Wellbore imaging using magnetic permeability measurements

US 6,020,741 A
Filed: 06/16/1998
Issued: 02/01/2000
Est. Priority Date: 06/16/1998
Status: Expired due to Fees

First Claim

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1. A wellbore wall imaging tool for use in a well bore, comprising:

a transmitter configured to generate a magnetic field; and

a plurality of receiver coils arranged to generate an image of said borehole, wherein each of the receiver coils includes a first portion wound in a first direction and a second portion wound in an opposite direction, wherein the plurality of receiver coils is configured to generate a plurality of respective voltages indicative of a plurality of respective relative magnetic permeability values in regions proximate to the receiver coils, wherein the plurality of receiver coils is coupled to a signal processor, and wherein the signal processor is configured to determine a pixel intensity value signal for each of the receiver coils.

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Abstract

A wellbore imaging tool is provided which is sensitive to magnetic permeability changes in the wellbore wall. In one embodiment, the measuring array comprises a transmitter coil, an array of receiver coils, and a signal processor. The transmitter coil generates an oscillating magnetic field in the wellbore wall, and each of the receiver coils generates a voltage indicative of a direct inductive coupling strength between the receiver coil and the transmitter coil. Variations in the magnetic permeability of the wellbore wall will cause the direct inductive coupling strength between the transmitter and receiver coils to vary accordingly. The signal processor is coupled to each of the receiver coils to determine the direct inductive coupling strength and configured to convert it into a pixel value for each of the receiver coils. The pixel value may represent the magnetic permeability of a wall region proximate to the receiver coil, or it may represent the direct inductive coupling strength. An image generator may take the pixel values and organize them into an image for display. Each of the receiver coils may comprise a first coil wound in a first direction and a second coil wound in a second direction and coupled in series with the first coil to balance the receiver coil with respect to the transmitter coil. Advantageously, direct inductive coupling measurements are not hindered by drilling mud conductivity or by the acoustic distortion of water droplets in the drilling mud. A high resolution image of wellbore walls may thus be obtained by this measurement technique when other techniques fail.

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20 Claims

1. A wellbore wall imaging tool for use in a well bore, comprising:
- a transmitter configured to generate a magnetic field; and
  
  a plurality of receiver coils arranged to generate an image of said borehole, wherein each of the receiver coils includes a first portion wound in a first direction and a second portion wound in an opposite direction, wherein the plurality of receiver coils is configured to generate a plurality of respective voltages indicative of a plurality of respective relative magnetic permeability values in regions proximate to the receiver coils, wherein the plurality of receiver coils is coupled to a signal processor, and wherein the signal processor is configured to determine a pixel intensity value signal for each of the receiver coils.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
- - 2. The wellbore wall imaging tool of claim 1, wherein the pixel intensity value signal for a receiver coil represents the relative magnetic permeability of a region of said borehole proximate to the receiver coil.
  - 3. The wellbore wall imaging tool of claim 1, wherein the wellbore wall imaging tool wherein said transmitter coil is configured to generate an oscillating magnetic field that couples equally to the first and second portions of each of the receiver coils when no magnetic material wall is present, and wherein the signal processor is configured to determine an imbalance voltage in each of the receiver coils caused by direct coupling between the transmitter coil and the receiver coils.
  - 4. The wellbore wall imaging tool of claim 3, wherein the pixel intensity value signal for a receiver coil represents the imbalance voltage in each of the receiver coils caused by direct coupling between the transmitter coil and the receiver coils.
  - 5. The wellbore wall imaging tool of claim 3, wherein the signal processor is configured to filter out imbalance voltages in each of the receiver coils caused by indirect coupling between the transmitter coil and receiver coils.
  - 6. The wellbore wall imaging tool of claim 3, wherein the first and second portions are adjacent and coaxial.
  - 7. The wellbore wall imaging tool of claim 3, wherein the first and second portions are adjacent and parallel.
  - 8. The wellbore wall imaging tool of claim 3, wherein the receiver coils are spaced circumferentially about the well imaging tool.
  - 9. The wellbore wall imaging tool of claim 3, wherein each of the pixel intensity value signals comprises a sequence of pixel value samples, and wherein the signal processor interleaves the sequences to form a single output sequence.
  - 10. The wellbore wall imaging tool of claim 9, wherein the signal processor provides the output sequence to an image generator, and wherein the image generator converts the output sequence into image data.

11. A wellbore wall imaging tool which comprises:
- at least one transmitter coil configured to generate an oscillating magnetic field;
  
  an array of receiver coils, wherein each of the receiver coils is configured to generate a voltage indicative of a direct inductive coupling strength between the given receiver coil and the transmitter coil;
  
  a signal processor coupled to each of the receiver coils to determine the direct inductive coupling strength and configured to convert the direct inductive coupling strength for each of the receiver coils into a pixel value for each of the receiver coils, wherein said pixel values are suitable for combination into a wellbore image.
- View Dependent Claims (12, 13, 14, 15, 16, 17)
- - 12. The wellbore wall imaging tool of claim 11, wherein each receiver coil comprises a first portion wound in a first direction and a second portion wound in a second direction, wherein the first and second portions are coupled in series and are balanced with respect to the transmitter coil.
  - 13. The wellbore wall imaging tool of claim 11, wherein the first and second portions are coaxial.
  - 14. The wellbore wall imaging tool of claim 11, wherein the pixel value signal for each receiver coil represents the relative magnetic permeability of a wall region proximate to the receiver coil.
  - 15. The wellbore wall imaging tool of claim 11, wherein the pixel value signal for each receiver coil represents the voltage in each of the receiver coils caused by direct coupling between the transmitter coil and the receiver coils.
  - 16. The wellbore wall imaging tool of claim 11, wherein the signal processor is configured to filter out voltages in each of the receiver coils caused by indirect coupling between the transmitter coil and receiver coils.
  - 17. The wellbore wall imaging tool of claim 11, wherein the signal processor provides the pixel values to an image generator, and wherein the image generator converts the pixel values into said wellbore image.

18. A method for imaging a wellbore wall, wherein the method comprises:
- generating an oscillating magnetic field in the wellbore wall, wherein said generating includes driving a transmitter coil with an oscillating signal;
  
  detecting a directly induced voltage in each of a plurality of receiver coils, each receiver coil corresponding to a spot of said wellbore wall and the spot of each receiver coil at least partially overlapping with a spot corresponding to another receiver coil;
  
  converting each detected directly induced voltage into a pixel value;
  
  determining a location of each pixel value relative to a desired viewing location;
  
  displaying all pixels within a predetermined distance of the viewing location.
- View Dependent Claims (19, 20)
- - 19. The method of claim 18, wherein detecting comprises:
    - correlating each receiver coil voltage with the oscillating signal to produce a correlation signal for each receiver coil;
      
      periodically sampling the correlation signals to determine induced voltages 90 degrees out of phase with the oscillating signal.
  - 20. The method of claim 18, wherein converting comprises calculating a magnetic coupling strength between the transmitter coil and the receiver coil.

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Current Assignee
Halliburton Energy Services Incorporated (Halliburton Company)
Original Assignee
Halliburton Energy Services Incorporated (Halliburton Company)
Inventors
Chemali, Roland E., Heysse, Dale R.
Primary Examiner(s)
Snow, Walter E.

Application Number

US09/098,253
Time in Patent Office

595 Days
Field of Search

324/338, 324/339, 324/340, 324/341, 324/343, 324/355, 324/357, 324/367, 702/6, 702/7
US Class Current

324/339
CPC Class Codes

G01V 3/28 using induction coils

Y02A 90/30 Assessment of water resources

Wellbore imaging using magnetic permeability measurements

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20 Claims

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Wellbore imaging using magnetic permeability measurements

First Claim

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