nur Model to complete the
end-point information in the RPT, and a workflow to obtain model parameters, G
and N, that fit the data. This workflow utilizes the integration of various
approaches, namely CPEI (Curved-Pseudo Elastic Impedance) attributes to
regularize the random pattern of fluid saturation, histogram matching to align the
statistical behavior of the model to the data, and forward modelling to obtain the
best model parameters, G and N, based on the smallest misfit. Testing this workflow
on synthetic and field well data shows the reliability of the proposed workflow
based on the best model parameters, G and N, obtained, where the resulting model
has a high correlation with the reference data |
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