A method and device are shown for detecting the characteristics of a cement annulus between a casing in a borehole and the surrounding earth formations in a slickline cement bond logging operation. An acoustic logging tool is utilized which produces a pure signal downhole. The received acoustically
A method and device are shown for detecting the characteristics of a cement annulus between a casing in a borehole and the surrounding earth formations in a slickline cement bond logging operation. An acoustic logging tool is utilized which produces a pure signal downhole. The received acoustically transmitted energy produces electrical signals indicative of both the amplitude of the received energy and variable density log data. Both the amplitude data and the variable density log data are captured in memory downhole by the use of a time amplitude matrix which stores a limited number of data points for producing a cement bond log at the well surface.
대표청구항▼
1. A method for detecting the characteristics of a cement annulus between a casing in a borehole and the surrounding earth formations in a slickline cement bond logging operation, the method comprising the steps of:lowering an acoustic logging tool within the borehole to a desired depth, the acousti
1. A method for detecting the characteristics of a cement annulus between a casing in a borehole and the surrounding earth formations in a slickline cement bond logging operation, the method comprising the steps of:lowering an acoustic logging tool within the borehole to a desired depth, the acoustic logging tool having at least an acoustic transmitting transducer, a primary acoustic receiving transducer and a longitudinally spaced secondary acoustic receiving transducer, the acoustic logging tool being suspended within the borehole by means of a slickline extending to the well surface; generating a pulse of acoustic energy from the transmitting transducer at a first point along said casing and transmitting said energy along said casing; receiving the acoustic energy transmitted along the casing with the primary receiving transducer at a second point along the borehole longitudinally spaced from the first point and producing an electrical signal representative thereof; receiving the acoustic energy transmitted along the casing with the secondary receiving transducer at a third point along the borehole longitudinally spaced from the first and second points and producing an electrical signal representative thereof; collecting amplitude and variable density data based upon the electrical signals and storing the data so collected in memory in a time amplitude matrix, the memory carried down hole by the logging tool; generating additional pulses of acoustic energy at timed intervals as the acoustic logging tool is moved within the borehole between known depths and storing the data collected in memory; retrieving the logging tool to the well surface and producing a cement bond log based upon the memorized data. 2. The method of claim 1, wherein the data which is collected downhole is stored in memory carried in the tool using a data compression scheme.3. The method of claim 1, wherein a trigger pulse establishes the beginning of the acoustic signal which is transmitted, thereby establishing time intervals for use in later surface analysis, the time intervals comprising a first arrival, a chosen amplitude and a following acoustic wave train.4. The method of claim 3, wherein data is collected and stored down hole that allows both amplitude of the received energy and variable density log data to be produced later at the well surface to provide a cement bond log.5. The method of claim 4, wherein the amplitude data is collected and stored from the primary acoustic receiving transducer and is representative of an amplitude characteristic of a preselected portion of each of said intercepted acoustic pulses occurring during a predetermined time interval at the second location following the first arrival of acoustic energy.6. The method of claim 5, wherein the variable density log data is collected by the secondary acoustic receiving transducer.7. The method of claim 6, wherein both the amplitude data and the variable density log data are captured in memory by the use of a time amplitude matrix which stores a limited number of data points for producing a cement bond log at the well surface.8. The method of claim 7, wherein the matrix data is recovered at the well surface from the memory module and provided to a surface interface computer for algorithmic reconstruction of the signal to provide variable density log data.9. The method of claim 8, wherein time and depth are continuously recorded during the down hole logging operation and are later correlated to the amplitude and variable density log data gathered from the memory module.10. The method of claim 1, wherein the data is stored in the time amplitude matrix in a sequence corresponding to an order of measurement to facilitate algorthimic reconstruction of the data to produce the cement bond log.11. A method for detecting the characteristics of a cement annulus between a casing in a borehole and the surrounding earth formations in a slickline cement bond logging operation, the method comprising the steps of:lowering an acoustic logging tool within the borehole to a desired depth, the acoustic logging tool having at least an acoustic transmitting transducer, a primary acoustic receiving transducer and a longitudinally spaced secondary acoustic receiving transducer, the acoustic logging tool being suspended within the borehole by means of a slickline extending to the well surface; generating a pulse of acoustic energy from the transmitting transducer at a first point along said casing and transmitting said energy along said casing; receiving the acoustic energy transmitted along the casing with the primary receiving transducer at a second point along the borehole longitudinally spaced from the first point and producing an electrical signal representative thereof; receiving the acoustic energy transmitted along the casing with the secondary receiving transducer at a third point along the borehole longitudinally space from the first and second points and producing an electrical signal representative thereof; collecting amplitude and variable density data based upon the electrical signal and storing the data so collected in memory in a time amplitude matrix, the memory carried hole by the logging tool; generating additional pulses of acoustic energy at timed intervals as the acoustic logging tool is moved within the borehole between known depths and storing the additional data collected in memory; retrieving the logging tool to the well surface and producing a cement bond log based upon the memorized data; and wherein each pulse of acoustic energy so generated down hole is a nearly pure sonic signal free from interactions with the logging tool itself. 12. The method of claim 11, wherein a trigger pulse establishes the beginning of the acoustic signal which is transmitted by the transmitting transducer, thereby establishing time intervals for use in later surface analysis, the time intervals comprising a first arrival, a chosen amplitude and a following acoustic wave train; andwherein data is collected and stored down hole using a data compression technique that allows both an amplitude of the received signals and variable density log data to be produced later at the well surface. 13. The method of claim 12, wherein both the amplitude data and the variable density log data are captured in memory by the use of a time amplitude matrix which stores a limited number of data points for reconstruction at the well surface.14. The method of claim 11, wherein the acoustic logging tool uses mechanical dampening to achieve a nearly pure sonic signal free from interactions with the logging tool itself.15. The method of claim 14, wherein the mechanical dampening is achieved by providing a synthetic dampening material within an interior space of the logging tool as well as within cut-out regions on the exterior of the tool.16. The method of claim 15, wherein the synthetic dampening material which is present within the interior space of the logging tool also serves to isolate any electrical wires running through the interior space so that the electrical wires are run dry within the acoustic tool body.17. The method of claim 11, wherein the data is stored in the time amplitude matrix in a sequence corresponding to an order of measurement to facilitate algorthimic reconstruction of the data to produce the cement bond log.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (9)
Roberts Edwin K. ; Elizondo Enrique, Acoustic isolator for acoustic well logging tool.
Eyl Kevin A. (Boulogne FRX) Kurkjian Andrew L. (Saint Cloud TX FRX) Lineman David J. (Houston TX) Pierce Edward A. (Houston TX) Steiner ; Jr. Joseph M. (Houston TX), Method and apparatus for determining compressional first arrival times from waveform threshold crossing provided by appa.
Schmidt Mathew G. (Houston TX) Masak Peter C. (Katy TX) Rhodes Paul B. (Houston TX), Method and apparatus for measuring the quality of a cement to a casing bond.
Catala Gerard (Meudon FRX) Stowe Ian (Montrouge FRX) Henry Daniel (Gyf-sur-Yvette FRX), Method for evaluating the quality of cement surrounding the casing of a borehole.
Tello Lucio N. (Fort Worth TX) Blankinship Thomas J. (Fort Worth TX) Alford Gerald T. (Burleson TX), Transmitter and receiver to radially scan the cementing conditions in cased wells.
Ray, Clifford H.; Fisseler, Glenn D.; Thompson, James N.; Haygood, Hal B., Deployment and retrieval method for shallow water ocean bottom seismometers.
Kuijk,Robert Van; Calvez,Jean Luc Le; Froelich,Benoit, Determination of the impedance of a material behind a casing combining two sets of ultrasonic measurements.
Thompson, James N.; Ray, Clifford H.; Fisseler, Glenn D.; Fyffe, Roger L.; Mitchell, Stephen W.; Boone, William E., Method and apparatus for deployment of ocean bottom seismometers.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.