This section provides background information to facilitate a better understanding of the various aspects of the disclosure. It should be understood that the statements in this section of this document are to be read in this light, and not as admissions of prior art.
Wells are generally drilled into the ground to recover natural deposits of hydrocarbons and other desirable materials trapped in geological formations in the Earth's crust. A well is typically drilled using a drill bit attached to the lower end of a drill string. The well is drilled so that it penetrates the subsurface formations containing the trapped materials and the materials can be recovered.
At the bottom end of the drill string is a bottom hole assembly (“BHA”). The BHA includes the drill bit along with sensors, control mechanisms, and the required circuitry. A typical BHA includes sensors that measure various properties of the formation and of the fluid that is contained in the formation. A BHA may also include sensors that measure the BHA's orientation and position.
The drilling operations may be controlled by an operator at the surface or operators at a remote operations support center. The drill string is rotated at a desired rate by a rotary table, or top drive, at the surface, and the operator controls the weight-on-bit and other operating parameters of the drilling process.
Another aspect of drilling and well control relates to the drilling fluid, called mud. The mud is a fluid that is pumped from the surface to the drill bit by way of the drill string. The mud serves to cool and lubricate the drill bit, and it carries the drill cuttings back to the surface. The density of the mud is carefully controlled to maintain the hydrostatic pressure in the borehole at desired levels.
In order for the operator to be aware of the measurements made by the sensors in the BHA, and for the operator to be able to control the direction of the drill bit, communication between the operator at the surface and the BHA are necessary. A downlink is a communication from the surface to the BHA. Based on the data collected by the sensors in the BHA, an operator may desire to send a command to the BHA. A common command is an instruction for the BHA to change the direction of drilling.
Likewise, an uplink is a communication from the BHA to the surface. An uplink is typically a transmission of the data collected by the sensors in the BHA. For example, it is often important for an operator to know the BHA orientation. Thus, the orientation data collected by sensors in the BHA is often transmitted to the surface. Uplink communications are also used to confirm that a downlink command was correctly understood.
One common method of communication is called mud pulse telemetry. Mud pulse telemetry is a method of sending signals, either downlinks or uplinks, by creating pressure and/or flow rate pulses in the mud. These pulses may be detected by sensors at the receiving location. For example, in a downlink operation, a change in the pressure or the flow rate of the mud being pumped down the drill string may be detected by a sensor in the BHA. The pattern of the pulses, such as the frequency, the phase, and the amplitude, may be detected by the sensors and interpreted so that the command may be understood by the BHA.
One method of mud pulse telemetry is disclosed in U.S. Pat. No. 3,309,656, comprises a rotary valve or “mud siren” pressure pulse generator which repeatedly interrupts the flow of the drilling fluid, and thus causes varying pressure waves to be generated in the drilling fluid at a carrier frequency that is proportional to the rate of interruption. Downhole sensor response data is transmitted to the surface of the earth by modulating the acoustic carrier frequency. A related design is that of the oscillating valve, as disclosed in U.S. Pat. No. 6,626,253, wherein the rotor oscillates relative to the stator, changing directions every 180 degrees, repeatedly interrupting the flow of the drilling fluid and causing varying pressure waves to be generated. Some pulse generating valves are subject to jamming and erosion, given the nature of moving parts, and some have power consumption levels that are limiting in a downhole environment.
In accordance to aspects of one or more embodiments a fluidic modulator includes a body forming a flow aperture between an inlet and an outlet, the flow aperture having a nominal diameter less than the inlet diameter and the outlet diameter and a moveable portion operable to alter the flow aperture. A drive mechanism may be connected to the moveable portion and operable to radially shift the moveable portion in the flow aperture, rotate the moveable portion in the flow aperture, or control the rotation of the moveable portion in the flow aperture. In accordance to a method a pressure pulse is created in the fluid flow in response to moving the moveable portion.
This summary is provided to introduce a selection of concepts that are further described below in the detailed description. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of claimed subject matter.
Embodiments of fluid modulator devices, systems and methods are described with reference to the following figures. The same numbers are used throughout the figures to reference like features and components. It is emphasized that, in accordance with standard practice in the industry, various features are not necessarily drawn to scale. In fact, the dimensions of various features may be arbitrarily increased or reduced for clarity of discussion.
It is to be understood that the following disclosure provides many different embodiments, or examples, for implementing different features of various embodiments. Specific examples of components and arrangements are described below to simplify the disclosure. These are, of course, merely examples and are not intended to be limiting. In addition, the disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.
Fluidic modulators, systems, and methods disclosed herein may provide lower power consumption than current devices, a wider operating range than current devices, the capability to isolate the surface receiver from drilling and mud motor noise, the capability to isolate surface rig and mud pump noise from the downhole receivers and transmitters, provide the ability to perform fishing operations through the modulation device which is substantially co-axial with the drill string, and provides amplitude control (e.g., amplitude magnitude and/or quadrature amplitude modulation (“QAM”) control of the mud pulse signal. In accordance to aspects the fluidic modulator permits the use of high bandwidth efficiencies such as QAM. The fluidic modulator provides dynamic gapping control. For example, the disclosed fluidic modulators may permit the gap setting to be changed while the fluidic modulator is located downhole in order to change the generated signal strength to accommodate changes in the mud flow rate. In accordance to aspects of the disclosure the fluidic modulators are capable of phase, frequency, amplitude, or any combination of those, single-carrier or multi-carrier modulation, using a wide range of frequencies. The disclosed fluidic modulators can utilize these modulations when they function for example as uplink, downlink or along the string measurement or repeater tools.
Depicted drill string 14 includes a bottom hole assembly (“BHA”) 33, which includes at least one downhole tool 34. Downhole tool 34 may comprise survey or measurement tools, such as, logging-while-drilling (“LWD”) tools, measuring-while-drilling (“MWD”) tools, near-bit tools, on-bit tools, and/or wireline configurable tools. LWD tools may include capabilities for measuring, processing, and storing information, as well as for communicating with surface equipment. Additionally, LWD tools may include one or more of the following types of logging devices that measure characteristics associated with the formation 18 and/or the wellbore: a resistivity measuring device; a directional resistivity measuring device; a sonic measuring device; a nuclear measuring device; a nuclear magnetic resonance measuring device; a pressure measuring device; a seismic measuring device; an imaging device; a formation sampling device; a natural gamma ray device; a density and photoelectric index device; a neutron porosity device; and a borehole caliper device. A LWD tool is identified specifically with the reference number 120 in
MWD tools may include for example one or more devices for measuring characteristics adjacent drill bit 16. MWD tools may include one or more of the following types of measuring devices: a weight-on-bit measuring device; a torque measuring device; a vibration measuring device; a shock measuring device; a stick slip measuring device; a direction measuring device; an inclination measuring device; a natural gamma ray device; a directional survey device; a tool face device; a borehole pressure device; and a temperature device. MWD tools may detect, collect and/or log data and/or information about the conditions at the drill bit 16, around the underground formation 18, at a front of the drill string 14 and/or at a distance around the drill strings 14. A MWD tool is identified with the reference number 130 in
Downhole tool 34 may comprise a downhole power source, for example, a battery, downhole motor, turbine, a downhole mud motor or any other power generating source. The power source may produce and generate electrical power or electrical energy to be distributed throughout the BHA 33 and/or to power the at least one downhole tool 34.
Depicted downhole tool 34 includes a sensor 36, e.g., sensor assembly, data source, and a fluidic modulator 200 for mud pulse telemetry in accordance to one or more aspects of this disclosure. Fluidic modulator 200 is operated to disrupt the flow of the drilling fluid 20 through the drill string 14 to cause pressure pulses or changes fluid flow. The pressure pulses are modulated by operation of the fluidic modulator and thereby encoded for telemetry purposes. For example in
The surface system processor, as well as other processors, may be implemented using any desired combination of hardware and/or software. For example, a personal computer platform, workstation platform, etc. may store on a computer readable medium, for example, a magnetic or optical hard disk and/or random access memory and execute one or more software routines, programs, machine readable code and/or instructions to perform the operations described herein. Additionally or alternatively, the surface system processor may utilize dedicated hardware or logic such as, for example, application specific integrated circuits, configured programmable logic controllers, discrete logic, analog circuitry and/or passive electrical components to perform the functions or operations described herein.
The surface system processor may be positioned relatively proximate and/or adjacent to the drilling rig 10. In other words, the surface system processor may be substantially co-located with the drilling rig 10. Alternatively, a part of or the entire surface system processor may alternatively be located relatively remote with respect to the drilling rig 10. For example, the surface system processor may be operationally and/or communicatively coupled to the fluidic modulator 200 via any combination of one or more wireless or hardwired communication links. Such communication links may include communications links via a packet switched network (e.g., the Internet), hardwired telephone lines, cellular communication links and/or other radio frequency based communication links which may utilize any communication protocol.
BHA 33 may include one or more downhole tools such as a logging-while-drilling (“LWD”) tool 120 and/or a measuring-while-drilling (“MWD”) tool 130, a motor 150 (e.g., mud motor), a rotary steering system (“RSS”) 155 and drill bit 16. In accordance with some embodiments, mud motor 150 converts fluid power in the downward mud flow into rotary motion. The rotary motion is transmitted to the portions of the BHA below mud motor 150. In some embodiments, the mud motor 150 comprises a positive displacement motor (“PDM”) or turbodrill.
LWD tool 120 can be housed in a special type of drill collar, as is known in the art, and can contain one or more known types of logging tools. LWD tool 120 may include capabilities for measuring, processing and storing information, as well as for communicating with surface equipment. LWD tool 120 may be employed to obtain various downhole measurements as generally represented by one or more sensors (e.g., sensor assembly) identified generally as local or data source sensors 36.
MWD tool 130 can also be housed in a special type of drill collar, as is known in the art, and can contain one or more devices for measuring characteristics of the drill string and drill bit. It will also be understood that more than one MWD can be employed. MWD tool 130 may include capabilities for measuring, processing and storing information, as well as for communicating with surface equipment. MWD tool 130 may be employed to obtain various downhole measurements as generally represented by one or more sensors (e.g., sensor assembly) identified generally as data source sensors 36.
System 100 depicted in
Similar to the system depicted in
The fluidic modulator 200 (i.e., modulation mechanism) includes a flow path through which drilling fluid, i.e., mud, can flow. The flow path may include a venturi having a constricted flow aperture 216 or reduced flow path area, i.e. constriction or throat. The fluidic modulator includes a moveable portion or element 218, which can be operated to alter or disrupt the fluid flow through the constricted flow aperture for example by changing the size or cross-section area of the flow aperture or otherwise changing the resistance to the fluid flow through the flow aperture. The moveable element can be formed in various geometric shapes and configurations as will be understood with benefit of this disclosure. The movement of the moveable element for example radially relative to the inner wall of the throat or relative to the longitudinal axis of the fluidic modulator flow path changes the nominal diameter of the flow aperture. In accordance to one or more aspects the moveable element may be rotated in the flow aperture to change the cross-sectional surface area of the moveable element that is blocking the flow aperture. For example, a moveable element may have two sides or faces having different cross-sectional surface areas. Rotating the moveable element from a first face being positioned in the flow aperture perpendicular to the direction of the fluid flow to a second face being positioned in the flow aperture perpendicular to the fluid flow may increase or may decrease the cross-sectional area of the flow aperture that is open for fluid flow. In accordance to an aspect of at least one embodiment, a moveable element moves in response to the fluid flow and controlling the moveable elements resistance to movement alters the resistance to the fluid flow through the flow aperture thereby creating pressure pulses.
It should be recognized that the movement of the moveable element may not reduce the cross-sectional area of the flow aperture but instead increase the cross-section area for example when the moveable element is moved radially outward from the flow path thereby increasing the flow path area relative to the nominal flow path area or when a moveable element is rotated from a first face to a second face having a smaller blocking surface area than the first face. Accordingly, movement of the moveable element may be said to change or alter the flow aperture for example by increasing or decreasing the area (e.g. cross-sectional area) of the flow aperture (i.e. throat, constriction), altering the course of the fluid flow through the flow aperture, changing the texture of the wall forming the flow aperture, or otherwise disturbing the boundary layer of the fluid flow through the fluidic modulator.
In a different configuration, such as a circular shaped moveable element 218 the circumferential coverage angle 221 can vary with the radial distance it is extended into the throat or flow aperture 216. In accordance to various aspects, moveable element 218 may be rotationally or linearly translated in and out of the flow aperture of the fluidic modulator. For example, the moveable element may be in a circular shape and be linearly translated into and out of the flow path; accordingly the circumferential coverage of the moveable element 218 will increase as it is translated into the flow path. Similarly, a moveable element 218 may be rotated radially into the flow aperture from the side or circumferentially rotated into the flow aperture in a manner such that the circumferential coverage changes. In accordance to some aspects, the moveable element 218 may be positioned in the flow aperture and rotatable to position different faces of the moveable element that have different surface areas perpendicular to the direction of the fluid flow.
By way of example, top moveable element 218 is illustrated in
The pressure drop in the fluid flow may be caused by a combination of the choking effect of the movable element and the disruption of the fluid boundary layer in the exit funnel or diffuser of the fluidic modulator. Depending on the blocking surface area of the disposed movable element and/or the distance the moveable element is projected into or out of the flow aperture, the pressure drop may be caused mostly, if not entirely, by the boundary layer disruption.
By utilizing a movable element that extends into only a fraction of the fluidic modulator flow path, the likelihood of jamming the fluidic modulator is reduced, if not eliminated. For example, poppet and mud siren types of mud pulse devices have a blocking element that remains positioned in the flow path of the amplifying device and of the drill string. In addition, fishing operations may be performed, for example by moving the moveable element out of the flow path. If necessary, the moveable element can be broken off or pushed out of the flow path when necessary fishing operations are performed.
In conjunction with the fluidic modulator, upstream and downstream pressure sensors can be positioned to monitor the signal amplitude, see e.g.
To allow for erosion of the movable element, the movable element can be configured to have an extended length so that, as the distal end of the movable element is eroded, the additional length of the movable element can be utilized to extend the overall life of the fluidic modulator. This technique can be used to improve signal strength at greater depths, by using a short length at shallow depths and a longer length at greater depths. In general, the length could be modified by downlink commands from the surface or an automated algorithm downhole. Redundant moveable elements, e.g., faces or tabs, may also be utilized to address erosion and/or for additional amplitude control, e.g. dynamic length or gap control.
Some systems may include a multi-stage type of venturi, where several fluidic modulators are placed back to back in order to achieve a large pressure drop without requiring an extremely small diameter constriction.
Fluidic modulator 200 itself reflects tube waves in general and can be made to have different reflection coefficients in each direction, thus providing noise isolation between the surface, where the pressure transducers are located, and the BHA elements that are below the fluidic modulator (e.g., mud motors, active reamers, vibrating tools), see for example
Movement of the moveable element to block portions of the flow aperture may result in the generation of pressure waves with fast rise times, such as a few milliseconds. The resulting reaction force on the structure anchoring the fluidic modulator, such as the drill string, can impart vibration to the BHA. The vibration may be used to reduce or resist differential sticking and may be utilized for wellbore cleaning, increased rate of penetration and for other drilling optimization techniques.
The fluidic modulator can be used in many different applications, including uplink transmitters, mid-string repeaters, along-string communications, along-string measurements, lost circulation material (“LCM”) tolerant/fail safe pulsers, downlinks, subsurface seismic exploration systems, and in high temperature applications (e.g., low power actuator). Other applications include without limitation as an agitator to shake the BHA for example to prevent sticking, as a hammer drill device for example with a PDC bit, and as an actuator to shift a piston or sleeve in response to a pressure differential. For example, fluidic modulators 200 may be utilized to actuate the rotary steering system (i.e., bias unit) 155 in
Fluidic modulator 200 includes a moveable portion or element 218 (e.g. modulator, tab, tip) that can alter the size of the flow constriction or flow aperture 216 and/or to disrupt the boundary layer and create an amplified pressure drop in the flow aperture 216. The pressure drop can be modulated, and thus encoded for telemetry purposes, by selectively controlling movement of the moveable element 218 relative to the diameter or cross-sectional area of the constriction or flow aperture. The destabilized fluid flow does not recover before entering the diffuser 214. The destabilized fluid flow does not efficiently recover the created amplified pressure drop in the diffuser 214 consequently creating an amplified pressure drop between the inlet 211 and the outlet 213.
Depicted moveable element 218 is connected to a drive mechanism 220 (e.g., actuator, solenoid, controller, motor, brake) that moves and/or controls movement of movable element to induce changes in the flow aperture or changes to the resistance to fluid flow through the flow aperture. A change in the flow aperture may be an increase or a decrease in the cross-sectional area of the flow aperture, a change in the texture (i.e. friction) of the wall of the flow aperture, and/or altering the fluid flow path or flow regime (e.g., turbulent, laminar) through the fluidic modulator. In
In
Any known drive mechanism for shifting or controlling the movement of the movable element is contemplated, including the use of a hydraulic drive. Further, the movable element can be configured to minimize exposure of the drive mechanism to the drilling fluid, such as by the use of bellows or other structures. In accordance to some aspects, a diamond interface between the moveable element and the body may be provided to minimize the exposure of the drive mechanism to the particular in the drilling fluid. It is contemplated that the movable element and/or the drive mechanism can be made of active materials, such as Terfenol D, to eliminate moving parts. Other active materials, such as a ceramic stack (e.g. piezoelectric ceramic stack) and a dual opposed ceramic stack can be utilized to eliminate moving parts, reduce power consumption, and/or thermally compensate the device.
In accordance to aspects of the disclosure, a moveable element 218 may form a portion of flow aperture 216. For example, moveable element 218 may form a limited part of the circumferential inner wall 219 of the constriction or flow aperture 216 or may form a full circumferential portion or section of flow aperture 216. Accordingly, moveable element 218 may be expanded, rotated, moved radially or otherwise moved to change the size of flow aperture 216 for example from nominal diameter 215 to a reduced or an expanded diameter and thereby change the cross-sectional area of the flow aperture.
Fluidic modulator 200 may include multiple moveable elements 218 and/or multiple blocking surfaces or faces 228. In accordance to some embodiments the moveable elements may be separately and independently moveable, for example the moveable elements 218 may be connected to separate drive mechanisms. For example, one or more moveable elements 218 may be radially expanded or contracted while other elements 218 remain static or moved in an opposing expanded or contracted position.
A multiple moveable element fluidic modulator can provide signal modularity control and manipulation. For example, a first moveable element or blocking surface may be configured to have a surface area sized relative to the flow aperture cross-sectional area to create a first pressure drop that may be suited for communications at a first subsurface depth. A second moveable element or blocking surface may be configured to have a different surface area from the first blocking surface to create a second pressure drop that may be suited for communications at a second subsurface depth. In some embodiments, the two or more moveable elements may be operated in combination to create the desired pressure drop. Accordingly, the fluidic modulator can provide the needed pressure pulses for communication at different depths without having to remove the fluidic modulator from the wellbore to adjust the pulse magnitude. In accordance to an aspect of a method of operation, a pressure signal emitted from a downhole fluidic modulator may be received at a sensor and information regarding the strength of the received pressure signal may be fed-back to the fluid modulator so that the pressure pulse strength of the fluidic modulator can be adjusted.
Refer now to
The depicted moveable element 218 is radially and linearly translated in and out of the fluid flow path of flow aperture 216 by drive mechanism 220 via a shaft 224. In the illustrated example, shaft 224 extends through an outer bearing surface or sleeve 226 located in body 210. As further described below, the shaft 224 portion of the moveable element and the outer bearing surface may be constructed of diamond. In
The geometric shape of moveable element 218, in particular the blocking surface or face 228, may be configured in various configurations and the illustrated and described geometric shape and configuration is one example. The geometric shape of the illustrated moveable element 218 has a slightly concave face 228 and an elongated and perhaps aerodynamic trailing edge or tail 230. This geometric shape of the moveable element may create a similar pressure change within the constriction or flow aperture as a result of disturbing and choking the fluid flow compared to other blocking surface profiles. The concave front blocking surface or face 228 may act to impart swirl and vortices into the fluid flow and disrupt boundary layers on the inner wall 219. The elongated tail 230 may improve the fluid dynamics around the moveable element to reduce erosion. The strength of the pressure pulse may be controlled by varying the distance that the moveable element is extended into flow aperture 216 from the inner wall. As previously noted, the moveable element 218 may be formed in various geometric shapes. In accordance to some embodiments, moveable element 218 may be circular shape (i.e. disc) that is linearly translated relative to the side wall of the flow aperture.
Drive mechanism 220 is illustrated connected to electronics 236 which may include for example, and without limitation, a power source, electronic circuits, a processor, memory, transducers (e.g. pressure transducer), and the like. Electronics 236 or similar electronics may be utilized with the fluidic modulators disclosed in the various figures. In operation, a signal can be communicated to modulator 200 to actuate and create a pressure pulse signal in the fluid 20; the modulator 200 may be actuated in response to a programmed event. In
In
Diamond technology permits producing diamond approximately one inch in all directions, which limits the size of components that can be produced out of a single diamond piece. A reduced erosion geometric shape, such as illustrated in
Diamond can be manufactured to extremely tight tolerances such that two cylinders naturally act as a journal bearing. In
The cross-sectional area of the flow aperture 216 is reduced by the portion of moveable element 218, i.e. the blocking surface or face 228 that extends into the flow aperture and blocks fluid flow through the flow aperture. It can be understood with reference to
Due to the size constraints inside a drill collar, i.e. housing or body 210, the larger the diameter of constriction or flow aperture 216 the smaller the moveable element 218 that can be used. For example, it is conceived that a 2.1 inch throat diameter is needed to pass a significant number of downhole tools and downhole pressure valve balls, for example for reamers, flow bypass subs, etc. Assuming a 6.75 inch tool outside diameter, signal strengths of 15-20 psi can be achieved from a single moveable element 218. In accordance to one or more aspects, signal strengths of 15-20 psi may be utilized in along-the-string measurement (“ASM”) systems. Accordingly, the fluidic modulator can be utilized along the string.
The orientation of moveable element 218 may act to fill any gaps in the venturi throat walls. In an open position, see for example
As noted previously, more than one moveable element may be positioned in the flow aperture simultaneously. For example,
A multiple, e.g. twin, moveable element assembly configuration can provide for covering a larger percentage of the cross-sectional flow area of the flow aperture than a single moveable element assembly thereby permitting larger signal strengths while maintaining a flow aperture diameter that is large enough for passing other tools. The larger the flow aperture diameter the more wellbore applications and operations the fluidic modulator can be utilized. Additionally, the larger flow aperture diameter corresponds to lower fluid flow speeds which also results in improved erosion control.
The moveable elements 218, i.e. blocking surface or face, may be tilted at a non-perpendicular angle to the longitudinal axis. For example, in
The drive mechanism 220 and the electronics are located in the body 210 of the fluidic modulator (e.g., in a drill collar). The fluidic modulator electronics, e.g. electronics 236 in
The tilt of the moveable element relative to the longitudinal axis may reduce the erosion of the moveable element. The tilt of the moveable element may also increase the signal strength relative to a moveable element oriented perpendicular to the longitudinal axis. The tilt of the moveable element away from perpendicular may alter the boundary layer.
Rotating the circular moveable element arrangement in the fluid flow direction may allow the fluid flow 20 to drive the circular moveable element arrangement. Drive mechanism 220 can provide less torque than in other configurations and the drive mechanism may apply braking torque rather than a drive torque. For example, a pressure signal pulse can be created by applying braking torque to the rotating moveable elements and changing the resistance to the fluid flow through the flow aperture. By controlling multiple rotating moveable element assemblies separately, additional amplitude control can be applied.
Refer now to
In
Refer now to
In
In
As discussed previously, the mud pump noise and the reflected generated signal are attenuated as they pass through the fluidic modulator (e.g., venturi). In accordance to aspects of the disclosure, the fluidic modulator can be utilized as an along the string repeater and/or for along-the-string measurements (“ASM”). Fluidic modulators are located at intervals along the drill string, for example every 1,000 feet or so, as a repeater. In accordance to aspects the fluidic modulators may be located at different interval lengths as desired by an operator or as dictated by the well installation. For example, fluidic modulators may be separated by 250 feet or so in one wellbore and the fluidic modulators may be separated by 1,500 or more feet in a second wellbore. Similarly, the intervals between adjacent fluidic modulators may change within a single wellbore.
Sensors (e.g., data sources 36, pressure transducers 40) can be located along the drill string (
Fluidic modulator 200b may attenuate some or all of the signal strength of the original pressure pulse transmitted from modulator 200a to 200b. Fluidic modulator 200b may create the signal carrying pressure pulse at a different frequency than used from modulator 200a to 200b. The pressure pulse from modulator 200b is received at modulator 200c and is then retransmitted with additional data obtained by sensor package 310c. In accordance to some embodiments, modulator 200c may transmit at the same carrier frequency as modulator 200a. The process can continue transmitting the original data from the BHA and the measurements obtained at the along the string sensor packages 310b, 310c, 310d, etc. along the string, i.e. drill string 14.
In accordance to an aspect of the disclosure a well system includes a first fluidic modulator (FM) located at the bottom of the tubular string and a repeater fluidic modulator (FM) located in the tubular string between the first FM and the surface, the repeater FM including a body forming a flow aperture between an inlet and an outlet, the flow aperture providing a constriction to a fluid flowing axially through the tubular string, and a moveable portion operable to alter the flow aperture. To create a modulated pressure pulse the moveable portion may be for example radially shifted in the flow aperture, rotated in the flow aperture, or the rotation of the moveable portion in the flow aperture may be controlled. The repeater FM may communicate local data with the original data received from the first FM. In accordance to an aspect of a method a first fluidic modulator transmits a first pressure pulse which is received a repeater fluidic modulator which then transmits the original data in a second pressure pulse. The second pressure pulse may include local data in addition to the repeated data.
The foregoing outlines features of several embodiments so that those skilled in the art may better understand the aspects of the disclosure. Those skilled in the art should appreciate that they may readily use the disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the disclosure, and that they may make various changes, substitutions and alterations herein without departing from the spirit and scope of the disclosure. The scope of the invention should be determined only by the language of the claims that follow. The term “comprising” within the claims is intended to mean “including at least” such that the recited listing of elements in a claim are an open group. The terms “a,” “an” and other singular terms are intended to include the plural forms thereof unless specifically excluded.
Number | Date | Country | |
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61860206 | Jul 2013 | US | |
61913347 | Dec 2013 | US | |
62002901 | May 2014 | US | |
62002904 | May 2014 | US |