Aspects of the present disclosure generally relate to fluid flow control. More specifically, aspects of the present disclosure relate to controlling the flow of fluid such as formation fluid and/or borehole fluid within a downhole tool.
Underground formation testing is performed during drilling and geotechnical investigation of underground formations. The testing of such underground formations is important as the results of such examinations may determine, for example, if a driller proceeds with drilling and/or extraction. Since drilling operations are expensive on a per day basis, excessive drilling impacts the overall economic viability of drilling projects.
Multi-valve well testing tools use multiple valves configured in a circuit. Toggling of one of the valves typically sets the other valves into motion as well. The well testing tools disclosed in U.S. Pat. No. 4,553,598 to Meek entitled “Full Bore Sampler Valve Apparatus”, and in U.S. Pat. No. 4,576,234 to Upchurch entitled “Full Bore Sampler Valve”, are mechanical in nature. One valve is disposed in the tool and is mechanically linked to another valve disposed in the tool. To open one valve, an operator at the well surface, upon opening the valve, must expect the other valve to open or close, since the two valves are mechanically linked together. Therefore, the operation of one valve is not independent of the operation of the other valve. When one valve in the tool is opened, other valves disposed in the tool must be opened or closed in a specific predetermined sequence.
More recent multi-valve well testing tools use other arrangements for toggling valves. For example, semi-passive valves are referenced in U.S. Pat. No. 7,577,070 to Brennan, III et al., the entirety of which is incorporated herein by reference. Brennan, III et al. disclose valves that are partially passive wherein the flow of fluid through the valve assists in toggling the valve. Hydraulics are only used in the referenced system to assist in returning the valve-state to its original position. The hydraulic valve systems of the prior art do not use hydraulics to initially set the valve or valves into motion. Moreover, the valve systems are not fully active. That is, all aspects of valve movement are not controlled by hydraulics. To provide a valve system that is fully active, a solenoid is required for each individual valve. Space is limited in a downhole tool, and each solenoid requires a relatively large amount of space.
Therefore, a need exists for providing a system and/or method that uses hydraulic pressure to toggle valve state while minimizing size and/or the number of solenoids required.
Certain examples are shown in the above-identified figures and described in detail below. In describing these examples, like or identical reference numbers are used to identify common or similar elements. The figures are not necessarily to scale and certain features and certain views of the figures may be shown exaggerated in scale or in schematic for clarity and/or conciseness.
The example valves described herein may be used on a downhole tool to sample fluids in a subterranean formation. More specifically, the example valves described herein may route dirty fluid between the displacement unit and inlet or outlet flowline portions of a testing tool.
The hydraulic fluid line 24 is connected to the discharge of the pump 16 and runs through hydraulic power module C and into adjacent modules for use as a hydraulic power source. In the embodiment shown in
The tool A further includes a pump-out module M, as shown in
A piston pump 92, energized by hydraulic fluid from a pump 91, may be aligned in various configurations, e.g., to draw from the flowline 54 and dispose of the unwanted sample though flowline 95. Alternatively, the pump 92 may be aligned to pump fluid from the borehole into the flowline 54. The pump-out module M can also be configured where the flowline 95 connects to the flowline 54 such that fluid may be drawn from the downstream portion of the flowline 54 and pumped upstream or vice versa. The pump-out module M has the necessary control devices to regulate the piston pump 92 and to align the fluid line 54 with the fluid line 95 to accomplish the pump-out procedure.
Referring to
In each of the
The fluid pumped through the tool A, flows directly past the o-ring seats 393a, 393b at various intervals during the two-stroke pumping cycles. Since this fluid may be formation fluid or borehole fluid laden with impurities varying from fine mud particles to abrasive debris of various sorts, such flow may produce accelerated wear of the o-ring seats. The wear can shorten the life of the o-ring and may lead to frequent failure of the seals. The following are examples of failures that may occur: 1) the o-ring is gradually worn during the pumping process until the o-ring will no longer seal; 2) debris gets trapped between the ball and one or both of the O-ring seats; 3) fine particles settle in the valve cavity and may gradually build up to the point where the particles prevent the ball from sealing against the seat; and 4) filters that are typically used with such valves are susceptible to plugging. The failure of any one of the four reversible mud check valve seals may reduce the output of the pump 392, and the loss of two seals may completely disable the pump 392.
The present disclosure illustrates a system and method for pumping formation fluid through a downhole tool using controlled mud check valves. The system and/or method may use one or more springs to assist in opening and closing the valves. The mud check valves may operate using only hydraulic pressure with the assistance of the springs. Furthermore, a reduced number of solenoids are required to open and close the valves.
In accordance with the present disclosure, a valve 590 is described to exhibit a non-limiting example of an embodiment of the application. Referring now to the drawings wherein like numerals refer to like parts,
The valve 590 combines two mud check valves 591, 592 in one port, thus saving tool space and reducing flowline dead volume. The valve 590 may be used as a check valve, e.g., as a replacement for the check valve CMV1 (also referenced as 390) of
A piston 518 may be slidably disposed in the passageway 512 between the first flowline 514 and the second flowline 516 of the body 510. The piston 518 may have a conduit portion 520 that defines a bore therethrough for conducting fluid through the passageway 512. The piston 518 may have the third flowline 515 extending therefrom. The piston 518 may also be referred to as a sliding cylinder, a check valve slide, or simply a piston slide.
A pair of annular seals 528, 530 may seal the first flowline 514 and the second flowline 516, respectively. The annular seals 528, 530 may be elastomeric o-rings, or various other materials, as dictated by the operating temperatures and pressures in the downhole environment. The annular seals 528, 530 may have a metal cone sealable against a donut elastomer. Furthermore, the annular seals 528, 530 may be face seals or shear seals. The annular seals 528, 530 are adapted for sealably engaging inner walls 524, 526 upon translatory movement of the piston 618 relative to the body 510.
The valve body 510 may also have a first hydraulic line 532 and a second hydraulic line 534 extending therefrom. The hydraulic lines 532, 534 may be in communication with the directional unit, a pump, and/or any other device for creating differential pressure. Accordingly, differential pressure across the hydraulic lines 532, 534 such as that provided by pressurized hydraulic fluid in a known manner, induces reciprocal translatory movement of the piston 518 within the passageway 512 of the body 510.
The valve 590 may further include a pair of coil springs 544, 546 slidably disposed at least partially around a portion of the piston 518. The coil springs 544, 546 yieldably limit translatory movement of the piston 512 within the passageway 512. Thus, increasing the pressure of the first hydraulic line 532 above that of the second hydraulic line 534 induces translatory movement of the piston 518 within the passageway 512 of the body 510 to one of two stop positions. In the stop position of
From the position of
Movement of the piston 618 may be dictated by the increasing and/or decreasing of pressure in the hydraulic lines 631, 633. For example, hydraulic pressure may be increased in the hydraulic lines 631, 633 to bias the piston towards an inner wall 626 to seal a second flowline 616. A vacuum cavity 650 may be defined between the piston 618 and a body 610 of the valve 690. The hydraulic lines 631, 632, 633, 634 may be fluidly connected to the cavity 650 such that an increase and/or a decrease of pressure via the hydraulic lines 631, 632, 633, 634 causes the piston 621 to move within the cavity 650.
Elastomer donuts 628, 630 may be provided on the inner walls 624, 626 to engage end portions 621, 622 of the piston 618. Alternatively, a cone-shaped opening in the end portions 621, 622 may engage a cone-shaped elastomer (not shown) extending from the inner walls 624, 626 of the valve 690.
Coil springs 644, 646 may be provided within the valve 690 to aid in biasing the piston 618. The coil springs 644, 646 may act to move the piston 618 to an original position after the piston 618 has been moved to one side or another due to hydraulic pressure.
The preceding description has been presented with reference to present embodiments. Persons skilled in the art and technology to which this disclosure pertains will appreciate that alterations and changes in the described structures and methods of operation can be practiced without meaningfully departing from the principle and scope of the disclosure. Accordingly, the foregoing description should not be read as pertaining only to the precise structures described and shown in the accompanying drawings, but rather should be read as consistent with and as support for the following claims, which are to have their fullest and fairest scope.
In one example embodiment, a valve is disclosed comprising: a body defining a volume; at least two mud check valves in the body, a fluid passageway connecting the at least two mud check valves, a first flowline configured to transport a first portion of a fluidl, a second flowline configured to transport a second portion of the fluid, wherein each of the first and second flowlines are configured to receive and discharge fluid from the passageway wherein the first flowline is configured to transfer the first portion of the fluid to a first portion of a downhole tool and wherein the second flowline is configured to transfer the second portion of the fluid to a second portion of the downhole tool.
In another example embodiment a valve for transporting a fluid, comprising: a body, a flowline, at least four hydraulic lines in the body, the hydraulic lines configured to transport the fluid, and a piston configured to move according to at least one of an increasing and decreasing pressure in two of the hydraulic lines, wherein the piston is configured to transport to a position to allow the fluid to exit the valve via the flowline.
Although exemplary systems and methods are described in language specific to structural features and/or methodological acts, the subject matter defined in the appended claims is not necessarily limited to the specific features or acts described. Rather, the specific features and acts are disclosed as exemplary forms of implementing the claimed systems, methods, and structures.
This application claims priority to U.S. Provisional Application 61/734,694 filed Dec. 7, 2012, the entirety of which is incorporated herein by reference.
Number | Date | Country | |
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61734694 | Dec 2012 | US |