1. Field of the Invention
This invention relates generally to apparatus and methods for evaluating formations traversed by a well borehole, and more particularly to a testing apparatus and method for determining formation characteristics and preventing contamination of tool inner mechanisms and sensors.
2. Description of the Related Art
In the oil and gas industry, formation testing tools have been used for monitoring formation pressures along a well borehole, obtaining formation fluid samples from the borehole and predicting performance of reservoirs around the borehole. Such formation testing tools typically contain an elongated body having an elastomeric packer that is sealingly urged against a zone of interest in the borehole to collect formation fluid samples in fluid receiving chambers placed in the tool.
Downhole multi-tester instruments have been developed with extensible sampling probes for engaging the borehole wall at the formation of interest for withdrawing fluid samples therefrom and measuring pressure. In downhole instruments of this nature it is typical to provide an internal piston, which is reciprocated hydraulically or electrically to increase the internal volume of a fluid receiving chamber within the instrument after engaging the borehole wall. This action reduces the pressure at the instrument formation interface causing fluid to flow from the formation into the fluid receiving chamber of the instrument.
During drilling of a borehole, a drilling fluid (“mud”) is used to facilitate the drilling process and to maintain a pressure in the borehole greater than the fluid pressure in the formations surrounding the borehole. This is particularly important when drilling into formations where the pressure is abnormally high: if the fluid pressure in the borehole drops below the formation pressure, there is a risk of blowout of the well. As a result of this pressure difference, the drilling fluid penetrates into or invades the formations for varying radial depths (referred to generally as invaded zones) depending upon the types of formation and drilling fluid used. The formation testing tools retrieve formation fluids from the desired formations or zones of interest, test the retrieved fluids to ensure that the retrieved fluid is substantially free of mud filtrates, and collect such fluids in one or more chambers associated with the tool. The collected fluids are brought to the surface and analyzed to determine properties of such fluids and to determine the condition of the zones or formations from where such fluids have been collected.
One feature that all such testers have in common is a fluid sampling probe. This may consist of a durable rubber pad that is mechanically pressed against the formation adjacent the borehole, the pad being pressed hard enough to form a hydraulic seal. Through the pad is extended one end of a metal tube that also makes contact with the formation. This tube (“probe”) is connected to a sample chamber that, in turn, is connected to a pump that operates to lower the pressure at the attached probe. When the pressure in the probe is lowered below the pressure of the formation fluids, the formation fluids are drawn through the probe into the well bore to flush the invaded fluids prior to sampling. In some prior art devices, a fluid identification sensor determines when the fluid from the probe consists substantially of formation fluids; then a system of valves, tubes, sample chambers, and pumps makes it possible to recover one or more fluid samples that can be retrieved and analyzed when the sampling device is recovered from the borehole.
A problem associated with typical formation test tools is contamination within the tool inner mechanisms and sensors and consequent failures associated with such contamination. Another problem is increased time required even when only formation pressure testing is desired. There is a need for a quick formation pressure test that does not require large formation fluid volume and that does not allow contaminants into the tool inner mechanisms and sensors.
The present invention provides a formation evaluation tool and method to address some of the drawbacks existing in conventional tools used in drilling and other downhole well operations.
One aspect of the present invention is an apparatus for in-situ formation pressure testing. The apparatus includes a sealing member sealing a portion of a borehole wall adjacent a formation and a port exposable to the sealed portion to allow fluid communication between the formation and the port. A first chamber accepts a first fluid communicated from the formation. A second chamber contains a second fluid, which is a hydraulic fluid. A flexible member is between the first chamber and the second chamber, the flexible member providing pressure communication between the first chamber and the second chamber, the flexible member also preventing fluid communication between the first chamber and the second chamber. A sensor is in communication with the second chamber, the sensor sensing a characteristic of the second fluid, the characteristic being representative of pressure in the first chamber.
In one embodiment, the flexible member is made using an elastomeric sheet comprising a polymer. The polymer may be selected from a synthetic polymer or from a natural polymer ore a combination.
Another embodiment includes a pump acting on the second fluid in the second chamber, the pump pumping to reduce pressure in the second chamber below formation pressure, the reduced pressure communicated to the first chamber to draw formation fluid into the first chamber.
In another embodiment, the flexible member flexes from a first position to a second position and back to the first position, the first position resulting in a portion of the flexible member being substantially juxtaposed to the port providing a substantially zero volume in the first chamber. The flexible member flexes from the second position to the first position expelling through the port fluid in the first chamber. A reversible pump may be used to operate on the second fluid.
In yet another embodiment, the sealing member and the port are on an extendable probe having a probe body and an inner bore for accepting fluid from the formation through the port.
In another embodiment, a pump operates on the second fluid and a controller is coupled to the pump and to the sensor, the controller controlling the pump in a closed-loop manner based in part on an output signal received from the sensor. The controller may be used to control the pump to reduce pressurization effects at the port as the seal is pressed against the borehole wall.
A method according to the present invention includes conveying a tool to a borehole location adjacent a formation of interest, sealing a portion of the borehole wall at the location, communicating a first fluid from the formation into a first chamber in the tool through a port exposed to the sealed portion of the borehole wall, using a flexible member to separate the first chamber from a second chamber containing a second fluid, communicating pressure from the first chamber to the second chamber using the flexible member, and sensing a characteristic of the second fluid using a sensor in communication with the second chamber, the sensed characteristic being representative of pressure in the first chamber.
A system according to the present invention includes a carrier carrying a tool into a well borehole. The tool includes a sealing member sealing a portion of a borehole wall adjacent a formation, a port exposable to the sealed portion to allow fluid communication between the formation and the port, a first chamber accepting a first fluid communicated from the formation, a second chamber containing a second fluid, a flexible member between the first chamber and the second chamber. The flexible member provides pressure communication between the first chamber and the second chamber and prevents fluid communication between the first chamber and the second chamber. A sensor is in communication with the second chamber for sensing a characteristic of the second fluid. A pump within the carrier operates on the fluid in the second chamber, and a controller including a processor processes an output of the sensor. The processed sensor output being representative of pressure in the first chamber.
For detailed understanding of the present invention, references should be made to the following detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings, in which like elements have been given like numerals and wherein:
Drilling operations include pumping drilling fluid or “mud” from a mud pit 122, and using a circulation system 124, circulating the mud through an inner bore of the drill string 104. The mud exits the drill string 104 at the drill bit 108 and returns to the surface through the annular space between the drill string 104 and inner wall of the borehole 110. The drilling fluid is designed to provide the hydrostatic pressure that is greater than the formation pressure to avoid blowouts. The pressurized drilling fluid also drives a drilling motor and provides lubrication to various elements of the drill string.
Modular subs 114 and 116 according to the present invention are positioned as desired along the drill string 104. As shown, the modular sub 116 may be included as part of the BHA 106. Each modular sub includes one or more modular components 118. The modular components 118 are preferably adapted to provide formation tests while drilling (“FTWD”) and/or functions relating to drilling parameters. It is desirable for drilling operations to include modular components 118 adapted to obtain parameters of interest relating to the formation, the formation fluid, the drilling fluid, the drilling operations or any desired combination. Characteristics measured to obtain to desired parameter of interest may include pressure, flow rate, resistivity, dielectric, temperature, optical properties tool azimuth, tool inclination, drill bit rotation, weight on bit, etc. These characteristics are processed by a processor (not shown) downhole to determine the desired parameter. Signals indicative of the parameter are then telemetered uphole to the surface via a modular transmitter 112 located in the BHA 106 or other preferred location on the drill string 104.
The sub 200 is constructed using known materials and techniques for adapting the sub 200 to a drill string such as the drill string 104 shown in
The probe module 204 includes an extendable probe 210 and a sealing pad 212 coupled to one end of the extendable probe 210. The probe module has a connector 228 that enables quick connection and detachment of the probe module 204 into the corresponding probe module receptacle 202a. The sub body 201 includes a connector 230 compatible with the probe connector 228. The connectors 228 and 230 may be any suitable connectors that allow quick insertion and detachment of the probe module 201. The connectors may be threaded connectors, plug-type connectors, or other suitable connector.
The probe module is operationally coupled to the pump module 206. Coupling the probe module 206 to the pump module 206 is accomplished when the modules 204 and 206 are installed in their respective receptacles 202a and 202b. The coupling mechanism depends upon the operating principles of the components. In one embodiment, the extendable probe module 204 is hydraulically operated and is coupled to the pump module 206 by fluid lines (not shown) pre-routed through the sub body 201. In another embodiment, the extendable probe module 204 is electrically operated and is coupled to the pump module 206 by electrical conductors (not shown) pre-routed through the sub body 201.
The sealing pad 212 is attached to a distal end of the extendable probe 210 using any suitable attaching device or adhesive. The sealing pad 212 is preferably a strong polymer material to provide for sealing a portion of the borehole wall when the when the extendable probe 210 is extended, while resisting wear-out caused by down-hole abrasive conditions. Any well-known sealing pad material may be used for constructing the sealing pad 212.
In the embodiment shown in
Continuing with the embodiment of
The test module 208 shown includes a motor 220 and a fluid sampling device 222. The sampling device 222 is preferably a reciprocating piston operated by the motor 220. Alternatively, the fluid sampling device 222 may be a motor driven pump, wherein the motor may be an electric or a mud-driven motor. Alternatively, the sampling device may be a selectable valve that opens upon command, and formation pressure is used to urge fluid into the device. The test module 208 is operatively associated with the probe module 204 for determining one or more parameters of interest of the formation fluid received through the probe. These parameters of interest may be any combination of fluid pressured, temperature, resistivity, and fluid composition. The test module includes an appropriate sensor or sensors 218 for measuring characteristics indicative of the parameters of interest. For example, the test module may include any number of known pressure sensors, resistivity sensors, thermal sensors, and/or nuclear magnetic resonance (NMR) sensors. Alternatively, the sensors may be disposed within the probe module with the sensor output being transferred to the test module via electrical conductors (not shown) pre-routed within the sub.
In operation, formation fluid entering the probe module 204 is independently drawn into a chamber 240 located in the test module using the fluid sampling device 222. A sensor 218 as described above is coupled to the chamber for sensing a characteristic of the formation fluid drawn into the chamber. A downhole processor (not shown) is adapted to accept an output of the sensor 218 and to determine the desired parameter of interest associated with the measured characteristic.
A particularly useful modular probe for use in a probe module according to the present invention is shown in
The hydraulic oil chamber 312 is filled with a suitable oil or other hydraulic fluid. A piston 314 is operatively associated with the pump module 206 described above and shown in
When sampling and/or testing are complete, the piston 314 is operated in the opposing axial direction to purge the sample chamber 308 of formation fluid. This action also helps in retracting the probe 302 by increasing pressure in the sample chamber 308.
The modular probe 300 shown couples to the sub 200 in the probe receptacle 202a. A suitable probe coupling 316 is shown that allows detachable coupling to the sub 200 and provides a good seal. Standard O-ring seals 318 provide pressure sealing when the probe 300 is connected to the sub 200. An appropriate fitting 320 is integral to the piston 314 to allow automatic connection when the probe 300 is inserted into the probe receptacle 202a.
During drilling, formation fluid must be circulated through the drilling system and thus must flow through the modular sub 200. To effect fluid flow through the sub 200, the sub body 201 has a plurality of fluid passageways 400a-d to allow drilling fluid to pass through the length of the sub 200 during drilling. The shape and number of individual passageways may be selected as desired to provide adequate flow through the sub 200. The shape and/or number of passageways may vary according to the number of component receptacles necessary for a particular modular sub.
A modular rib capable of receiving formation fluid is provided in another embodiment of the present invention.
The rib module 502 includes an elongated body 510 coupled to the sub body 504 at one end using a coupling 512 that preferably allows the rib module 502 to pivot at the coupling 512. The coupling 512 is preferably a pin-type coupling to allow release of the rib module when desired for repair or replacement. The rib module 502 is retractable into the recess 508 during drilling or otherwise when the sub 500 is moving within the borehole or is being transported.
The rib module 502 includes a pad member 514 disposed at a second end of the rib body 510. The pad 502 provides sealing engagement with the borehole wall when the rib is in an extended position as shown by dashed lines 522. The pad 514 includes a port 516 for receiving fluid. A pump 518 disposed in the rib module 502 is used to urge fluid into the port 516, and may also be used to expel fluid outwardly from the port 516. In a preferred embodiment the rib module 510 includes a power supply (not separately shown) such as a battery for operating the pump. In a preferred embodiment, the rib module 510 includes one or more sensors 520 and a processor (not separately shown) for testing the fluid entering the port. The processor is used to accept a sensor output and to process the output for determining a parameter of interest of the formation and/or the formation fluid. The sensed characteristic and parameter of interest are substantially identical to those described above with respect to the test module described above and shown in
A controller module 618 is coupled to the body 606 in a corresponding controller module receptacle 608a. The controller module includes a processor (not separately shown) for controlling downhole components housed in the body 606. A sample/test module 616 is coupled to the in the body 606 in a corresponding sample/test module receptacle 608d. The sample test module 616 is operatively associated with the controller module 610 and the probe module 610 to perform wireline testing and sampling according to conventional practices. The sample test module 616 is fluidically coupled to the probe module 610 such that fluid received through the probe is conveyed to the sample test module for testing and/or storage. The sample/test module 616 is substantially identical to the sample/test module described above and shown in
Once fluid is received at the probe module and conveyed to the sample/test module, sensors such as those described above and shown in
The hydraulic oil chamber 712 is filled with a suitable oil or other hydraulic fluid and is in fluid communication via conduit 714 with a pump module such as pump module 206 described above and shown in
The flexible member 710 may be any material suitable for repeated flexing and which withstand repeated trips into a well borehole. An example of such a material for manufacturing the flexible member is an elastomeric sheet comprising a polymer. The polymer may be a synthetic polymer, a natural polymer or a combination of the two. Any flexible material that will not allow fluid to pass from the sample chamber to the rest of the tool but will communicate pressure across the material will suffice for effective operation. Some pressure loss may be incurred across the flexible member making the sensed hydraulic fluid pressure Ph slightly different than the actual pressure Pf in the sample chamber. Such loss, however, is constant and can be determined and compensated for using a calibration process for the sensor and/or controller used to process the sensor output.
As shown, the tool 800 includes a flexible member 812 that separates a sample chamber 814 from a hydraulic fluid chamber 816 and from the rest of the tool inner mechanisms and circuitry. A conduit 818 provides fluid communication from the hydraulic chamber 816 and a pump 820. A sensor (P) 828 is coupled to sense a characteristic of the hydraulic chamber 816. The sensor 828 can be any sensor useful in determining a desired characteristic of the hydraulic fluid chamber 816. In one embodiment the sensor includes a pressure sensor. The sensor might also include a temperature sensor or a displacement sensor. A controller 822 includes a processor 824 and a memory device 826 or simply memory 826. The controller is coupled to the sensor 828 and to the pump 820 to control the pump. Closed-loop control of the pump is accomplished using information derived down hole. Such information includes in part an output of the sensor 828 conveyed to and processed by the processor 824. The processed output can be stored in the memory 826. The processed output can be used in part by the controller to control the pump 820. For some embodiments, the pump may be a reversible pump so that the flexible member can be flexed in a bi-directional manner.
In one embodiment the pump 820 acts on the fluid in the hydraulic chamber 816 to reduce pressure in the hydraulic chamber. Pumping the hydraulic chamber to a pressure below formation pressure will provide a reduced pressure communicated to the sample chamber 814 to draw formation fluid into the sample chamber. It should be noted that the pump may not always be necessary.
In one embodiment the flexible member flexes from a first position to a second position and back to the first position. In the first position a portion of the flexible member is substantially juxtaposed to the port providing a substantially zero volume in the sample chamber. The second position providing a small volume for receiving fluid from the formation. The flexible member may be forcibly flexed from the second position (
In one embodiment the pump is a reversible pump operating on the hydraulic fluid and the controller coupled to the pump and to the sensor controls the pump in a closed-loop manner based in part on an output signal received from the sensor to reduce pressurization effects at the port as the seal is pressed against the borehole wall.
The invention described above in various embodiments shown in
Each component module and associated receptacle are preferably fitted with corresponding plug coupling devices to enable quick mating and demating of the component module to the sub. As used herein, the term plug coupling means a coupling that is adapted to mate fluid and/or electrical connections within the sub and component module without the use of tools. The term does not exclude, however, the possibility of using a fastener to mechanically secure the component module within the sub.
The foregoing description is directed to particular embodiments of the present invention for the purpose of illustration and explanation. It will be apparent, however, to one skilled in the art that many modifications and changes to the embodiments set forth above are possible without departing from the scope of the invention, which is defined by the claims appended hereto.
This application is a continuation-in-part of U.S. patent application Ser. No. 10/100,670 for “Sub Apparatus with Exchangeable Modules and Associated Method” filed on Mar. 18, 2002 now U.S. Pat. No. 6,837,314, the entire contents of which are hereby incorporated herein by reference.
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Number | Date | Country | |
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Parent | 10100670 | Mar 2002 | US |
Child | 10871460 | US |