The present invention is a rock physics model that relates generally to the field of exploration geophysics, and more particularly to identification and characterization of potential hydrocarbon (oil, gas, and natural gas liquids) or CO2 storage reservoirs in onshore and offshore sedimentary basins, using prestack inverted seismic (Acoustic impedance and Vp/Vs ratio) data acquired onshore or offshore. The invention also relates to subsurface formation interval P-wave velocity (Vp), S-wave velocity (Vs), and bulk density (RHOB) measured from borehole logs in a well as means to calibrate with the output obtained from the inverted data from seismic.
The prestack inversion of seismic data has in recent years become a valuable tool in investigating potential hydrocarbon-bearing formations. Seismic surveys in general, when used in combination with other available geophysical, borehole, and geological data, provide useful information about the structure and distribution of subsurface rock properties and their interstitial fluids. Oil companies employ interpretation of such seismic data for selecting the sites to drill oil and gas exploratory and development wells. The seismic surveys while providing maps of geological structures also yield useful information for rock typing, fluid identification and quantification.
When borehole logs are available from nearby wells, seismic survey and the subsequent inverted data can be enhanced and calibrated by combining it with the log data.
Extracting reservoir properties from seismic has always been an objective of geophysicists since commercial seismic has been used for hydrocarbon exploration. Standard reservoir characterization workflows comprise seismic inversion and amplitude-variation-with-offset (AVO) or amplitude-variation-with-angle (AVA) analysis. The change in amplitude with angle has long been demonstrated by Zoeppritz in 1919 (Zoeppritz, 1919). Since the Zoeppritz equations were not intuitive, many approximations to solve AVO/AVA have been presented over the years (e.g., Aki and Richards, 1980; Fatti et al., 1994; Goodway et al., 1997; Shuey, 1985; Smith and Gidlow, 1987; Verm and Hilterman, 1995).
Since AI is a function of zero-offset reflection, an elastic impedance (EI) can be computed for non-normal incident angles (Connolly, 1999). The EI contains fluid information. The EI method is further improved by Whitcombe et al. (2002), calling it Extended Elastic Impedance (EEI) with the option of a theoretical rotation angle (chi) from −90° to +90° in the intercept-gradient crossplot space. Particular rotation angles are related to elastic parameters, such as Lambda-Mu-Rho (LMR) (Goodway et al., 1997), and the compressional (P) to shear (S) wave velocity ratio (Vp/Vs). The LMR parameters are useful lithology and fluid discriminators.
Yenwogfai et al. (2017) disclose a method for the determination of shale volume (Vsh) and teaches an integrated approach used to estimate effective porosity (PHIE), shale volume (Vsh), and sand probability from prestack angle gathers and petrophysical well logs comprising combining model-based prestack inversion outputs from a simultaneous inversion and an extended elastic impedance (EEI) inversion into a multilinear attribute regression analysis to estimate absolute Vsh and PHIE seismic attributes. Moreover, Porosity-Impedance relationships and linear regression coefficients link EEI to porosity and shale volume.
Bredesen et al. (2021) disclose a measurement-based data processing method for the determination of shale volume, porosity, P-velocity (Vp), S-velocity (Vs), density (ρ), acoustic impedance (AI) and Vp/Vs-ratios. The study comprises a combination of both prestack and post-stack seismic inversion data in 2D and 3D. Elastic moduli and densities for the mineral and fluid constituents are used in the rock physics modelling, whereby calibrating the facies-dependent rock physics model, the seismic response of varying a particular reservoir parameter, e.g. the porosity, the mineral composition, cementation, and compaction can be studied in a quantitative manner, for example total shale as a function of AI and Vp/Vs for varying porosity.
Recently, Lehocki et al. (2019) suggested an inversion of the Zoeppritz equation (Zoeppritz, 1919) to obtain the ratio of the density of two layers at the layers' interface. The distinction seemed possible employing the density ratio technique even in (initially) cemented rocks as the diagenetic cement dampens the fluid effect on elastic properties. This technique is in a developing stage and needs testing in other lithology-fluid environments.
Regarding the patents, a U.S. Pat. No. 5,583,825A Published on Dec. 10, 1996 related to a method for deriving reservoir lithology and fluid content for a target location from prestack seismic reflection data. The results of the inversion process are a set of subsurface elastic parameters for both the target and calibration locations. Relative magnitudes of these parameters are compared, together with the known subsurface lithology and fluid content at the calibration location, to extract the subsurface lithology and fluid content at the target location.
WO2015191971A1 published on Dec. 17, 2015 disclosed a method for determining shale volume comprising formulating a model based on measurement data from several instruments, wherein seismic attributes may include acoustic impedance, density, Vp/Vs, S-impedance or other anisotropic parameters of areas in a subsurface of the earth, and the seismic inversion encompasses many different seismic data processes, which may be done pre-stack. The rock model may be calibrated and be run iteratively for a survey area and discriminate main rock families and to suggest realistic starting values for both porosity and water saturation and the volume of shale. Other parameters or attributes used in the model include porosity, mineralogy and cementation. The forward modeling in this procedure was based on the existing rock physics and cross property models.
US2008015782A1 published on Jan. 17, 2008 demonstrated an inversion using rock physics model to solve for the lithologic properties and porosity using an iterative process and converging to a solution by optimizing the L1 norm of the difference between bulk elastic properties obtained from the seismic data and values obtained for the same properties by forward modeling with the rock physics model. This was an iterative process converging to a solution by finding a maximum a posteriori estimate (MAP) of the lithologic properties and porosity using model and data covariance matrices estimated from well data and inversion results at the well.
U.S. Pat. No. 7,373,251B2 published on May 13, 2008 utilized acoustic impedance (AI) values from seismic data to predict a designated rock or fluid property in a subsurface geologic volume. In the procedure, a first predicted value of the designated rock or fluid property is compared to the seismic value of acoustic impedance to determine a difference between the predicted and seismic values of AI. The difference is gradually reduced by making a subsequent prediction.
All these methods, however, were mostly qualitative, or used indirect ways to solve for the shale volume. There had been a need to directly relate acoustic impedance with the Vp/Vs ratio with a flexibility to calibrate locally, in consideration of the rock matrix, fluid properties and the in-situ conditions using bore-hole data.
Therefore, the present invention's main objective is to provide a better and innovative method for the estimation of shale volume in subsurface rock formations using the acoustic impedance and Vp/Vs ratio obtained by inversion from seismic data. The above-mentioned shortcomings associated with the prior art are addressed by way of the following novel improvements.
1) Coming up with a new rock physics model that relates the Vp/Vs ratio with acoustic impedance (AI), by-passing the use of elastic moduli (Bulk modulus, Shear modulus etc.) typically used to establish the relationship between these properties. Circumvent the use of Gassmann equation (Gassmann, 1951) for fluid substitution.
2) The Gassmann equation is useful; however, it requires the input variables at moduli level (Bulk modulus, Shear modulus etc.) instead of directly using the P- and S-wave velocities.
3) An essential part of this method is that the model can be calibrated using the nearest well penetrated in the zone of interest. The calibration yields the stress level/cementation factor, mineralogy factor, target shale's P-wave velocity (Vpsh) and density (ρsh).
These upper mentioned benefits are aimed at addressing the deficiencies in the prior art. The improved method is disclosed according to the appended independent claim. Advantageous further developments are subject of the dependent claims.
A first aspect of the present invention relates to a method for the estimation of shale volume in a reservoir comprising the following steps:
Other features and advantages of the invention will be better understood from the following detailed description and the attached drawings in which:
The method of the invention comprises the use of AI and Vp/Vs inverted from seismic data, calibrated by well-logging tools making it possible to separate the influence of shale from water or hydrocarbon bearing sandstone, thus, to estimate the shale volume within sedimentary rocks. Subsurface shaly reservoirs may generally consist of three components: (1) the rock mineral matrix (e.g., quartz grains), (2) shale/clay, and (3) the fluid(s) within the pore space (water, oil/gas).
Data obtained from the wellbore may include so-called “well log” data. Such data are typically recorded and presented against depth in the subsurface of various physical parameters measured by probes lowered into the wellbore. Such probes may include, for example, electrical resistivity, compressional and shear wave sonic interval time, bulk density, neutron slowing down length, neutron capture cross-section, natural gamma radiation, and nuclear magnetic resonance relaxation time distribution, among others. The well logging procedure comprises recording of magnitudes of various above mentioned physical properties within a bore-hole using an array of logging probes (
Seismic data acquisition is routinely performed both on land and at sea. At sea, seismic vessels deploy one or more cables (“streamers”) behind the vessel as the vessel moves forward. Each streamer includes multiple receivers in a configuration generally as shown in
One embodiment of a method according to the invention, will be explained with reference to the flow chart in
Acoustic impedance (102) and Vp/Vs ratio (103) are standard outcome of prestack inversion of seismic data. The seismic procedure yields independent measurements within a wide areal extent.
In a salt water-wet porous rocks, the two curves, i.e. acoustic impedance and Vp/Vs ratio respond to porosity. But in case of rock pores filled with hydrocarbon, or CO2 both the acoustic impedance and Vp/Vs measurements respond due to two main effects: 1) the acoustic impedance responds to the presence of porosity and low-density, low-velocity fluids, and 2) the Vp/Vs ratio measurements respond to the rock matrix and pore fluids (gas/oil, CO2). In a rock comprised of 100% matrix content with zero porosity (
The two properties obtained from the well log data are chosen also so that the collection of pairs of values of acquired parameters (namely the acoustic impedance on the one hand and the Vp/Vs ratio on the other) at least partly correspond to the equal shale volume (Vsh) for sedimentary rocks comprising a given proportion of matrix or water are substantially identical.
This selection of parameters substantially simplifies the operation for estimating the shale volume. In a cross-plot of the two chosen properties, the collection of pairs of values of the said parameters are spread over iso-volumetric content curves. A diagram may be drawn where the iso-volumetric content curved lines run parallel to a reference curved line (34) representing 0% (or 0 fraction) Vsh which joins a perceived water pole (32) with a 100% (or 1 fraction) mineral matrix pole (31).
If we assume the rock consists of a mineral matrix, shale/clay and water-filled matrix porosity then collection of pairs of values of the parameters serving as reference which is represented by the iso-volumetric content curved line equivalent to a given shale percentage within a rock obtained experimentally from values of the two chosen parameters acquired from the data.
This method of determining the G (mineralogy/shaliness coefficient) and n (stress/cementation coefficient) to align the 0% (or 0 fraction) Vsh zone data along the 0% (or 0 fraction) Vsh reference line implies that, among the zones crossed by the well, some are water-bearing, non-shaly, clean sandstone. This is possible if we assume the data pairs with low Vp/Vs ratio values occasionally showing a trend partly parallel to the 0% (or 0 fraction) Vsh reference line (34). It is possible to verify the existence of such zones by comparison with other shale volume calculation techniques within a basin. The pairs of values are represented by the set of iso-volumetric content curved lines, from the line with 0% shale volume to the line representing 100% shale volume (35), constrained by a shale pole (33), defined by the shale's P-wave velocity (Vpsh) and density (ρsh). The Vp/Vs which corresponds to that is then obtained by applying the following relation (Lee, 2003):
where Vp is P-wave velocity, Vs is S-wave velocity, G is mineralogy/shaliness coefficient, α is Vs/Vp ratio of the mineral/rock matrix, n is stress/cementation coefficient, and we derived the rock pore volume ϕ as:
where VPma, VPsh and VPw are the P-wave velocities of the mineral matrix, target shale and water respectively, ρma is density of mineral grains, ρsh is density of target shale, ρw is density of water, AI is acoustic impedance and Vsh is the target shale volume (in fraction). Changing the mineralogy/shaliness coefficient ‘G’ results in a vertical static shift in the curved iso-volumetric content lines. The stress/cementation coefficient ‘n’ controls the slope of the iso-volumetric content curved lines and may be selected in a formation zone depending on level of stress, compaction, or cementation. The matrix, shale and fluid related constants may be taken from Mavko et al (2009) and vendors' logging chart books.
From this function (equation 1) we are able to define a set of lines representing different shale volumes parallel to the reference zero percent Vsh curve (that is usually a brine/water saturated sandstone) onto the Acoustic impedance-Vp/Vs ratio function plane (
Rearranging the equation the shale volume can be calculated (in fraction) using the following equation:
Until now the G, n, Vpsh, and ρsh are unknown. Plotting the well data (41) onto AI-Vp/Vs plane (
Putting both the AI (
The technical solution is only one embodiment of the present invention, to those skilled in the art, the present invention discloses a fundamental principle of the method and applications, straightforward to make various types of modifications or variations, the method is not limited to the specific embodiments of the present invention described above, and therefore the manner described above are only preferred and is not in a limiting sense.
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Yenwongfai, H. D., Mondol, N. H., Faleide, J. I., Lecomte, I., and J. Leutscher (2017): “Prestack inversion and multi-attribute analysis for porosity, shale volume, and sand probability in the Havert Formation of the Goliat Field, SW Barents Sea”, Interpretation, V. 5, p. 1-54. Zoeppritz, K. (1919): “Über Reflexion and Durchgang seismischer Wellen durch Unstetigkeitsflächen: Nachrichten von der Gesellschaft der Wissenschaften zu Göttingen, Mathematisch-Physikalische Klasse”, v. 1919, p. 66-84.
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20210088 | Jan 2021 | NO | national |
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63140896 | Jan 2021 | US |