RU99116613A - Borehole tool for collecting data from a subsurface stratum (OPTIONS) AND A METHOD FOR MEASURING PROPERTIES OF A FLUID PRESENT IN A SURFACE LAYER - Google Patents

Claims (23)

1. A downhole tool for collecting data from a subsurface formation, characterized in that the tubular mandrel configured to axially connect to a drill string installed in the wellbore passing the subsurface formation, a stabilizing element located around the tubular mandrel for relative rotation of the stabilizing element and tubular mandrel, elongated ribs connected to the stabilizing element, means connected to the stabilizing element, for engagement by frictional forces from the walls a borehole protecting the stabilizing element from rotation relative to the borehole wall, an actuating system supported at least partially by the stabilizing element, and a probe supported by one of the elongated ribs and configured to move the actuating system between the retracted position within one rib and extended position with engagement of the borehole wall, so that the probe collects data from the formation.  2. The downhole tool according to claim 1, characterized in that the elongated ribs are spaced in radial directions at distances from each other and are oriented along the axis along the stabilizing element.  3. The downhole tool according to claim 1, characterized in that the elongated ribs are spaced in radial directions at distances from each other and are oriented in a spiral along the stabilizing element.  4. The downhole tool according to claim 1, characterized in that the means for engaging by friction includes several elongated ribs.  5. The downhole tool according to claim 1, characterized in that the means for engagement by friction includes several stabilizing blades, each of which is located between two elongated ribs.  6. The downhole tool according to claim 1, characterized in that the means for engagement by the forces of friction includes a spring system for moving the means for engagement by the forces of friction in contact with the wall of the wellbore to prevent rotation of the means for engagement by the forces of friction relative to the wall of the wellbore.  7. The downhole tool according to claim 6, characterized in that the spring system includes several curved spring blades, each of which has a spring inherent rigidity.  8. The downhole tool according to claim 1, characterized in that the probe includes an elastic packer located in a substantially cylindrical hole in one of the ribs of the stabilizing element and having a central hole, a pipe having an open end located to communicate with the central fluid a hole in the packer, and a filter valve located in the central hole of the packer around the open end of the pipeline and able to move between the first position, closing the open end of the pipeline, and the second position ayuschem opportunity filtered formation fluid flow between the formation and the conduit.  9. The downhole tool according to claim 1, characterized in that the actuating system includes a hydraulic system, means for selectively increasing the pressure of the working fluid in the hydraulic system, an expanding vessel in fluid communication with the hydraulic system and capable of expanding at high pressure in the working fluid and contracting under reduced pressure in the working fluid.  10. The downhole tool according to claim 8, characterized in that the actuating system includes a hydraulic system, means for selectively increasing the pressure of the working fluid in the hydraulic system, an expanding bellows in fluid communication with the hydraulic system, and connected to the packer, and capable of expanding with increased pressure in the working fluid to move the packer in tight engagement with the wall of the wellbore.  11. The downhole tool according to claim 10, characterized in that the actuating system further comprises a sequence valve that is actuated upon detection of a predetermined pressure in the working fluid resulting from the maximum expansion of the bellows to move the filter valve to a second position, resulting in a fluid, located in the reservoir, can flow into the open end of the pipeline.  12. The downhole tool according to claim 8, characterized in that it further comprises a sensor in fluid communication with the pipeline for measuring the properties of the formation fluid.  13. The downhole tool according to claim 12, wherein the sensor is a pressure sensor configured to sense the pressure of the formation fluid.  14. The downhole tool according to claim 1, characterized in that it is a non-rotating stabilizer.  15. A downhole tool for collecting data from a subsurface formation, characterized in that it comprises a tubular mandrel configured to axially connect to a drill string installed in a wellbore passing a subsurface formation, a stabilizing element located around the tubular mandrel for relative rotation of the stabilizing element and the tubular mandrels, elongated ribs connected with a stabilizing element for engagement by friction forces with the wall of the wellbore, protecting the stabilizer a supporting element from rotation relative to the wall of the wellbore, an actuating system supported at least partially by a stabilizing element, and a probe supported by one of the elongated ribs and configured to move the actuating system between a retracted position within one rib and an extended position with an engagement of the wall wellbore so that the probe collects data from the formation.  16. A downhole tool for collecting data from a subsurface formation, characterized in that it comprises a tubular mandrel configured to axially connect to a drill string installed in a wellbore passing a subsurface formation, a stabilizing element located around the tubular mandrel for relative rotation of the stabilizing element and a tubular mandrel, elongated ribs connected to the stabilizing element spaced in radial directions at distances from each other, stabilize blades connected to a stabilizing element for engagement by friction forces with the wall of the wellbore, which prevents the stabilizing element from rotating relative to the wall of the wellbore, an actuating system supported at least partially by a stabilizing element, and a probe supported by one of the elongated ribs and made with the ability of the actuator to move between the retracted position within one rib and the extended position with engagement of the borehole wall, so that data from the reservoir.  17. The downhole tool according to claim 16, characterized in that each stabilizing blade is located between two elongated ribs.  18. The downhole tool according to claim 16, characterized in that each stabilizing blade includes a curved spring having an inherent spring stiffness to advance the stabilizing blade into engagement by friction forces with the wall of the wellbore.  19. The method of measuring the properties of the fluid present in the near-surface formation, characterized in that the drill string is installed in the borehole, the near-surface formation is installed, a non-rotating tool element is installed located in the drill string in engagement with the borehole wall, so that the non-rotating element cannot move relative to the wall of the wellbore, and move the probe, supported by a non-rotating element, in tight engagement with the wall of the wellbore, to establish a message f fluid between the formation and the non-rotating element.  20. The method according to p. 19, characterized in that it further injected fluid from the reservoir into the sensor supported by the downhole tool to perceive the properties of the reservoir.  21. The method according to p. 20, characterized in that as a sensor using a pressure sensor configured to sense the pressure of the reservoir fluid.  22. The method according to p. 21, characterized in that the quality of the probe is used, which is configured to move the actuator between the retracted position inside the non-rotating element and the extended position with the engagement of the borehole wall, so that the probe collects data from the reservoir.  23. The method according to p. 22, characterized in that as a probe use a probe comprising an elastic packer located in a substantially cylindrical hole in the non-rotating element, and having a Central hole, a pipe having an open end located for fluid communication with a central hole in the packer, and a filter valve located in the central hole of the packer around the open end of the pipeline, and able to move between the first position, closing the open end of the pipeline, and the second position, ensuring which allows filtered formation fluid to flow between the formation and the pipeline.