Not applicable.
Not applicable.
1. Field of the Invention
The invention relates generally to the field of instrumentation used in wellbores drilled through Earth formations. More specifically, the invention relates to methods and apparatus for communicating signals to an instrument in a wellbore from the Earth's surface.
2. Background Art
Instruments used in wellbores drilled into the Earth's subsurface include a wide variety of sensing devices and mechanical operating devices. Examples of the former include pressure and temperature sensors, inclinometers and directional sensors, capacitance sensors, fluid density sensors, among others. In using such instruments, it is often necessary to send signals from the Earth's surface to the instrument to affect instrument operation or to provide information that may be used in the instrument.
For instruments deployed in a wellbore using armored electrical cable (“wireline” deployment) signals are transmitted along the cable to the instrument from the surface, typically from a surface recording system. For instruments deployed using a drilling rig or similar apparatus, where the instrument may be conveyed at the end of a drill pipe or tubing string, it is known in the art to send signals to the instrument by modulating the flow of drilling fluid through the drill pipe. Such modulation may be detected and decoded at the instrument by a flow sensor or a pressure sensor. It is also known in the art to send signals to the instrument by modulating the rate of rotation of the drill pipe. See, for example, U.S. Pat. No. 6,847,304 issued to McLoughlin and U.S. Pat. No. 5,113,379 issued to Scherbatskoy. It is also known in the art to communicated signals to an instrument in a wellbore by modulating fluid pressure from the Earth's surface. See, for example U.S. Pat. No. 4,856,595 issued to Upchurch and assigned to the assignee of the present invention.
In some cases, it is impractical to use any of the foregoing techniques for communicating signals to an instrument in a wellbore. For example, using “slickline” (a solid wire or wire rope conveyance having no insulated electrical conductors) there is no practical way to send electrical signals to the instrument from the Earth's surface. Further, it is not possible to rotate an instrument from the surface when conveyed by slickline or by coiled tubing. Finally, some wellbore instruments are materially complicated as to design by including a pressure or flow sensor.
One aspect of the invention is a method for communicating a signal to an instrument in a wellbore. A method according to this aspect of the invention includes axially accelerating the instrument in a preselected pattern of acceleration. The predetermined pattern corresponds to the signal to be communicated. The axial acceleration of the instrument is detected, and the signal is decoded from the detected axial acceleration.
A signal detection system for an instrument in a wellbore according to another aspect of the invention includes an accelerometer oriented along a longitudinal axis of the instrument. The system also includes means for comparing measurements made by the accelerometer to at least one predetermined pattern. The predetermined pattern corresponds to a signal communicated from the Earth's surface to the instrument.
Other aspects and advantages of the invention will be apparent from the following description and the appended claims.
The slickline unit 20 includes a winch 20A or similar device of any type known in the art. As will be further explained with reference to
The instrument 10 is shown deployed in the wellbore 16 at the lower end of the slickline 18. The instrument 10 may include sensors or other devices and a data acquisition processor, shown generally at 14, and an accelerometer and associated signal processing circuit devices, shown generally at 12. The accelerometer 12 is oriented in the instrument 10 to be sensitive primarily to acceleration along the longitudinal axis of the instrument, as shown generally by line 16A.
A tensile stress sensing element, or “load cell” 60 may be coupled between the upper sheave 24 and the derrick portion of the mast unit 22 to enable estimating the tensile stress (“weight”) on the slickline 18. In addition to providing the slickline unit 20 operator with indication of the condition of the instrument 10 as it is moved along the wellbore 16, tensile stress measurements may be used, as will be explained below with reference to
Another example of deployment device for a wellbore instrument is shown in
The deployment devices shown in
Having shown generally conveyance devices for deploying the instrument in the wellbore, an example of a signal detection and decoding apparatus according to one aspect of the invention will be explained with reference to
The signal detection and processing device 12 may include an accelerometer 42, such as a quartz flexure accelerometer, as previously explained, oriented so that its sensitive axis is generally along the longitudinal axis (16A in
The other signal acquisition and processing devices 14 may include a central processor 50 to process and/or record signals output from the DSP 46 as well as signals generated by one or more other sensors 52 or other devices in the instrument 10. Non-limiting examples of such other sensors 52 may include pressure and/or temperature sensors and calipers (wellbore internal diameter measuring devices). Any other device ordinarily operated by a slickline or coiled tubing conveyed instrument may also be disposed in or associated with the housing 11. Accordingly, the structure shown in
Electrical power to operate all the foregoing devices may be supplied by a battery 48 or other energy storage device. The source of electrical power to operate the various devices in the instrument, however, is not intended to limit the scope of this invention.
In one example, the DSP 46 may be configured to measure the filtered output of the accelerometer 42 for a selected period of time, for example, by buffering a selected number of accelerometer measurement samples, and calculating certain attributes of the measured acceleration. Such attributes may include maximum acceleration, minimum acceleration, means acceleration and variance (or standard deviation). The statistical information may be used in some examples to discriminate between true signals communicated from the Earth's surface and noise that is unlikely to represent a signal from the Earth's surface. For example, if the maximum and minimum acceleration values within a selected time interval are not outside selected threshold criteria, the measured acceleration may be attributed to ordinary operation of the conveyance device rather than signal elements.
The DSP 46 may be configured to compare the measured acceleration to one or more predetermined acceleration patterns. If a predetermined acceleration pattern is matched, the DSP 46 may communicate a signal to the processor 50 corresponding to the detected pattern indicating that a signal has been detected. The processor 50 may operate one or more devices in the instrument 10 according to instructions corresponding to the detected signal. For example, a sensor may be switched on or off. A recording device in the processor 50 may be switched to record a particular type of sensor output or change a sample rate of sensor signal recording. It is not a limit on the scope of this invention as to the type of operation initiated (or stopped) by the instrument 10 in response to a detected pattern. In addition, while the foregoing examples of signals from the Earth's surface have been explained in terms of commands or instructions, it is also within the scope of this invention that data may also be communicated to the instrument. Accordingly, the term “signal” as used herein with reference to information being transmitted from the Earth's surface to the instrument is intended to mean any information that can be encoded into a particular acceleration pattern and detected by suitable processing of acceleration signals in the DSP 46 and/or processor 50, or any similar signal detection and decoding device.
Acceleration as that term is used in the present description is intended to mean a force applied for a sufficient duration of time so as to change the velocity of the instrument 10. Such definition is intended to distinguish from acoustic signal transmission (which may be detected by an accelerometer), in which elastic or shear waves are moved through the instrument 10 but do not change its velocity.
To generate a selected acceleration pattern at the Earth's surface to represent a signal to be communicated to the instrument 10, the winch (20A in
In one example, the slickline unit or coiled tubing unit operator may cause the upward (or downward) motion to generate a selected increase (or decrease) in measured tensile stress (as measured by the load cell 60 in
In another example, automatic operation of the slickline or coiled tubing unit for signal generation may be provided by an apparatus such as the one shown in
The example system shown in
Alternatively, an as explained above, the winch or coiled tubing unit may be operated to momentarily move the instrument downward at full speed and then stop motion of the instrument. The winch or coiled tubing unit may also be operated to move the instrument downward and then reverse motion, either prior to stopping motion of subsequent reversing the direction of motion of the instrument.
By operations such as suggested above, a signal may be transmitted from the Earth's surface to the instrument in the wellbore without the need for a directly coupled signal communication channel (e.g., electrical power, optical signal or pressure modulation).
While the invention has been described with respect to a limited number of embodiments, these skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.
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Number | Date | Country |
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007498 | Oct 2006 | EA |
2288834 | Nov 1995 | GB |
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Entry |
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English Translation of Russian Decision to Grant for RU Application No. 2008108716/03 dated Mar. 5, 2012. |
Number | Date | Country | |
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20080218374 A1 | Sep 2008 | US |