In the resource recovery industry, information about a formation (i.e., the rock that is drilled through) can affect decisions about drilling and production. During the drilling process, rock samples are produced as drill cuttings. The drill cuttings from different sections of the borehole can provide information about the different types of formations that are encountered during drilling. Analysis of the drill cuttings represents a quick and continuous analysis technique when compared with wireline logging, for example, which requires introducing tools into the borehole. Prior analysis of drill cuttings required extensive and careful treatment of the cuttings or specific particle sizes. Thus, the industry would benefit from a multi-frequency dielectric coaxial probe for formation analysis.
The following descriptions should not be considered limiting in any way. With reference to the accompanying drawings, like elements are numbered alike:
A detailed description of one or more embodiments of the disclosed apparatus and method are presented herein by way of exemplification and not limitation with reference to the Figures.
As previously noted, analysis of drill cuttings offers a quick approach to formation evaluation without the need for specialized downhole tools. Prior analysis of drill cuttings required treatment and sizing of the cuttings. Dielectric spectroscopy techniques require less treatment of the cuttings. According to one or more embodiments of the invention, a multi-frequency dielectric coaxial probe is used for formation analysis. Specifically, drill cuttings are put in a host fluid to form a medium under test (MUT). A multi-frequency dielectric coaxial probe is lowered into the MUT, and a voltage is applied at different frequencies. The resulting reflected voltage is measured and operated on to determine different characteristics that indicate formation properties. The comparison of results obtained using different host fluids provides additional insights, as detailed.
Referring to
A reflected voltage is measured by the probe 110. The probe 110 is excited by a reference voltage at one frequency at a time. The reference voltage generates a transverse electromagnetic wave (TEM) in the dielectric material 140. At the interface between the probe 110 and the MUT 150, two waves, generally indicated as 160, are generated as the reference wave. One is a transmitted wave into the MUT 150 and the other is a reflected wave back to the probe 110. The reflected wave has a voltage that is measured by the probe 110. This reflected voltage has a similar frequency as the reference voltage that generates the reference wave, but its magnitude is attenuated and it is time delayed. The ratio of the reflected voltage to the reference voltage is the reflection coefficient. The reflection coefficient is then provided to a processing system 170 for processing, as detailed herein. The processing system 170 includes one or more memory devices 175 and one or more processors 180 to perform the analysis. The memory device 175 may store measurements of reflected voltage and instructions for processing the measurements that are executed by the processor 180.
Generally, the parameters of interest with regard to the formation 10 (
The permittivity of a given medium is the amount of energy stored or dissipated per unit volume as an electric field passes through the medium. This permittivity or dielectric constant is expressed as a complex number ε*:
In EQ. 1, ε′ is the real component of dielectric constant, ε″ is the imaginary component of dielectric constant, ω is the angular frequency in radians/second, σ is the conductivity in Siemens/meters (m), ε0 and is the free-space dielectric constant which is 8.85×10−12 Farads/m2. The dielectric constant is a function of frequency. In the MHz range, the dielectric constant is dominated by interfacial polarization, which occurs between any interface with a contrast in permittivity (e.g., between the cuttings 220 and host fluid 210 (
The reflection coefficient measured by the probe 110 is used to compute the dielectric constant (i.e., permittivity) of the MUT 150 using a full-wave electromagnetic model. This is a known computation that is not detailed herein. Based on the known computation, the permittivity computed from the measured reflection coefficient is referred to as effective permittivity herein. For a heterogeneous mixture such as the cuttings 220 suspended in the host fluid 210, a mixing model is used to determine physical parameters (e.g., volumetric concentration of each constituent of the MUT 150) from the measured effective permittivity. For a porous medium such as the cuttings 220 partially saturated by a host fluid 210 such as water or oil, a complex refractive index model (CRIM) is expressed as:
√{square root over (εCRIM)}=ØSw√{square root over (εw)}+Ø(1−Sw)√{square root over (εoil)}+(1−Ø)√{square root over (εm)} [EQ. 2]
In EQ. 2, εCRIM is the effective dielectric constant of the MUT 150, εw is the permittivity of water (i.e., all water, whether in the pores 230 or host fluid 210 (
The CRIM is a volumetric-based mixing model and describes molecular polarization, which occurs in the GHz range. Other models that capture information about the geometry of the constituents of the MUT 150 may be used to describe the interfacial polarization, which occurs in the MHz range, and to solve for effective cementation factor m, which describes the connectivity or tortuosity of the water 235 in pores 230 of the cuttings 220 (
As such, the exemplary MUT 150 of
Four systems of measurements, to allow for solving four unknowns in EQ. 3 below, can be obtained by changing the host fluid 210 and, for example, a temperature of the host fluid 210 and by adding a term corresponding to inter-cutting porosity, Øh (i.e., porosity of the host fluid 210) while considering the porosity Ø as the porosity of each cutting 220. Then, EQ. 2 becomes:
√{square root over (εCRIM)}=Øh√{square root over (εh)}+ØSwc√{square root over (εw)}+Ø(1−Swc)√{square root over (εoil)}+(1−Ø−Øh)√{square root over (εm)} [EQ. 3]
In EQ. 3, εh is the known permittivity of the host fluid 210. The four unknowns are porosity Ø, water saturation of the cuttings 220 Swc, and the permittivity of the matrix 225 of the cuttings 220 εm, as noted previously, and additionally the permittivity of the host fluid 210 εh. The host fluid 210 can be one of the fluids (e.g., water, oil) that is inside the pores 230 of the cuttings 220 but with a different temperature or may be another fluid with known permittivity such as acetone or methanol.
A cutoff frequency (fc) (e.g., 100 MHz) indicates the frequency at which the molecular polarization starts to dominate interfacial polarization in multi-frequency dielectric measurements. That is, molecular polarization occurs on the entire frequency scale while interfacial polarization occurs only at lower frequency ranges and decays with increasing frequency. At the cutoff frequency fc, the decay is such that the molecular polarization dominates. A more specific cutoff frequency fc value can be determined experimentally based on pore structure and shape, for example. The degree of interfacial polarization, which occurs at frequencies below fc, is determined based on the amount and shape of interfaces between two different constitutes of the pores 230 of the cuttings 220, while the degree of molecular polarization, which occurs at frequencies above fc, is governed by the volume of bulk constitutes (e.g., total volume of water 235 in pores 230 and in host fluid 210 or oil 240 in pores 230 and in host fluid 210).
When the film 310 around cuttings 220 is water, an oil host fluid 210 will result in a high number of interfaces between the water film 310 and oil host fluid 210 and between the water film 310 and oil 240 in the pores 230. Thus, the low-frequency dielectric measurement (i.e., effective permittivity) is relatively higher than the high-frequency measurement when the cuttings 220 with a water film 310 are put in a host fluid 210 of oil. When cuttings 220 with a water film 310 are put in a host fluid 210 of water, the effective permittivity determined using the probe 110 will be increased, relative to the effective permittivity using a host fluid 210 of oil, due the enhancement of molecular polarization, which occurs over the entire frequency range as previously noted. That is, effective permittivity is higher at lower frequencies with both host fluids 210 but is relatively higher for a water host fluid 210 than oil. This is illustrated in graph set 410 (
When the film 310 around the cuttings 220 is oil, there are fewer water interfaces when the cuttings 220 are immersed in a host fluid 210 of oil. Thus, a flatter dielectric dispersion response results (i.e., the effective permittivity is essentially a flat line). However, when the film 310 around the cuttings 220 is oil and the cuttings 220 are immersed in a host fluid 210 that is water, the amount of water interfaces (between the host fluid 210 and pores 230 with water 235) will increase the low frequency dielectric response (i.e., the effective permittivity will be higher at lower frequencies). This is illustrated in graph set 420 (
A more comprehensive approach to evaluating both the water saturation and wettability of cuttings 220 includes using a different mathematical representation for the cuttings 220, which considers the solid matrix 225 of the cuttings 220, the film 310, and water 235 or oil 240 in the pores 230 as a whole, and which separates the porosity Øc and water saturation of the cuttings 220 Swc from porosity Øh and water saturation of the host fluid 210 Swh. The permittivity of the cuttings 220 can be substituted for another mixing model as a modified matrix permittivity εm′ given by:
√{square root over (εm′)}=ØcSwc√{square root over (εwc)}+Øc(1−Swc)√{square root over (εoc)}+(1−Øc)√{square root over (εm)} [EQ. 4]
In EQ. 4, εwc and εoc are the permittivity of water 235 and oil 240 in the pores 230 of the cuttings 220.
By substituting the expression in EQ. 4 defining εm′ for εm in EQ. 2, the following results:
√{square root over (εCRIM)}=ØhSwh√{square root over (εwh)}+Øh(1−Swh)√{square root over (εoh)}+(1−Øh)[ØcSwc√{square root over (εwc)}+Øc(1−Swc)√{square root over (εoc)}+(1−Øc)√{square root over (εm)}] [EQ. 5]
In EQ. 5, Øh and Swh are the porosity and water saturation of the host fluid 210. With a system of five independent effective permittivity measurements for a given MUT 150, the five unknowns in EQ. 5 can be solved. As previously noted, each of the independent systems may be based on a difference in host fluid 210 or temperature of the host fluid 210, for example. The five unknowns are the porosity Øh and water saturation Swh of the host fluid 210, porosity of the cuttings 220 Øc, water saturation of the cuttings 220 Swc, and permittivity of the matrix 225 εm.
It is assumed that the permittivity of the host fluid 210 (e.g., ∃wh or εoh), and the permittivity of the water 235 εwc and oil 240 εoc in the pores 230 of the cuttings 220 are known. The water saturation of the host fluid 210 Swh can be used as a metric to indicate the wettability of the cuttings 220. Tat is, if Swh>0 and the host fluid 210 is oil, then the cuttings 220 must be water-wet (i.e., film 310 is water), and if Swh<1 and the host fluid 210 is water, then the cuttings 220 must be more oil-wet (i.e., film 310 of oil). The value of the water saturation of the host fluid 210 Swh in the previously discussed embodiments can be used as a quantitative measure of the wettability of the cuttings 220. If a mineralogy assessment or other source provides the permittivity of the matrix 225 εm, then the number of unknowns in EQ. 5 can be reduced from five to four.
Set forth below are some embodiments of the foregoing disclosure:
A system to evaluate a formation by analyzing drill cuttings, the system comprising: a multi-frequency dielectric coaxial probe configured to obtain a reflected voltage from a medium under test based on a reference voltage over a frequency range, the medium under test including the drill cuttings; and a processor configured to compute an effective permittivity of the drill cuttings over the frequency range based on a reflection coefficient, which is a ratio of the reflected voltage to the reference voltage over the frequency range, and to determine one or more parameters from the effective permittivity, wherein the one or more parameters are used to make decisions about subsequent drilling in the formation.
The system as in any prior embodiment, wherein the medium under test also includes a host fluid.
The system as in any prior embodiment, wherein the processor is further configured to determine the effective permittivity over the frequency range, using water as the host fluid, as a first data set, to determine the effective permittivity over the frequency range, using oil as the host fluid, as a second data set, to determine a difference between a value of the effective permittivity in the first data set and in the second data set at a frequency below a cutoff frequency fc as mLF, and to determine a difference between a value of the effective permittivity in the first data set and in the second data set at a frequency above the cutoff frequency fc as mHF.
The system as in any prior embodiment, wherein the processor is configured to determine that a film on the drill cuttings is water based on mLF/mHF being ≤1 and to determine that the film on the drill cuttings is oil based on mLF/mHF being >>1.
The system as in any prior embodiment, wherein the processor is configured to use a complex refractive index model (CRIM) mixing model with the effective permittivity to obtain a representation:
√{square root over (εCRIM)}=ØhSwh√{square root over (εwh)}+Øh(1−Swh)√{square root over (εoh)}+(1−Øh)[ØcSwc√{square root over (εwc)}+Øc(1−Swc)√{square root over (εoc)}+(1−Øc)√{square root over (εm)}],
where
εCRIM is permittivity of the mixing model, Øh is porosity of the host fluid, Swh is water saturation of the host fluid, εwh is permittivity of the host fluid based on the host fluid being water, εoh is the permittivity of the host fluid based on the host fluid being oil, Øc is porosity of the drill cuttings, Swc is water saturation of the drill cuttings, εwc is permittivity of water in pores of the drill cuttings, εoc, is permittivity of oil in the pores of the drill cuttings, and εm is the permittivity of a solid portion of the drill cuttings.
The system as in any prior embodiment, wherein the processor is configured to obtain the permittivity of the host fluid based on the host fluid being water εwh, the permittivity of the host fluid based on the host fluid being oil εoh, the permittivity of the water in the pores of the drill cuttings εwc, the permittivity of the oil in the pores of the drill cuttings εoc, as known values.
The system as in any prior embodiment, wherein the processor is configured to obtain the representation for five different conditions, each of the five different conditions including a different material as the host fluid or a different temperature of the host fluid as compared to any other of the five different conditions.
The system as in any prior embodiment, wherein, based on the representation obtained for the five different conditions, the processor is configured to solve for the one or more parameters including the porosity of the host fluid Øh, the water saturation of the host fluid Swh, the porosity of the drill cuttings Øc, the water saturation of the drill cuttings Swc, and the permittivity of a solid portion of the drill cuttings εm.
A method of evaluating a formation by analyzing drill cuttings, the method comprising: obtaining, using a multi-frequency dielectric coaxial probe, a reflected voltage from a medium under test based on a reference voltage over a frequency range, the medium under test including the drill cuttings; computing, using a processor, an effective permittivity of the drill cuttings over the frequency range based on a reflection coefficient, which is a ratio of the reflected voltage to the reference voltage over the frequency range; and determining, using the processor, one or more parameters from the effective permittivity, wherein the one or more parameters are used to make decisions about subsequent drilling in the formation.
The method as in any prior embodiment, further comprising forming the medium under test to include a host fluid.
The method as in any prior embodiment, further comprising determining the effective permittivity over the frequency range, using water as the host fluid, as a first data set, determining the effective permittivity over the frequency range, using oil as the host fluid, as a second data set, determining a difference between a value of the effective permittivity in the first data set and in the second data set at a frequency below a cutoff frequency fc as mLF, and determining a difference between a value of the effective permittivity in the first data set and in the second data set at a frequency above the cutoff frequency fc as mHF.
The method as in any prior embodiment, further comprising the processor determining that a film on the drill cuttings is water based on mLF/mHF being ≤1 and determining that the film on the drill cuttings is oil based on mLF/mHF being >>1.
The method as in any prior embodiment, further comprising the processor using a complex refractive index model (CRIM) mixing model with the effective permittivity to obtain a representation:
√{square root over (εCRIM)}=ØhSwh√{square root over (εoh)}+(1−Øh)[ØcSwc√{square root over (εwc)}+Øc(1−Swc)√{square root over (εoc)}+(1−Øc)√{square root over (εm)}],
where
εCRIM is permittivity of the mixing model, Øh is porosity of the host fluid, Swh is water saturation of the host fluid, εwh is permittivity of the host fluid based on the host fluid being water, εoh is the permittivity of the host fluid based on the host fluid being oil, Øc is porosity of the drill cuttings, Swc is water saturation of the drill cuttings, εwc is permittivity of water in pores of the drill cuttings, εoc is permittivity of oil in the pores of the drill cuttings, and εm is the permittivity of a solid portion of the drill cuttings.
The method as in any prior embodiment, further comprising the processor obtaining the permittivity of the host fluid based on the host fluid being water εwh, the permittivity of the host fluid based on the host fluid being oil εoh, the permittivity of the water in the pores of the drill cuttings εwc, the permittivity of the oil in the pores of the drill cuttings εoc, as known values.
The method as in any prior embodiment, further comprising the processor obtaining the representation for five different conditions, each of the five different conditions including a different material as the host fluid or a different temperature of the host fluid as compared to any other of the five different conditions.
The method as in any prior embodiment, further comprising the processor solving, based on the representation obtained for the five different conditions, for the one or more parameters including the porosity of the host fluid Øh, the water saturation of the host fluid Swh, the porosity of the drill cuttings Øc, the water saturation of the drill cuttings Swc, and the permittivity of a solid portion of the drill cuttings εm.
A resource recovery system, comprising: a drill configured to cut through a formation and generate drill cuttings; a multi-frequency dielectric coaxial probe configured to obtain a reflected voltage from a medium under test based on a reference voltage over a frequency range, the medium under test including the drill cuttings; and a processor configured to compute an effective permittivity of the drill cuttings over the frequency range based on a reflection coefficient, which is a ratio of the reflected voltage to the reference voltage over the frequency range, and to determine one or more parameters from the effective permittivity, wherein the one or more parameters are used to make decisions about subsequent drilling in the formation.
The system as in any prior embodiment, wherein the medium under test also includes a host fluid.
The system as in prior embodiment, wherein the processor is further configured to determine the effective permittivity over the frequency range, using water as the host fluid, as a first data set, to determine the effective permittivity over the frequency range, using oil as the host fluid, as a second data set, to determine a difference between a value of the effective permittivity in the first data set and in the second data set at a frequency below a cutoff frequency fc as mLF, and to determine a difference between a value of the effective permittivity in the first data set and in the second data set at a frequency above the cutoff frequency fc as mHF.
The system as in any prior embodiment, wherein the processor is configured to determine that a film on the drill cuttings is water based on mLF/mHF being ≤1 and to determine that the film on the drill cuttings is oil based on mLF/mHF being >>1.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. Further, it should be noted that the terms “first,” “second,” and the like herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. The modifier “about” used in connection with a quantity is inclusive of the stated value and has the meaning dictated by the context (e.g., it includes the degree of error associated with measurement of the particular quantity).
The teachings of the present disclosure may be used in a variety of well operations. These operations may involve using one or more treatment agents to treat a formation, the fluids resident in a formation, a wellbore, and/or equipment in the wellbore, such as production tubing. The treatment agents may be in the form of liquids, gases, solids, semi-solids, and mixtures thereof. Illustrative treatment agents include, but are not limited to, fracturing fluids, acids, steam, water, brine, anti-corrosion agents, cement, permeability modifiers, drilling muds, emulsifiers, demulsifiers, tracers, flow improvers etc. Illustrative well operations include, but are not limited to, hydraulic fracturing, stimulation, tracer injection, cleaning, acidizing, steam injection, water flooding, cementing, etc.
While the invention has been described with reference to an exemplary embodiment or embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the claims. Also, in the drawings and the description, there have been disclosed exemplary embodiments of the invention and, although specific terms may have been employed, they are unless otherwise stated used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention therefore not being so limited.
This application claims the benefit of U.S. Provisional Application No. 62/928,631 filed Oct. 31, 2019, the disclosure of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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62928631 | Oct 2019 | US |