System and method for logging isotope fractionation effects during mud gas logging

US 10,371,691 B2
Filed: 07/10/2014
Issued: 08/06/2019
Est. Priority Date: 07/10/2013
Status: Active Grant

First Claim

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1. A mud gas analyzer, comprising:

a plurality of degassers adapted to extract gas from drilling mud passing through a flow path formed at least partially by a drill string within a well and an annulus positioned between an exterior surface of the drill string and a formation surrounding the well at a well-site, wherein the plurality includes a first degasser and a second degasser, the first degasser adapted to extract gas passing through the flow path upstream of the drill string, and the second degasser adapted to extract gas passing through the flow path downstream of the annulus and downstream with respect to the first degasser;

at least one gas analyzer, adapted to analyze the gas extracted by the plurality of degassers and generate a sequence of signals indicative of ratios of isotopes of gas species of gas extracted from the drilling mud; and

a computer system including a processor adapted to execute logic to cause the processor to, receive the sequence of signals, and to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well.

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Abstract

A mud gas analyzer and a well-site system using the mud gas analyzer are described. The mud gas analyzer includes at least one degasser adapted to extract gas from drilling mud passing through a flow path formed at least partially by a drill string within a well and an annulus positioned between an exterior surface of the drill string and a formation surrounding the well at a well-site, at least one gas analyzer adapted to interact with the gas extracted from the drilling mud. The gas analyzer determines an isotopic composition of a gas liberated from the drilling mud and generates a sequence of signals indicative of ratios of isotopes of a gas species liberated from the drilling mud. The computer system includes a processor adapted to execute logic to cause the processor to access information indicative of the well'"'"'s and drilling tools geometry and mud flow rates or access information from any other source providing particular locations of the well at which mixing of fractions of a gas species occurred including formation gas and recycled gas, receive the sequence of signals, and to calculate and log isotopic characteristics of the gas species entering the drilling mud at particular locations of the well within a geological formation.

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17 Claims

1. A mud gas analyzer, comprising:
- a plurality of degassers adapted to extract gas from drilling mud passing through a flow path formed at least partially by a drill string within a well and an annulus positioned between an exterior surface of the drill string and a formation surrounding the well at a well-site, wherein the plurality includes a first degasser and a second degasser, the first degasser adapted to extract gas passing through the flow path upstream of the drill string, and the second degasser adapted to extract gas passing through the flow path downstream of the annulus and downstream with respect to the first degasser;
  
  at least one gas analyzer, adapted to analyze the gas extracted by the plurality of degassers and generate a sequence of signals indicative of ratios of isotopes of gas species of gas extracted from the drilling mud; and
  
  a computer system including a processor adapted to execute logic to cause the processor to, receive the sequence of signals, and to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 12, 13, 14, 15)
- - 2. The mud gas analyzer of claim 1, wherein the computer system is coupled to the at least one gas analyzer and a flow meter.
  - 3. The mud gas analyzer according to claim 2, where the computer system accesses information indicative of a flow of the drilling mud, a geometry of the well and a geometry of the tool string or any other source providing particular locations of the well of mixing gases, and wherein the processor calculates and logs isotopic characteristics of gas entering the drilling mud at particular locations of the well using the information indicative of the flow of the drilling mud, the geometry of the well and the geometry of the tool string or any other source providing particular locations of the well of mixing gases.
  - 4. The mud gas analyzer of claim 1, wherein the at least one gas analyzer is at least one of a spectrophotometer and a gas chromatograph-isotope ratio mass spectrometer or any other technology able to provide measurement of relative concentrations of isotopes of at least one element within one or more gas species.
  - 5. The mud gas analyzer of claim 1, wherein the at least one gas analyzer is a plurality of gas analyzers including a first gas analyzer adapted to analyze gas extracted by the first degasser, and further comprising a second gas analyzer adapted to analyze gas extracted from the second degasser, and wherein signals to be generated by the first gas analyzer are indicative of a first level of retention of gas species of the gas in the drilling mud prior to reinjection of the drilling mud into the drill string, and signals to be generated by the second gas analyzer are indicative of a second level of retention of the gas species of the gas in the drilling mud upon exiting from the annulus.
  - 6. The mud gas analyzer of claim 5, wherein the computer system analyzes the sequence of signals to determine an isotopic composition of a gas species with logic indicative of δ
    - _formation=(δ
      
      _OUT−
      
      f_IN* δ
      
      _IN) / f_formationwhere δ
      
      _formationis the isotopic composition of the gas entering the drilling mud at particular locations of the well, δ
      
      _OUTis the isotopic composition of the gas in the drilling mud upon exiting from the annulus, δ
      
      _INis the isotopic composition of the gas in the drilling mud prior to reinjection of the drilling mud into the drill string, f_INis a fraction of the gas species transported out that is not coming from the formation, but is recycled gas; and
      
      f_formation=1−
      
      f_IN.
  - 7. The mud gas analyzer according to claim 1, wherein the gas analyzer is adapted to separately analyze gas extracted by the first degasser and the second degasser and to generate signals indicative of a first level of retention of gas species of the gas in the drilling mud prior to reinjection of the drilling mud into the drill string, and to generate signals indicative of a second level of retention of the gas species of the gas in the drilling mud upon exiting from the annulus.
  - 8. The mud gas analyzer according to claim 1, where the flow path is a first flow path having a first section and a second section, and further comprising a second flow path separate from the first section of the first flow path, the second flow path being coextensive with the second section of the first flow path, and wherein the processor is adapted to execute logic to cause the processor to access information indicative of the geometry of the well, the geometry of the tool string or any other source providing depth at which mixing gases are synchronized, and to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well using flow rates of the first and second paths.
  - 9. The mud gas analyzer of claim 8, where the computer system analyzes the sequence of signals to determine an isotopic composition of a gas species with logic indicative of δ
    - _formation=(δ
      
      _OUT−
      
      a*f_IN*δ
      
      _IN−
      
      b*f_{IN booster}*δ
      
      _{IN booster})/(1−
      
      a*f_IN−
      
      b*f_{IN booster}), wherein a mass balance calculation of δ
      
      _formationinvolves three fractions of the gas species;
      
      f_IN, f_formationand f_{IN booster};
      
      f_{IN booster}is a portion of the gas species not degassed at the surface out of a same mud reservoir as f_IN; and
      
      a and b are relative contributions first and second flow rates described in claim 8.
  - 12. A well-site system, comprising:
    - a drill string having a drilling tool positioned in a formation to bore a well through the formation thereby creating an annulus between an exterior surface of the drill string and the formation, the well having an entrance;
      
      a container containing drilling mud and being fluidly connected to the entrance of the well to receive drilling mud from the well;
      
      a mud pump having an inlet receiving drilling mud from the container, and an outlet injecting drilling mud into the drill string through a flow path formed at least partially by the drill string and the annulus;
      
      a mud gas analyzer according to claim 1.
  - 13. The well-site system of claim 12, wherein the mud gas analyzer includes a plurality of degassers, wherein the plurality includes a first degasser and a second degasser, the first degasser adapted to extract gas passing through the flow path upstream of the drill string, and the second degasser adapted to extract gas passing through the flow path downstream of the annulus and downstream with respect to the first degasser and wherein the at least one gas analyzer is a plurality of gas analyzers including a first gas analyzer adapted to analyze gas extracted by the first degasser, and further comprising a second gas analyzer adapted to analyze gas extracted from the second degasser, and wherein signals to be generated by the first gas analyzer are indicative of a first level of retention of gas species of the gas in the drilling mud prior to reinjection of the drilling mud into the drill string, and signals to be generated by the second gas analyzer are indicative of a second level of retention of the gas species of the gas in the drilling mud upon exiting from the annulus.
  - 14. The well-site system according to claim 12, wherein the computer system analyzes the sequence of signals to determine an isotopic composition of a gas species with logic indicative of δ
    - _formation=(δ
      
      _OUT−
      
      f_IN*δ
      
      _IN)/f_formationwhere δ
      
      _formationis the isotopic composition of the gas entering the drilling mud at particular locations of the well, δ
      
      _OUTis the isotopic composition of the gas in the drilling mud upon exiting from the annulus, δ
      
      _INis the isotopic composition of the gas in the drilling mud prior to reinjection of the drilling mud into the drill string, f_INis a fraction of the gas species transported out that is not coming from the formation, but is recycled gas; and
      
      f_formation=1−
      
      f_IN.
  - 15. The well-site system according to claim 12, wherein the computer system uses data indicative of a predetermined rate of degassing of gas from the drilling mud, time of degassing of particular mud volume, and one or more predetermined kinetic isotopic fractionation factor to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well.

10. A mud gas analyzer, comprising:
- at least one degasser adapted to extract gas from drilling mud passing through a flow path formed at least partially by a drill string within a well and an annulus positioned between an exterior surface of the drill string and a formation surrounding the well at a well-site;
  
  at least one gas analyzer, adapted to analyze the gas extracted by the plurality of degassers and generate a sequence of signals indicative of ratios of isotopes of gas species of gas extracted from the drilling mud; and
  
  a computer system including a processor adapted to execute logic to cause the processor to, receive the sequence of signals, and to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well,wherein the computer system uses data indicative of a predetermined rate of degassing of gas from the drilling mud, and one or more predetermined kinetic isotopic fractionation factor to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well.
- View Dependent Claims (11)
- - 11. The mud gas analyzer of claim 10, wherein the computer system analyzes the sequence of signals to determine an isotopic composition of a gas species with logic indicative of δ
    - _{IN (t)}=[δ
      
      _{OUT (t0)}+1000)*e^((k_surface* t)*(1−
      
      α
      
      ^−
      
      1_surface))] −
      
      1000 where k_surfaceis the degassing rate of the gas species from mud on the surface (e.g. mud pit), t is exposure time of a volume of mud to the surface degassing process starting at t0 when mud from which δ
      
      ¹³_{OUT (t0)}was measured, and α
      
      _surfaceis the isotopic fractionation factor of the mud degassing process.

16. One or more non-transitory computer readable medium storing processor executable code that when executed by one or more processors of a computer system cause the one or more processor to:
- receive information indicative of a geometry of a well, and a geometry of a tool string within the well, and a flow rate of drilling mud from at least one of a communication device and input device of the computer system or receive information from any other source providing particular locations of the well at which mixing of fractions of a gas species occurredreceive a sequence of signals indicative of ratios of isotopes of a gas species of gas extracted from a drilling mud from the at least one of the communication device and the input device of the computer system, andcalculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well,wherein the signals are indicative of a first level of retention of gas species in the drilling mud prior to reinjection of the drilling mud into the drill string, and are also indicative of a second level of retention of gases in the drilling mud upon exiting from an annulus; and
  
  wherein the processor executable code, when executed by one or more processors of the computer system, cause the one or more processor to analyze the sequence of signals to determine an isotopic composition of a gas species with logic indicative of δ
  
  _formation=(δ
  
  _OUT−
  
  f_IN*δ
  
  _IN)/f_formationwhere δ
  
  _formationis the isotopic composition of the gas entering the drilling mud at particular locations of the well, δ
  
  _OUTis the isotopic composition of the gas in the drilling mud upon exiting from the annulus, δ
  
  _INis the isotopic composition of the gas in the drilling mud prior to reinjection of the drilling mud into the drill string, f_INis a fraction of the gas species transported out that is not coming from the formation, but is recycled gas; and
  
  f_formation1−
  
  f_IN.

17. One or more non-transitory computer readable medium storing processor executable code that when executed by one or more processors of a computer system cause the one or more processor to:
- receive information indicative of a geometry of a well, and a geometry of a tool string within the well, and a flow rate of drilling mud from at least one of a communication device and input device of the computer system or receive information from any other source providing particular locations of the well at which mixing of fractions of a gas species occurredreceive a sequence of signals indicative of ratios of isotopes of a gas species of gas extracted from a drilling mud from the at least one of the communication device and the input device of the computer system, andcalculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well,wherein the processor executable code, when executed by one or more processors of the computer system, cause the one or more processor to use data indicative of a predetermined rate of degassing of gas from the drilling mud, and one or more predetermined kinetic isotopic fractionation factor to calculate and log isotopic characteristics of gas entering the drilling mud at particular locations of the well.

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Current Assignee
Geoservices Equipements (Schlumberger NV)
Original Assignee
Geoservices Equipements (Schlumberger NV)
Inventors
Strapoc, Dariusz, Niemann, Martin, Jacquet, Benjamin
Primary Examiner(s)
Smith, Maurice C

Application Number

US14/903,388
Publication Number

US 20160153955A1
Time in Patent Office

1,853 Days
Field of Search
US Class Current
CPC Class Codes

E21B 21/067   Separating gases from drill...

E21B 47/10   Locating fluid leaks, intru...

E21B 49/005   Testing the nature of boreh...

G01N 33/0047   for organic compounds

G01N 33/2823   raw oil, drilling fluid or ...

System and method for logging isotope fractionation effects during mud gas logging

First Claim

2 Assignments

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Abstract

28 Citations

17 Claims

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System and method for logging isotope fractionation effects during mud gas logging

First Claim

2 Assignments

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0 Petitions

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Abstract

28 Citations

17 Claims

Specification

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Solutions

Use Cases

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