Valve status indicator system and method

Abstract

A fluid control system includes a fluid control device configured to be connected to at least one of two casing elements in a well, for controlling a fluid flow between a bore of the fluid control device and a zone located outside the casing elements; and a tracer material located within an inner chamber of a body of the fluid control device, the tracer material being uniquely associated with the fluid control device. The fluid control device is configured to release, when activated, the tracer material out of the inner chamber.

Claims

1. A fluid control system comprising: a fluid control device comprising a body defining an inner chamber, wherein such device is configured to be connected to at least one of two casing elements in a well, for controlling a fluid flow between a bore of the fluid control device and a zone located outside the casing elements; and a tracer material enclosed within the inner chamber, the tracer material being uniquely associated with the fluid control device, wherein the fluid control device, when activated, is configured to allow fluid to flow from the zone located outside the casing elements into the bore of the fluid control device, and also to open the inner chamber such that the flow of fluid causes the tracer material to pass from the inner chamber to the bore.

2. The system of claim 1, wherein the fluid control device is a valve and the casing elements form (a) either a casing of the well, and the zone is a geological formation or (b) a tubing located inside the casing of the well, and the zone is an annulus formed between the tubing and the casing.

3. The system of claim 1, wherein the fluid control device comprises: the body that extends along a longitudinal axis X, the body having the bore; a port formed to extend radially through the body and to achieve the fluid flow between the zone and the bore; and an inner sleeve located within the body and configured to close the port to prevent the fluid flow between the zone and the bore.

4. The system of claim 3, further comprising: an actuating mechanism configured to actuate the inner sleeve to open or close the port relative to the bore.

5. The system of claim 4, wherein the actuating mechanism comprises a controller, a battery, a pressure switch, a dump valve, and a conduit fluidly connected to the dump valve.

6. The system of claim 5, wherein the inner sleeve and the body define first and second chambers, and the conduit is fluidly connected to the first chamber.

7. The system of claim 6, wherein the inner chamber is defined only by the inner sleeve and the body.

8. The system of claim 6, wherein the tracer material is placed in a containment vessel, and the containment vessel is located in the inner chamber, which is defined only by the inner sleeve and the body.

9. The system of claim 8, further comprising: a puncturing member located in the inner chamber and the puncturing member is configured to puncture the containment vessel when the inner sleeve is actuated.

10. A fluid control device comprising: a body extending along a longitudinal axis X, the body having a bore; a port formed to extend radially through the body; an inner sleeve located within the body and configured to close the port to prevent fluid communication between the port and the bore; and an actuation mechanism configured to actuate the inner sleeve to open or close the port relative to the bore and also to open an inner chamber defined by the body, such that fluid flowing through the port causes a tracer material enclosed within the inner chamber to pass into the bore of the body.

11. A fluid control system comprising: a fluid control device configured to be connected to at least one of two casing elements in a well for controlling a fluid flow between a bore of the fluid control device and a zone outside the casing elements; and a tracer material located within a moving sleeve of the fluid control device, wherein the tracer material is uniquely associated with the fluid control device, and the tracer material is released from the moving sleeve when the moving sleeve is activated.

12. The system of claim 11, wherein the fluid control device is a valve and the casing elements form either (a) a casing of the well, and the zone is a geological formation or (b) a tubing located inside the casing of the well, and the zone is an annulus formed between the tubing and the casing.

13. The system of claim 11, wherein the fluid control device comprises: a body that extends along a longitudinal axis X, the body having the bore; a port formed to extend radially through the body and to achieve the fluid flow between the zone and the bore; and the inner sleeve located within the body and configured to have a chamber that holds the tracer material, the inner sleeve being configured to close the port, when the chamber is not aligned with the port, to prevent the fluid flow between the zone and the bore, wherein the inner sleeve defines with the body first and second internal chambers, and the inner sleeve separates the first internal chamber from the second internal chamber.

14. The system of claim 13, further comprising: an actuating mechanism configured to actuate the inner sleeve to open or close the port relative to the bore.

15. The system of claim 14, wherein the actuating mechanism comprises: a conduit fluidly connected to the bore and the first chamber; and a burst disc that obstructs an end of the conduit and the burst disc is directly exposed to a fluid well in the bore.

16. The system of claim 15, wherein the tracer material is located in the first chamber.

17. The system of claim 15, wherein the tracer material is placed in a containment vessel, and the containment vessel is located in the first chamber.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) For a more complete understanding of the present invention, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:

(2) FIG. 1 illustrates a well in which a gun is used to open fluid channels between the wellbore and the formation around the casing;

(3) FIG. 2 illustrates a well having a casing equipped with plural valves that can be opened remotely to establish a fluid communication between the wellbore and the formation around the casing;

(4) FIG. 3 illustrates a tracer system having a tracer material that is released by a mechanical action of a sleeve in a sand screen device for identifying whether an associated valve is open;

(5) FIG. 4 illustrates a novel fluid control system equipped with a status monitoring system that indicates whether the fluid control system has been opened;

(6) FIG. 5 illustrates the fluid control system being opened and the status monitoring system releasing a tracer material to indicate the status of the fluid control system;

(7) FIG. 6 illustrates another novel fluid control system equipped with a status monitoring system that indicates whether the fluid control system has been opened;

(8) FIG. 7 illustrates the another fluid control system being opened and the status monitoring system releasing a tracer material to indicate the status of the fluid control system;

(9) FIG. 8A illustrates the fluid control system and the associated status monitoring system being implemented in the casing of a well, and FIG. 8B illustrates the fluid control system and the associated status monitoring system being implemented in a tubing that is lowered into the casing of a well;

(10) FIG. 9 illustrates yet another novel fluid control system equipped with a status monitoring system that indicates whether the fluid control system has been opened;

(11) FIG. 10 illustrates the yet another fluid control system being opened and the status monitoring system releasing a tracer material to indicate the status of the fluid control system;

(12) FIG. 11 illustrates still another novel fluid control system equipped with a status monitoring system that indicates whether the fluid control system has been opened;

(13) FIG. 12 illustrates the still another fluid control system being opened and the status monitoring system releasing a tracer material to indicate the status of the fluid control system; and

(14) FIG. 13 is a flowchart of a method for establishing fluid communication between a bore of a fluid control system and a zone outside the system and providing an indication that the fluid communication has been established.

DETAILED DESCRIPTION OF THE INVENTION

(15) The following description of the embodiments refers to the accompanying drawings. The same reference numbers in different drawings identify the same or similar elements. The following detailed description does not limit the invention. Instead, the scope of the invention is defined by the appended claims. The following embodiments are discussed, for simplicity, with regard to an oil well. However, the embodiments to be discussed next are not limited to an oil well, but they may be applied to other types of wells, for example, gas wells or water wells.

(16) Reference throughout the specification to “one embodiment” or “an embodiment” means that a particular feature, structure or characteristic described in connection with an embodiment is included in at least one embodiment of the subject matter disclosed. Thus, the appearance of the phrases “in one embodiment” or “in an embodiment” in various places throughout the specification is not necessarily referring to the same embodiment. Further, the particular features, structures or characteristics may be combined in any suitable manner in one or more embodiments.

(17) According to an embodiment, a novel valve status indicator system includes a containment vessel that is placed within a recess of the casing, and the containment vessel includes a tracer material. When the sleeve that closes the port formed in the recess of the casing is opened, the containment vessel is broken, releasing the tracer material. The arrival of the tracer material at the surface can be quickly identified and that tracer material is a positive indication that the corresponding port in the casing has been opened.

(18) More specifically, as illustrated in FIG. 4, a casing 400 is shown to have a top casing element 402A and a bottom casing element 402B physically separated from each other, but fluidly connected to each other by a fluid control device 410. The fluid control device 400 is configured to control a fluid flow from a bore 408 of the casing to a formation 409 outside the casing, or vice versa. In one application, the fluid flow is between the bore 408 and an annulus outside the casing, as discussed later with regard to FIG. 8B. For this reason, the formation 409 and the annulus are referred herein as a zone. The fluid control device acts as a valve and can be implemented as a valve. One skilled in the art would understand that the casing 400 can have any number of casing elements, but only two are shown in the figure for simplicity. Also, the casing 400 may have any number of fluid control devices 410. The casing elements may be mechanically connected to the fluid control device 410 by corresponding threads 404, or other equivalent connecting devices. In this embodiment, an inner diameter ID1 of the casing elements is identical to an inner diameter ID2 of the fluid control device 410, so that an inner sleeve 412 of the fluid control device 410 is flush with an inner wall 403 of the casing elements. In one embodiment, it is possible that the inner sleeve 412 enters inside the borehole of the casing. Note that casing elements 402A and 402B are directly connected to the fluid control device 410 in this embodiment.

(19) The inner sleeve 412 is configured to slide relative to a body 414 of the fluid control device 410, so that a port 416 formed in an external part of a wall of the body is closed by the inner sleeve and no fluid flow happens between the borehole 408 and the formation 409 around the casing 400. The wall of the body is understood herein to extend radially, from the bore to the formation around it. The body 414 may be manufactured to have two parts, an upper part 414A and a lower part 414B that are connected to each other, for example, by threads 415. In this way, the internal elements of the fluid control device 410 can be added in a more efficient way. The terms “upper” and “lower” are defined herein relative to a head and toe of the well, the upper part facing the head of the well and the lower part facing the toe of the well, irrespective of whether the well is horizontal, vertical, or having any other shape. One or more seals 418 may be formed at interfaces of the various elements of the fluid control device 410 to prevent a well fluid 406 to move along these interfaces. Under certain conditions, which are discussed later, the inner sleeve 412 can move along the longitudinal axis X and allow fluid communication through the port 416, between the borehole 408 of the casing and the formation 409.

(20) The lower part 414B may include an actuation mechanism 420 for actuating the inner sleeve 412, for opening the port 416. In one implementation, the actuation mechanism 420 includes a pressure disc or burst disc 422 and a conduit 424 that fluidly connects the pressure disc 422 to a first internal chamber 426 of the fluid control device 410. The first internal chamber 426 is defined in this embodiment only by the inner sleeve 412 and the lower part 414B of the body. The pressure disc 422 is configured to break at a given pressure of the well fluid 406. At that point, the well fluid 406 from the bore 408 enters through the conduit 424 into the first chamber 426 and exerts a force F on the sleeve 412, opposite to the direction of the longitudinal axis X. A second chamber 428 is defined by the lower part 414B of the body 414 and the sleeve 412 and this chamber contains air at the atmospheric pressure. The second chamber 428 is sealed from the bore 408 and from the formation 409.

(21) The fluid control device 410 further includes a status monitoring system 430 that is integrated into and associated with the fluid control device 410 and is configured to indicate to the operator of the well when the fluid control device 410 has opened. In one embodiment, the status monitoring system 430 is fully integrated within the body 414 of the fluid control device 410 in the sense that no part of the status monitoring system 430 extends into the bore 408 or outside of the fluid control device. This specific configuration of having the status monitoring system 430 fully located or integrated within the fluid control device 410 is understood as being “fully within a wall, or between two walls of the fluid control device, with no part sticking out into the bore or the formation.” The status monitoring system 430 may be implemented as a containment vessel 432 that holds a tracer material 434. The containment vessel 432 is placed in a third chamber 429 formed between the sleeve 412 and the lower part 414B of the body 414. The containment vessel 432 may be fixedly attached to one of the sleeve or the lower part of the body or just sitting within the third chamber 429. In one embodiment, the third chamber is defined exclusively by the sleeve 412 and the lower part 414B of the body 414. However, in one embodiment, the containment vessel 432 may be omitted so that the tracer material 434 is directly placed inside the third chamber 429. In one embodiment, the second chamber 426 is insulated from the third chamber 429 so that no fluid can be exchanged between the two chambers. However, in one application, the second chamber 426 may be in fluid communication with the third chamber 429.

(22) The tracer material 434 may include, but is not limited to, any small scale material capable of unique marking or identification, for example, DNA or DNA-like material comprising molecules of variable length, size, number of base pairs (amino acids) or sequence and/or type of amino acid base pairs; radioactive materials including nuclear or unique isotope, particle, or other materials; organic or inorganic molecules of varying molecular size, atomic composition or structure, for example, polymers of varying chain length detectable by analytical methods and instrumentation known in the art, e.g., mass spectrometry or other techniques, magnetic material, nanoparticles, nanofibers, nanorods, or other nanosized materials, etc. The type of material states may include gases, liquids, solids, and particles. Individual micro- or nano-particles may be physically marked with unique identifiers such as microdots or other tagging methods known in the art to include unique numbers, shapes, colors, color or other patterns, RFID, UPC, QR or other barcodes. Current technology has designed RFID chips that are 0.15×0.15 mm in size or smaller.

(23) The tracer reservoir or containment vessel 432 itself may be composed or a tracer material that dissolves in the wellbore fluid 406 or another material, such as an acid, contained and released by a separate compartment of the valve. In one embodiment, the tracer reservoir may be made of a material that is degraded by the oil flowing into the bore and thus, the tracer reservoir releases the tracer material.

(24) Combinations of different tracer materials are also contemplated herein, for example, a certain colored sphere of a particular material may identify a given group of valves, and each valve within the group is further marked with an individual RFID tag. Similar schemes may be applied wherein the DNA chain length is indicative of a subgroup of valves, while each DNA tracer within the group varies with respect to its amino acid base pair composition or sequence to identify individual valves within the group.

(25) In one application, a tracer reservoir or containment vessel 432 of up to approximately 100 mL is possible, depending on the valve size and overall design. In one application, the tracer material 434 could be a closed cell foam ball. In the well, it would be compressed by the hydrostatic pressure ˜>5,000 psi. and be a small size ˜<2 mm. As it reaches the surface at 14.7 psi, its size would have grown due to the air inside the foam expanding. It would now be much bigger and its bulk density would be reduced, and thus it would float. It could be skimmed off the top of a surface collector tank (not shown) placed at the head of the well. In another application, the containment vessel 432 is made of a material that dissolves when in contact with the well fluid 406. In still another embodiment, the containment vessel is made of a flexible material, like a balloon or a bladder, which when exposed to the high pressure inside the wellbore, breaks and releases the tracer material 434. In still another embodiment, the containment vessel 432 is accompanied by a second reservoir 436, which may be filled with an acid or solvent that would dissolve the containment vessel 432. When the inner sleeve 412 opens, it may be configured to puncture the second reservoir 436, which releases its content so that the first containment vessel 432 is starting to dissolve. In still another application, the containment reservoir 432 is pressurized by the second reservoir 436 that, upon sleeve opening, communicates to the containment reservoir which then causes the tracer to disperse into the wellbore.

(26) Because of the pressure differential between the high pressure of the well fluid in the first chamber 426 and the low pressure (atmospheric pressure) in the second chamber 428, the sleeve 412 is actuated and forced to move in an upward direction in FIG. 4 (in a different embodiment, the sleeve can move in a downward direction), which eventually opens up the port 416, as illustrated in FIG. 5. As the containment vessel 432 moves together with the inner sleeve 412, a puncturing member 450, which is attached to the lower part 414B of the body 414, opens up the containment vessel 432 and releases the tracer material 434 into the third chamber 429, which now directly communicates with the wellbore 408, as shown in FIG. 5. In fact, due to the movement of the inner sleeve 412, the port 416 is now in fluid communication with the wellbore 408. The tracer material 434 enters into the well fluid 406, and travels to the head of the well, where the tracer material is detected and associated with the corresponding valve, as each valve is provided with a unique tracer material.

(27) In another embodiment, as illustrated in FIG. 6, the actuation mechanism 420 is an electronic mechanism. More specifically, the actuation mechanism 420 includes a dump valve 622 that fluidly communicates the conduit 424 to the wellbore 408. The dump valve 622 is an electronically controlled valve, which is opened and closed when instructed by a controller 624. Controller 624 is electrically connected to a power source 626, that is configured to supply electrical power. In one application, the power source 626 is a battery that provides DC current. The controller 624 is also connected to a start switch 628 that is directly exposed to the fluid 406 in the wellbore 408. In one application, the controller 624, the power source 626, and the start switch 628 are also part of the actuation mechanism 420. All these elements of the actuation mechanism 420 are in this embodiment fully provided within the lower part 414B of the body 414, for example, in a wall of the body.

(28) In operation, the start switch 628 is configured to determine when a pressure inside the wellbore is larger than a given pressure. This pressure is selected by the operator of the well. When the operator needs to actuate the inner sleeve 412, the operator increases the pressure of the fluid inside the wellbore, until the start switch 628 is activated. When this happens, a signal is transmitted from the start switch 628 to the controller 624. The controller 624, aware now that the pressure inside the wellbore is over the given pressure, electronically instructs the dump valve 622 to open, so that the fluid 406 can enter through the conduit 424 into the first chamber 426, to initiate the movement of the inner sleeve 412. Because the pressure inside the second chamber 428 is smaller than the given pressure, the inner sleeves moves from the first chamber toward the second chamber to open the port 416. At the same time, the containment vessel 432, if present in the third chamber 429, moves together with the inner sleeve 412, and gets punctured by the puncturing member 450, which results in the release of the tracer material 434 as illustrated in FIG. 7. Note that the tracer material 434 can be provided directly in the third chamber, with no containment vessel 432. In one application, the controller 624, which can be a processor, can be programmed to apply a time delay after receiving the signal from the pressure switch 628 that the desired pressure in the wellbore has been reached.

(29) After the tracer material 434 is released into the wellbore 408, as shown in FIG. 8A, the tracer material 434 becomes mixed with the well fluid 406 (e.g., oil, gas, water) and may encounter a production pump 800, which is placed in the well and configured to move the oil from the well to the surface along a tubing 802. The production pump 800 is generally designed to pump sand with the well fluid 406, and the sand present in the well fluid 406 may have a grain size of typically about 2 mm in diameter. Hence, the tracer material 434 is preferably of a sufficient size to be pumped, or transferred through or around the blockages of the pumping equipment 800 through the tubing 802, in the well. The fluids are collected in the surface tank 804 and there, an appropriate device 806 identifies which tracer material is present. The device 806 may be a microscope, electronic microscope, a camera, a spectroscopy system, a magnetometer, etc., depending on the type of the tracer material.

(30) While FIG. 8A shows an embodiment in which the fluid control devices 410 are interposed between casing elements 402A and 402B (which form the casing 400, which is cemented in place with cement 820 inside the well), FIG. 8B illustrates another possible implementation of the fluid control devices 410. In this embodiment, the fluid control devices 410 are interposed between casing elements 402A and 402B that form a production tubing 802, and not the actual casing 400 that lines the well. In another words, in this embodiment, the fluid control devices 410 control a fluid flow from the bore 408 of the production tubing 802 to the annulus formed by the production tubing 802 and the casing 400, and not to the formation 409, which encloses the casing 400. Note that in both the embodiment of FIG. 8A and the embodiment of FIG. 8B, the elements of the casing 400 and the elements of the production casing 802 are called casing elements 402A and 402B. However, the casing elements 402A and 402B are in neither embodiment the elements of a sand screen tool.

(31) In still another embodiment, the tracer material 434 may be located directly within an inner sleeve 912 of a flow control device 910, as illustrated in FIG. 9. More specifically, the fluid control device 910 is configured to be connected directly between two casing elements 402A and 402B of the casing 400. The fluid control device 910 may have an inner sleeve 912 that is configured to slide inside a body 914. The body 914 may be made of an inner part 917 and an outer part 918, which covers and encloses the inner part 917 so that first and second chambers 920 and 922 are formed within the body 914. The sleeve 912 is placed between the inner part 917 and the outer part 918 to separate the first chamber 920 from the second chamber 922. Note that the inner and outer chambers are fully defined by the inner and outer parts of the body 914, and the inner sleeve 912.

(32) In this embodiment, the inner sleeve 912 has a chamber 913 formed within the sleeve 912 and this chamber is configured to hold the tracer material 434. Thus, in this embodiment, a status monitoring system 930 includes the chamber 913, which has one or more ports 915, and the tracer material 434. Because of the one or more ports 915, the chamber 913 is in fluid communication with the wellbore 408 only when the inner sleeve 912 moves in an open position, as illustrated in FIG. 10, to expose the one or more ports 915 to the wellbore 408. The inner sleeve 912 is configured to move to the left in FIG. 10, to reduce the size of the second chamber 922 to almost zero, so that the port in the chamber 913 is aligned to one or more ports 916 formed in the outer part 918 of the body 914 and also to one or more ports 916′ formed in the inner part 917 of the body 914. For this situation, the fluid 960 present in the formation 409, around the body 914, may enter the chamber 913 and combine with the tracer material 434 and move upward in the casing, as indicated by arrow A, eventually arriving at the head of the well.

(33) To move the inner sleeve 912 from the closed position shown in FIG. 9, to the open position shown in FIG. 10, an actuating mechanism 923 includes a conduit 924, which may be formed in the body 914, to fluidly communicate the wellbore 408 with the first chamber 920. The conduit is closed by a burst disc 932, which prevents the well fluid 406 entering the first chamber 920. The bust disc 932 is also part of the actuating mechanism 923. When the pressure inside the wellbore 408 is increased over a given value, the burst disc 932 is designed to break and allow the wellbore fluid 406 to enter the first chamber 920 through the conduit 924. Because the pressure in the second chamber 922 (atmospheric pressure) is lower than the pressure of the wellbore fluid, the inner sleeve 912 moves from the right to the left in the figure, which results in the substantial reduction of the volume of the second chamber 922, as shown in FIG. 10. The various o-rings 919 shown in the figures are used to prevent the high pressure of the well to enter the first and second chambers 920 and 922 before the operator intends to do so. Those skilled in the art would understand that the embodiment of FIG. 6 and that of FIG. 9 can be combined, e.g., to provide the electronic actuation mechanism of the inner piston 412 in FIG. 6 for the inner sleeve 912 of FIG. 9.

(34) In another embodiment illustrated in FIGS. 11 and 12, the tracer material 434 is placed into a containment vessel 1130. The containment vessel 1130 is designed to break when exposed to the hydrostatic pressure that is present in the wellbore. Thus, when the inner sleeve 912 is opened as show in FIG. 12, and the containment vessel 1130 is exposed at the high hydrostatic pressure of the wellbore, the containment vessel 1130 breaks and the tracer material 434 is released into the wellbore. All the other elements in this embodiment are similar to those in the previous embodiment, and for this reason, those common elements are not described again.

(35) A method for controlling a fluid flow in a well is now discussed with regard to FIG. 13. The method includes a step 1300 of providing plural fluid control devices 410 interposed between casing elements 402A, 402B in the well for controlling the fluid flow between a bore 408 of the fluid control devices 410 and a zone 409 located around the casing elements 402A, 402B, a step 1302 of lowering the plural fluid control devices 410 and the casing elements 402A, 402B into the well, a step 1304 of actuating a fluid control device 410 of the plural fluid control devices 410 to establish the fluid flow between the bore 408 and the zone 409, and a step 1306 of releasing a tracer material 434 from withing a wall of the fluid control device 410 into the fluid flow, where the tracer material 434 is uniquely associated with the fluid control device 410. In one application, the tracer material is released by a status monitoring system integrated within the wall of the fluid control device. The tracer material may be located in a chamber defined by an inner sleeve and a body of the fluid control device. In another application, the tracer material is located in its entirety within the inner sleeve.

(36) The disclosed embodiments provide a fluid control device and an associated and integrated status monitoring system that is capable to indicate whether the fluid control device has opened or not. It should be understood that this description is not intended to limit the invention. On the contrary, the embodiments are intended to cover alternatives, modifications and equivalents, which are included in the spirit and scope of the invention as defined by the appended claims. Further, in the detailed description of the embodiments, numerous specific details are set forth in order to provide a comprehensive understanding of the claimed invention. However, one skilled in the art would understand that various embodiments may be practiced without such specific details.

(37) Although the features and elements of the present embodiments are described in the embodiments in particular combinations, each feature or element can be used alone without the other features and elements of the embodiments or in various combinations with or without other features and elements disclosed herein.

(38) This written description uses examples of the subject matter disclosed to enable any person skilled in the art to practice the same, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the subject matter is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims.