In some hydrocarbon recovery systems, a reciprocating pump may be used to deliver fluid into a wellbore. In some cases, the reciprocating pump may comprise a plurality of pistons driven by a shared crankshaft and each of the pistons may repeatedly displace a volume of fluid to a fluid output of the pump. While an average total output rate may be provided by the pump, the volumetric output associated with each of the pistons may generate a pressure pulsation within the fluid output and the fluid systems connected downstream relative to the fluid output. In some cases, the collection of pressure pulsations associated with the pistons may at least one of (1) coincide with at natural frequency and/or harmonic of a natural frequency of a component downstream of the fluid output, (2) reduce an effectiveness of a wellbore servicing method that is sensitive to pressure fluctuations, and (3) interfere with communications effectuated through the pumped fluid, such as, mud pulse telemetry. In some cases, pulsation dampers may be used to accommodate and/or dampen pressure pulsations by reactively expanding and/or compressing a compressible fluid in response to pressure pulsations. However, in some cases, the pulsation dampers are tuned and/or designed for a predetermined pressure and the pressure may not be easily adjustable in the field environment.
In some embodiments of the disclosure, a pumping system is disclosed as comprising an output conduit associated with an output of a positive displacement pump, a first sensor configured to measure a fluid flow characteristic (FFC) within the output conduit a second sensor configured to measure a phase of the positive displacement pump; a feedforward active controller configured to receive information related to the FFC, receive information related to the phase of the positive displacement pump, and determine an FFC variability value, and a first fluid flow normalizer (FFN) configured to at least one of add fluid to the output of the positive displacement pump and remove fluid from the output of the positive displacement pump in response to a signal from the feedforward active controller.
In other embodiments of the disclosure, a hydrocarbon recovery system is disclosed as comprising a drillstring and a pumping system. The pumping system is disclosed as comprising an output conduit in fluid communication with the drillstring and associated with an output of a positive displacement pump, a first sensor configured to measure a fluid flow characteristic (FFC) within the output conduit, a second sensor configured to measure a phase of the positive displacement pump, a feedforward active controller configured to receive information related to the FFC, receive information related to the phase of the positive displacement pump, and determine an FFC variability value, and a first fluid flow normalizer (FFN) configured to at least one of add fluid to the output of the positive displacement pump and remove fluid from the output of the positive displacement pump in response to a signal from the feedforward active controller.
In yet other embodiments of the disclosure, a method of normalizing a fluid flow characteristic (FFC) of a fluid of an output of a positive displacement pump is disclosed as comprising determining an FFC variation of a fluid of an output of a first positive displacement pump, generating an FFC variation cancellation fluid output from a first fluid flow normalizer (FFN), and combining the output of the first positive displacement pump with the FFC variation cancellation fluid output of the FFN.
In some cases, it may be desirable to provide a fluid flow normalizer (FFN) for reducing an overall repetitive fluid flow variability of a pumping system. In some embodiments, the above-described FFN may be controlled to selectively reduce periodic increases in a fluid flow characteristic (FFC) of an output of a pumping system comprising a reciprocating and/or positive displacement pump by at least one of reducing a volumetric space of the fluid carrying components of the pumping system and increasing an amount of fluid injected into the fluid carrying components of the pumping system at appropriate intervals. In some embodiments, the above-described FFN may be controlled to selectively reduce periodic decreases in an output FFC of a pumping system comprising a reciprocating and/or positive displacement pump by at least one of increasing a volumetric space of the fluid carrying components of the pumping system and decreasing an amount of fluid injected into the fluid carrying components of the pumping system at appropriate intervals. In some embodiments, an FFN may be configured to selectively reduce a magnitude of both periodic increases and decreases in an output FFC of a pumping system comprising a reciprocating and/or positive displacement pump. In some embodiments, an FFN comprises a selectively controlled positive displacement fluid device, such as, but not limited to, a piston configured to inject fluid into the fluid carrying components of a pumping system and/or remove fluid from the fluid carrying components of a pumping system. In other embodiments, an FFN comprises a selectively controlled actuator configured to assist a flexible separation diaphragm of a fluid system damper. In some embodiments, the positive displacement fluid device (e.g., the piston) and/or the flexible separation diaphragm may be configured for exposure on opposing sides to be exposed to the static and/or average fluid pressure within the fluid carrying components of a pumping system, thereby enabling the FFN to achieve normalization while primarily performing work associated with the energy of the repetitive variations in FFCs, such as, but not limited to, fluid mass flow rates (FMFRs) and/or fluid pressures.
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In some cases, the hydrocarbon recovery system 100 further comprises drilling fluid 124 which may comprise a water-based mud, an oil-based mud, a gaseous drilling fluid, water, gas and/or any other suitable fluid for maintaining bore pressure and/or removing cuttings from the area surrounding the drill bit 106. Some drilling fluid 124 may be stored in a pit 126 and a pumping system 200 may deliver the drilling fluid 124 to the interior of the drillstring 102 via a port in the rotary swivel 122, causing the drilling fluid 124 to flow downwardly through the drillstring 102 as indicated by directional arrow 128. The drilling fluid 124 may exit the drillstring 102 via ports in the drill bit 106 and circulate upwardly through the annulus region between the outside of the drillstring 102 and the wall of the borehole 104 as indicated by directional arrows 130. The drilling fluid 124 may lubricate the drill bit 106, carry cuttings from the formation up to the surface as it is returned to the pit 126 for recirculation, and create a mudcake layer (e.g., filter cake) on the walls of the borehole 104. In alternative embodiments, the hydrocarbon recovery system 100 may be configured to pressurize the borehole 104 for hydraulic fracturing the formations surrounding the borehole 104. In some methods of hydraulic fracturing, an effectiveness of the hydraulic fracturing technique may depend largely on a consistency in FFCs, such as, but not limited to, FMFRs and/or fluid pressures delivered to the formations.
The hydrocarbon recovery system 100 further comprises a communications relay 132 and a logging and control processor 134. The communications relay 132 may receive information and/or data from sensors, transmitters, and/or receivers located within the electronic components 112 and/or other communicating devices. The information may be received by the communications relay 132 via a wired communication path through the drillstring 102 and/or via a wireless communication path. The communications relay 132 may transmit the received information and/or data to the logging and control processor 134 and the communications relay 132 may receive data and/or information from the logging and control processor 134. Upon receiving the data and/or information, the communications relay 132 may forward the data and/or information to the appropriate sensor(s), transmitter(s), and/or receiver(s) of the electronic components 112 and/or other communicating devices. The electronic components 112 may comprise measuring while drilling (MWD) and/or logging while drilling (LWD) devices and the electronic components 112 may be provided in multiple tools or subs and/or a single tool and/or sub. In alternative embodiments, different conveyance types including, for example, coiled tubing, wireline, wired drill pipe, and/or any other suitable conveyance type may be utilized. In some embodiments, the above-described communications may comprise mud pulse telemetry in which the drilling fluid 124 and/or hydraulic fracturing fluids are used as a communication medium.
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In some embodiments, the pumping system fluid output 206 may be referred to as a trunk line. The pumping system fluid output 206 is a common output conduit into which substantially all of the fluid displaced by the pistons is commonly driven by the pump 202. In other words, regardless of whether each piston and/or set of pistons comprises a dedicated output from the pump 202, all of the piston outputs and/or set of pistons outputs are in fluid communication with and feed fluid to the pumping system fluid output 206. The pumping system 200 further comprises a feedforward active controller (FAC) 212, a sensor 214 associated with the pump 202, and a sensor 216 associated with the pumping system fluid output 206. The sensor 214 is also referred to as a second sensor 214 and the sensor 216 is also referred to as a first sensor 216. The FAC 212 comprises a general purpose processor and/or a computer and the FFN 208 is in fluid communication with the pumping system fluid output 206 via a fluid tap conduit 210. The sensor 214 is configured to receive and/or report operational information regarding the operation of the pump 202, namely, a speed and/or phase of the pump 202. In this case, the sensor 214 comprises a tachometer configured to measure a speed of a common drive shaft of the pump 202 that powers movement of one or more of the pistons of the pump 202 via a substantially kinematically predicable mechanical linkage. In this case, signals generated by the FAC 212 as a function of shaft speed information provided to the FAC 212 by the sensor 214 are phase locked to the shaft speed. In this embodiment, the phrase “phase of the pump” is intended to reference a known location and/or motion characteristic of a piston of the pump 202. Phase locking to the shaft speed may track changes in a phase of the pump in part because of the substantially kinematically predictable mechanical linkage between the drive shaft and the pistons of the pump 202. As a result, the sensor enables the FAC 212 to track, predict, estimate, and/or otherwise utilize a phase of the pump 202. In some cases, the phase of the pump 202 may be a value that is directly related to a frequency of a piston of the pump. In alternative embodiments, the sensor 214 may comprise a hall effect sensor and/or any other suitable device for providing operational information regarding a phase of the pump 202 to the FAC 212. In cases where a hall effect sensor is utilized, the sensor 214 may substantially directly measure a phase of a piston and/or a phase of the pump 202. In some embodiments, tachometers and hall sensors, for example, are generally used to provide shaft rotational speed information and/or piston reciprocation frequency, respectively, and are phase-locked to the motion of the pump 202/piston assembly, as the pump 202 system is substantially kinematically predictable. The sensor 216 may comprise a pressure sensor, a mass flow sensor, a velocity sensor, and/or any other suitable device for sensing and/or reporting information to the FAC 212 about a FFC of the fluid within the pumping system fluid output 206, namely, FMFR, fluid pressure, and/or associated noise information. The FAC 212 is generally configured to receive the information from the sensors 214, 216 and output a control signal to FFN 208. The control signal may be amplified and may control and/or vary the operation of the FFN 208 to normalize a FFC of fluid of the pumping system fluid output 206 to at least one of (1) decrease a variability in the FFC, (2) decrease noise transmitted via the drilling fluid 124, and (3) decrease vibrational energy of a component of the pumping system 200 and/or a component attached to the pumping system 200 (e.g., a hose). In some embodiments, the FAC 212 may operate substantially similarly to one or more of the feedforward active control systems known to those skilled in the art. In short, the FAC 212 is configured to (1) determine and synchronize with an operational phase of the pump 202 as a function of the known and/or modeled physical characteristics of the pump 202 and the information received from the sensor 214 that is associated with the pump 202, (2) determine, calculate, and/or receive FFC information, such as, but not limited to, pressure information and/or FMFR information regarding the fluid of the pumping system fluid output 206, and (3) send control signals to the FFN 208 to operate the FFN 208 synchronously with the pump 202 to alter at least one FFC of the fluid of the pumping system fluid output 206.
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In operation, the pumping system 200 may operate to actively monitor, regulate, and/or normalize a FFC of the fluid within the pumping system fluid output 206.
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In alternative embodiments, any number and combination of FFNs disclosed above may be used together and controlled by FAC 212 to manage normalization of a FFC of a fluid of the pumping system fluid output 206. In some cases, one or more of the FFNs may be selectively disabled when not needed to achieve a normalization goal. Further, it will be appreciated that while the above-described FFNs are disclosed primarily as functioning to inject and/or displace fluid into the pumping system fluid output 206 to achieve normalization, in alternative embodiments, one or more of the FFNs may be configured to selectively remove fluid from the pumping system fluid output 206 to achieve normalization. In other words, the systems and methods disclosed and contemplated herein may equally achieve an FFC normalization goal by reducing FMFR and/or pressure pulse amplitudes rather than increasing rates of fluid injections during periods of low FMFR and/or pressure amplitudes. In some embodiments, pumping systems may comprise both injecting and evacuating type FFNs.
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The FAC 612 is generally configured to receive the information from the sensors 614, 616 and output a control signal to FFN 608. The control signal may control and/or vary the operation of the FFN 608 to normalize an FFC of the pumping system fluid output 606 to at least one of (1) decrease a variability in the FFC, (2) decrease noise transmitted via the drilling fluid, and (3) decrease vibrational energy of a component of the pumping system 600 and/or a component attached to the pumping system 600 (e.g., a hose). In short, the FAC 612 is configured to (1) determine and synchronize with an operational phase of the pump 602 as a function of the speed of the pump 602, (2) determine, calculate, and/or receive FFC information (i.e. pressure information and/or FMFR information) regarding the fluid of the pumping system fluid output 606, and (3) send control signals to the FFN 608 to operate the FFN 608 synchronously with the pump 602 to alter an FFC of the fluid within the pumping system fluid output 606. In this embodiment, the FFN 608 comprises an actuator 610 that is in fluid communication with the pumping system fluid output 606. The actuator 610 may comprise an electrically driven piezoelectric transducer configured to effectively increase and/or decrease a volume of the pumping system fluid output 606 and/or by adding and/or removing fluid from the pumping system fluid output 606 in response to a control signal from the FAC 612. In this embodiment, the fluid and/or volume changes are associated with inverse and/or accommodating fluid and/or volume changes within an associated fluid reservoir 618. In some embodiments, the fluid reservoir may be segregated from the fluid of the pumping system fluid output 606 by a membrane or other flexible barrier as with FFN 400. While the actuator 610 is attached to the pumping system fluid output 606, in alternative embodiments the actuator may be attached directly to the pump output manifold 605. The tachometer sensor 614 provides an indication of the pump speed or frequency and a primary noise frequency may be a multiple of three of a measured pump 602 speed because there are three pistons. The pressure transducer and/or pressure sensor 616 provides real-time data for the FAC 612 to allow the FAC 612 to determine the phasing and amplitude needed for sending to the actuator 610 to reduce noise and/or pressure variations generated by the pump 602.
Other embodiments of the current invention will be apparent to those skilled in the art from a consideration of this specification or practice of the invention disclosed herein. Thus, the foregoing specification is considered merely exemplary of the current invention with the true scope thereof being defined by the following claims.
The present application claims priority to U.S. Provisional Patent Application No. 61/786,836 filed on Mar. 15, 2013 by Donald P. Margolis, et al., entitled “FLUID FLOW NORMALIZER,” which is incorporated by reference herein as if reproduced in its entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/025698 | 3/13/2014 | WO | 00 |
Number | Date | Country | |
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61786836 | Mar 2013 | US |