The present invention relates to telemetry systems for use in a wellbore during drilling and logging-while-drilling (LWD) operations. More particularly, the present invention relates to a method and system for transmitting downlinking commands from a surface-located modulator of harmonic pressure wave signals to a downhole receiver without a physical component inside of a fluid line for generation of the pressure wave signals.
A well is typically drilled using a drill bit attached to the lower end of a drill string. At the bottom end of the drill string is a bottom hole assembly (BHA), which can typically include the drill bit, a downhole motor (optional), sensor(s), a source of power, a signal generator, a rotary steerable system (RSS) (optional), and circuitry. A typical BHA includes sensors that measure the BHA's orientation and position, as well as sensors that measure various properties of the formation, such as resistivity, gamma, sonic destiny, porosity, and the like. Some of the measurements can include azimuthal information. Other information and data that may be transmitted from the BHA to the surface can include, e.g., temperature, pressure, drilling parameters, and the like.
The process of drilling can be controlled by comprehensive communication using various experts and operators, and based on analysis of information obtained from the downhole and surface sensors. 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 parameters of the drilling process. Another aspect of drilling relates to the drilling fluid (mud), which is pumped from the surface to 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 controlled to maintain hydrostatic pressure in the borehole at desired levels.
During drilling operations, various instructions are sent to the BHA from the surface in order to change adjustable drilling parameters, change logging parameters, and to change or adjust the communication parameters between the surface and downhole system to improve transfer of data. Such communications are known and referred to herein as a “downlink”.
Likewise, an “uplink” (as known in the industry and referred to herein) is a communication from the BHA to the surface. An uplink is a transmission of the data collected by the sensors in the BHA. Such data can be used to confirm that the downlink command was correctly detected.
One of the most common downlinking methods in the industry includes using variation of mud flowrate, drill string rotation speed, and generations of series of negative pressure pulses. During the downlinking process, one or more of these parameters are caused to change in magnitude or time duration and/or in numbers.
A downlink using pressure generally necessitates a bypass valve, manipulation of which causes negative pulses to be transmitted through the drilling fluid and detected by a pressure transducer. Typically, the bypass valve diverts a portion of the high-pressure fluid from the supply line back to the mud pit that is at atmospheric pressure. Such venting action can generate high fluid velocities through the valve, resulting in erosion. Valve failure due to such erosion is a safety hazarded under the high pressured environment. In addition, the data transmission speed for such downlinking process can be extremely slow.
U.S. Pat. No. 8,174,404 discusses use of a pulser for downlinking which is disposed in the drilling fluid supply line without the need of a bypass valve. The disadvantage of this option is that a pulser disposed inside of the supply line significantly obscures the flow area, resulting in the need to use a higher pumping pressure level which, in turn, can cause acceleration of wear and tear of the pumping equipment.
Changing the rotational speed to send a downlink signal is not a common method due to the large rotational inertia of the entire drill string. In addition, the rotational speed changes caused by the drilling process may be improperly interpreted by the system as a downlinking command.
One method in the industry for downlinking communications is manipulation of the drilling flow rate to cause changes in the downhole turbine rotation speeds. This method necessitates that the rotary steerable system (RSS) is equipped with a turbine/turbine alternator. Further, in addition to mud pumps, such process necessitates a hydraulic bypass unit controlled by the service company. However, manipulation of the drilling flow rate for downlinking communications results in slow transmission speeds, e.g., typically about 5-10 minutes of a single downlinking command. The low transmission speed limits the amount of downlinking commands and their varieties, preventing the industry from having more control over acquisition parameters and optimal density of the observation.
U.S. application Ser. No. 17/556,502 discusses a downlinking continuous combinatorial frequencies alphabet method and system for downlinking communication during MWD/LWD operations from a surface location to a downhole location by using a pressure wave modulator which is disposed inside of the fluid supply line pipe. The mud pulse system provides a fast and robust downlinking operation capable of optimizing data acquisition and improves management of the rotary steerable system (RSS). However, said system necessitates insertion into the fluid supply pipe at least a portion of equipment containing a rotational restrictional flap.
As such, there is a need in the industry to generate harmonic pressure waves for downlinking without necessitating inclusion of a restrictor of the drilling flow inside the supply pipe. In particular, there is a need in the industry for a system that is capable of generating pressure wave signals in the drilling fluid without a physical component disposed inside of the fluid line for generating said pressure wave signals.
The present invention discloses a downlinking continuous combinatorial frequencies alphabet method and system for continuous downlinking communication during logging-while-drilling (LWD) and measurement-while-drilling (MWD) operations from a surface location to a downhole location by using a pressure wave modulator disposed entirely outside of a surface fluid supply line. The pulser itself therefore does not obscure or block the flow area of the fluid supply line pipe, ensuring the desired pumping pressures are maintained. The exemplary mud pulse telemetry system provides a fast and robust, continuous downlinking operation capable of providing optimization of data acquisition and improves management for the rotary steerable system (RSS).
In some embodiments, the periodical signals used by the system are frequencies or orthogonal frequencies. In some embodiments, the combinatorial alphabet frequencies method used by the system can include selection and evaluation of the existing modulator or a selection of a modulator based on the required value of maximum frequency (Fmax) which a modulator is configured to generate.
In accordance with embodiments of the present disclosure, an exemplary method for continuous downlinking communication from a surface location to a bottom hole assembly during drilling operation is provided. The method includes pumping drilling fluid through a surface-located fluid line and through a drill string to the bottom hole assembly. The method includes generating continuous pressure wave signals with a modulator associated with the surface-located fluid line, each signal of the pressure wave signals including at least one letter of a downlinking combinatorial frequencies alphabet. The method includes detecting and receiving at the bottom hole assembly the continuous pressure wave signals generated by the modulator. The method includes processing and decoding the continuous pressure wave signals with a decoder associated with the bottom hole assembly to identify digital signal periodical components, and determine a command type and value, for controlling drilling operations.
The at least one letter of the downlinking combinatorial frequencies alphabet includes one or more orthogonal frequencies. The alphabetic component with a highest frequency Fmax is determined based on evaluation of the modulator. A selection of the modulator is based on a required value of the highest frequency Fmax. The modulator is coupled to the surface-located fluid line. The modulator is attached (directly and/or indirectly) in a compressed manner to at least a portion of the outer circumference of the pipe at an outside/surface location of the pipe to impart hydraulic and/or vibration signals to the outside surface of the pipe to generate the pressure wave signals within the drilling fluid within the pipe. The entire structure for generating the pressure wave signals is therefore disposed outside of the pipe.
An amount of orthogonal frequencies K in the downlinking combinatorial frequencies alphabet can be determined based on a range of frequencies from a minimum frequency Fmin to a maximum frequency Fmax, and on a selected equivalent duration T of output of a single alphabet member of the downlinking combinatorial frequencies alphabet by: K=((Fmax−Fmin)/Δf)+1, where Δf=1/T represents a difference in Hz of adjacent orthogonal frequencies, and T=1,024*2n ms, where n=0, 1, 2 . . . .
The amount of orthogonal frequencies in the combinatorial frequencies alphabet K* is calculated by K*=K−1. An output signal is a combination of one or two alphabet letters, where a second letter of the two alphabet letters is adjacent to a first letter. If an amount of frequencies components for one letter is greater than an amount of all predefined downlinking commands including general purpose and communication group instructions for managing RSS and optimization prescription, then a downlinking command includes from one letter with a structure as {Fsi}, where Fsi is one of the frequencies components form the range from Fmin to Fmax−Δf, each signal frequency component represents a unique combination of one downlinking command purpose and its value. If the amount of predefined downlinking commands is greater than an amount of the frequencies components of one letter of the combinatorial alphabet, a downlinking signal includes from two letters with a structure as {Fsi, Fsi}, where Fsi, Fsi are frequencies components, the combination of downlinking command purpose and its value, and the combination Fsi, Fsi represents one of the downlinking commands.
The method includes adjusting the range of frequencies for attenuation during propagation of the continuous pressure wave signals from the modulator to the bottom hole assembly. An effect of the attenuation is represented by:
where P is a signal strength at a surface transducer, P0 is a signal strength at the modulator, f is a carrier frequency of a measurement-while-logging signal. D is a measured depth between a downhole transducer and the modulator, d is an inside diameter of a drill pipe, μ is a plastic viscosity of the drilling fluid, an K is a bulk modulus of a volume of drilling fluid above the downhole transducer.
Based on an effect of the attenuation on higher frequencies alphabet members, a length of a drilling well is divided by two of more intervals and each interval has a different value of maximum frequency Fmaxi, where i is a number of intervals. The modulator continually generates the maximum frequency Fmax before and after transmitting the continuous pressure wave signals to the bottom hole assembly. A division for the intervals is based on predetermined criteria for a minimum amplitude value for each frequency in order to allow robust recording of the generated continuous pressure wave signals for a pressure transducer. Robust recording necessitates that the amplitude of each frequency at the bottom hole assembly depth is 10-15 time greater than a sensitivity of the pressure transducer.
A choice of the command type and value of a downlinking command is based on a combined evaluation of real-time data from bottom hole assembly sensors, surface gages, drilling parameters, information from an onsite operator, and instruction from a remote center. The method includes encoding the downlinking command and transmitting corresponding one or more alphabet letters to a controller of the modulator to generate a harmonic pressure wave signal. The command type associated with the continuous pressure wave signals is divided into three groups: service commands, RSS commands for managing rotary steering system parameters, and optimization commands for optimization of at least one of acquisition and saving energy resources. If multiple command types are transmitted simultaneously, the method includes prioritizing the service commands as highest priority, the RSS commands as a second highest priority, and the optimization commands as lowest priority.
The method includes detecting a presence of flow of the drilling fluid by a sensor disposed in the bottom hole assembly. The sensor is a flow stat device, and the method includes initiating recording of the continuous pressure wave signals by a pressure transducer after detection of the presence of flow of the drilling fluid by the sensor. A sampling frequency of the sensor is not less than 2*Fmaxi, where Fmaxi is a maximum frequency for an i interval.
The method includes removing a constant zero frequency component, applying band-pass filtering and preforming band selectable Fourier analysis on a sliding base equal to a used duration of the at least one letter of the downlinking combinatorial frequencies alphabet to process the pressure wave signals recorded by the pressure transducer. A processor of the pressure transducer recognizes harmonics, which includes decoding of a downhole signal to determine a command purpose and associated command value. Decoding is based on pattern recognition of a behavior of harmonic components of the continuous pressure wave signals along a timeline after applying Fourier analysis on the sliding base.
The method includes continuously using the maximum frequency Fmaxi to analyze a signal-to-white noise level ratio. A criteria for a robust detection of alphabetic harmonic components of the downlinking signals is established when an amplitude of spectrum of a signal harmonics is higher than three standard deviations of amplitude of white noise (A signal>3*σnoise). An increase of the signal-to-white noise level ratio is achieved by downlinking duration of the at least one letter each time when uplink communication indicates that an amplitude of spectrum for the maximum frequency Fmaxi is not sufficient. If an amplitude spectrum for the maximum frequency Fmaxi is not sufficient, an increase of the signal-to-noise ratio is achieved by increasing the duration of the downlinking command. If the duration of the downlinking signal reaches a predefined limit, the pressure wave signals generated by the modulator are adjusted. When all options are exhausted, and an energy of white noise is 200 times or more than an energy of signal harmonics, the method comprises lifting a drill bit from the bottom hole assembly.
In accordance with embodiments of the present disclosure, an exemplary system for continuous downlinking communication from a surface location to a bottom hole assembly during drilling operation is provided. The system includes a surface-located fluid line, a pump configured to pump drilling fluid through the surface-located fluid line and through a drill string to the bottom hole assembly, and a modulator coupled to the outer surface of the surface-located supply line. The modulator is configured to generate encoded pressure fluctuations in the drilling fluid flowing through the surface-located fluid line by imparting hydraulic and/or vibration signals to the outer surface of the supply line and without having a component inside of the supply line. The system includes a mud pulse telemetry system associated with the bottom hole assembly including at least one sensor for measuring formation properties. The system includes a downhole pressure sensor configured to detect the encoded pressure fluctuations generated by the modulator in the drilling fluid. The system includes a downhole controller and processor configured to process and decode downlinking commands associated with the encoded pressure fluctuations. The system includes a main controller in communication with the bottom hole assembly configured to execute the decoded downlinking commands to control drilling operations.
The modulator is coupled to the outer surface of the surface-located fluid line with one or more jackets capable of being tightly positioned and secured around at least a portion of the circumference of the outer surface of the fluid line. The electrical motor is disposed outside of the surface-located fluid line, the electrical motor having a power unit in the form of a battery or power source. Driving of the modulator with the electrical motor is regulated by a motor controller. A main onsite computer transmits through a data exchange device a sequence of letters of the downlinking combinatorial frequencies alphabet which represents an encoded downlinking command. The modulator generates a pressure wave fluctuation in accordance with the sequence of letters of the downlinking combinatorial frequencies alphabet. The electric motor the signals generated by the modulator based on feedback control signals to maintain the encoded downlinking command. Control of the electrical motor is performed using hall sensors.
The bottom hole assembly includes at least one sensor capable of identified a presence of drilling fluid flow due to pumping of the drilling fluid by a pump through the surface-located fluid line. Detection of starting of pumping and stopping of pumping of the drilling fluid through the surface-located fluid line triggers a start and end, respectively, of recording of pressure fluctuations by a pressure sensor. The pressure sensor includes a processor, software, circuit boards, and a pressure measuring device. A sensitivity of the pressure measuring device is 0.01 psi or 0.001 psi. The pressure sensor is configured to record, filter, process pressure wave fluctuation, and perform amplitude spectrum analysis using a Fast Fourier Transform.
A controller, processor and software are configured to decode the downlinking command by using pattern recognition of signal frequencies based on Fast Fourier Transform results from calculation on a sliding base. The modulator continuously generates the encoded pressure fluctuations with a harmonic signal with a frequency equal to a maximum frequency Fmaxi before and after downlinking commands. A pressure transducer sensor in the bottom hole assembly is configured to calculate a signal-to-white noise level ratio. The pressure transducer sensor is configured to request through an uplink communication an increase of the signal-to-white noise level ratio if the calculated signal-to-white noise level ratio drops below a predefined threshold level.
An initial signal duration of a single combinatorial alphabet letter T is doubled each time when an uplink request is generated until a new calculated time is less than a predefined Tmax1, where Tmax1 is a maximum duration of time allowed for transmission of one letter, or the signal-to-white noise level ratio is increased. When all options are exhausted and an energy of white noise is 200 times or more than an energy of signal harmonics, the drill bit is lifted from the bottom hole assembly and the single combinatorial alphabet letter T is adjusted. A decoded downlinking command type and value is transmitted via internal wires to the main controller of the bottom hole assembly for an execution. A surface sensor real-time information, downhole real-time data, remote center guidance, and onsite operations are processed on the main onsite computer to produce appropriate downlinking instructions to apply the encoded combinatorial alphabet signal schemes at the bottom hole assembly.
In accordance with embodiments of the present disclosure, an exemplary method for downlinking communication from a surface location to a bottom hole assembly during drilling operation is provided. The method includes pumping drilling fluid through a fluid line and through a drill string to the bottom hole assembly, and generating pressure wave signals by a modulator disposed against an outside surface of the fluid line at an outside-surface location of the fluid line. The modulator is disposed entirely outside of the fluid line. The method includes detecting and receiving at the bottom hole assembly the pressure wave signals generated by the modulator, and processing and decoding the pressure wave signals with a decoder associated with the bottom hole assembly to identify downlinking command purpose and required action for controlling drilling operations.
In some embodiments, the modulator can generate the pressure wave signals by applying forces around an entire circumference of the outside surface of the fluid line (e.g., the jacket(s) of the modulator are disposed entirely around a circumference of the fluid line). In some embodiments, the modulator can generate the pressure wave signals by applying forces around a partial circumference of the outside surface of the fluid line. In such embodiments, the modulator (and/or jacket associated with the modulator) is disposed against the partial circumference of the outside surface of the fluid line.
The pressure wave signals generated by the modulator can be periodic wave pressure signals. The pressure wave signals generated by the modulator can include at least one letter of a downlinking combinatorial frequencies alphabet. The at least one letter of the downlinking combinatorial frequencies alphabet can include one or more orthogonal frequencies. An alphabetic component of the downlinking combinatorial frequencies alphabet with a highest frequency Fmax can be determined based on evaluation of the modulator, and a selection of the modulator can be based on a required value of the highest frequency Fmax. The alphabetic component of the downlinking combinatorial frequencies alphabet with a minimum frequency can be determined based on evaluation of the modulator, and an initial amplitude of pressure wave signals at a frequency Fmin is equal to or greater than 10-15 times of a transducer sensitivity for a maximum hole measured depth. In selecting the highest and/or lowest frequency, the system can be configured to avoid pump noise frequencies.
The modulator tightly compresses (or can be tightly compressed to) the outside surface of the fluid line and performs periodic force actions in a direction perpendicular (or substantially perpendicular) to the central longitudinal axis of the fluid line. The modulator includes two jackets tightly compressed against the outside surface of the fluid line due to mutual tightening with fixing bolts, each jacket including a compartment filled with oil. In some embodiments, a single jacket with one or more fixation elements could be used to compress the jacket tightly against the outside surface of the fluid line. As used herein, the term “tight” or “tightly” refers to a positioning of one component adjacent to/against and under pressure against another component. For example, the jacket is positioned against the exterior surface of the fluid line and is compressed against the exterior surface of the fluid line to ensure contact along all or most of the surface area of the jacket against the exterior surface of the fluid line. Such positioning ensures accurate transfer of pressure wave signals from the modulator to the fluid line.
In some embodiments, the method can include operating one or more additional modulators to generate additional pressure wave signals along a central longitudinal axis of the fluid line to increase an amplitude of the pressure wave signals. In such embodiments, the multiple modulators can work in combination to collectively generate the desired pressure wave signals. An amount of orthogonal frequencies K in the downlinking combinatorial frequencies alphabet can be determined based on a range of frequencies from a minimum frequency Fmin to a maximum frequency Fmax, and on a selected equivalent duration T of output of a single alphabet member of the downlinking combinatorial frequencies alphabet by K=((Fmax−Fmin)/Δf)+1, where Δf=1/T represents a difference in Hz of adjacent orthogonal frequencies, and T=1,024*2n ms, where n=0, 1, 2 . . . .
The method can include adjusting the range of frequencies for attenuation during propagation of the pressure wave signals from the modulator to the bottom hole assembly. An effect of the attenuation can be represented by Equation 1:
where P is a signal strength at a surface transducer; P0 is a signal strength at the modulator; f is a carrier frequency of a measurement-while-logging signal; D is a measured depth between a downhole transducer and the modulator; d is an inside diameter of the fluid line; μ is a plastic viscosity of the drilling fluid; and K is a bulk modulus of a volume of drilling fluid above the downhole transducer.
Based on an effect of the attenuation on higher frequencies alphabet members, a length of a drilling well is divided by two of more intervals and each interval has a different value of maximum frequency Fmaxi, where i is a number of intervals. A division for the intervals is based on predetermined criteria for a minimum amplitude value for each frequency in order to allow robust recording of the generated pressure wave signals for a pressure transducer, and robust recording can necessitate that the amplitude of each frequency at the bottom hole assembly depth is 10-15 time greater than a sensitivity of the pressure transducer.
In some embodiments, a choice of a command type and value of a downlinking command can be based on a combined evaluation of real-time data from bottom hole assembly sensors, surface gages, drilling parameters, information from an onsite operator, and instruction from a remote center, and the method can include encoding the downlinking command and transmitting corresponding one or more alphabet letters to a controller of the modulator to generate a harmonic pressure wave signal. In some embodiments, a command type associated with the pressure wave signals can be divided into three groups: service commands, RSS commands for managing rotary steering system parameters, and optimization commands for optimization of at least one of acquisition and saving energy resources. If multiple command types are transmitted simultaneously, the method can include prioritizing the service commands as highest priority, the RSS commands as a second highest priority, and the optimization commands as lowest priority.
The method can include detecting a presence of flow of the drilling fluid by a sensor disposed in the bottom hole assembly. The sensor is a flow stat device, and the method includes initiating recording of the pressure wave signals by a pressure transducer after detection of the presence of flow of the drilling fluid by the sensor. A sampling frequency of the sensor can be not less than 2*Fmaxi, where Fmaxi is a maximum frequency for an i interval. The method can include removing a constant zero frequency component, applying band-pass filtering, and performing band selectable Fourier analysis on a sliding base equal to a used duration of the at least one letter of the downlinking combinatorial frequencies alphabet to process the pressure wave signals recorded by the pressure transducer. A processor of the pressure transducer recognizes harmonics, which includes decoding of a downhole signal to determine a command purpose and associated command value. Decoding is based on pattern recognition of a behavior of harmonic components of the pressure wave signals along a timeline after applying Fourier analysis on the sliding base.
The method can include using a maximum frequency Fmaxi to analyze a signal-to-white noise level ratio. A criteria for a robust detection of alphabetic harmonic components of the downlinking signals can be established when an amplitude of spectrum of a signal harmonics is higher than three standard deviations of amplitude of white noise (Δsignal>3*σnoise). An increase of the signal-to-white noise level ratio can be achieved by downlinking duration of the at least one letter each time when uplink communication indicates that an amplitude of spectrum for the maximum frequency Fmaxi is not sufficient. If an amplitude spectrum for the maximum frequency Fmaxi is not sufficient, an increase of the signal-to-noise ratio can be achieved by increasing the duration of the downlinking command. If the duration of the downlinking signal reaches a predefined limit, and an energy of white noise is 200 times or more than an energy of signal harmonics, the method can include lifting a drill bit from the bottom hole assembly. If all options are exhausted, the method can include to stop pumping.
In accordance with embodiments of the present disclosure, an exemplary system for downlinking communication from a surface location to a bottom hole assembly during drilling operation is provided. The system includes a surface-located fluid line, and a pump configured to pump drilling fluid through the surface-located fluid line and through a drill string to the bottom hole assembly. The system includes a modulator disposed against an outside surface of the surface-located fluid line and capable of generating pressure wave signals in the drilling fluid by applying a harmonical force to the outside surface of the surface-located fluid line in a direction perpendicular to a central longitudinal axis of the surface-located fluid line. The system includes a mud pulse telemetry system associated with the bottom hole assembly including at least one sensor for measuring formation properties, and a downhole pressure sensor configured to detect encoded pressure fluctuations generated by the modulator in the drilling fluid. The system includes a downhole controller and processor configured to process and decode downlinking commands associated with the encoded pressure fluctuations, and a main controller in communication with the bottom hole assembly configured to execute the decoded downlinking commands to control drilling operations.
In some embodiments, the modulator can include two jackets fit tightly against the outside surface of the surface-located fluid line and the two jackets can be tightened to each other with fixing bolts. In some embodiments, a single jacket with fixation elements can be used to secure at least partially around the circumference of the fluid line. An inner surface of the jackets can be a thin steel plate which, with increasing oil pressure in the jackets, fits snugly against the outside surface of the surface-located fluid line. An outer part of the jackets can be a thick steel plate capable of withstanding with a standard margin a maximum oil pressure achieved during operation of modulator. Each jacket can be mechanically and hydraulically connected to a stepped hydraulic cylinder with a hydraulic piston which generates harmonic pressure in oil inside of the jackets. A stepped hydraulic cylinder can be connected by a pressure hose to a hydraulic cylinder of lower pressure with a piston performing reciprocating movements due to a cam mechanism. The cam mechanism can include a flywheel of a profile that ensures movement of the piston in a lower pressure chamber according to a harmonic law. The cam mechanism can be driven by an electric motor which is disposed outside of the surface-located fluid line. The electrical motor includes a power unit in a form of a battery or power source. Driving of the modulator with the electrical motor is regulated by a motor controller.
A main onsite computer can transmit through a data exchange device a sequence of letters of a downlinking combinatorial frequencies alphabet which represents an encoded downlinking command. The modulator can generate a pressure wave fluctuation in accordance with the sequence of letters of the downlinking combinatorial frequencies alphabet. The bottom hole assembly can include at least one sensor capable of identifying a presence of drilling fluid flow due to pumping of the drilling fluid by a pump through the surface-located fluid line. Detection of starting of pumping and stopping of pumping of the drilling fluid through the surface-located fluid line can trigger a start and end, respectively, of recording of pressure fluctuations by a pressure sensor. The pressure sensor includes a processor, software, circuit boards, and a pressure measuring device. A sensitivity of the pressure measuring device can be about 0.01 psi or 0.001 psi. The pressure sensor can be configured to record, filter, process pressure wave fluctuation, and perform amplitude spectrum analysis using a Fast Fourier Transform. A controller, processor and software can be configured to decode the downlinking command by using pattern recognition of signal frequencies based on Fast Fourier Transform results from calculation on a sliding base.
The modulator can generate the encoded pressure fluctuations with a harmonic signal with a frequency equal to a maximum frequency Fmaxi before and after downlinking commands, and a pressure transducer sensor in the bottom hole assembly is configured to calculate a signal-to-white noise level ratio. The pressure transducer sensor can be configured to request through an uplink communication an increase of the signal-to-white noise level ratio if the calculated signal-to-white noise level ratio drops below a predefined threshold level. An initial signal duration of a single combinatorial alphabet letter T can be doubled each time when an uplink request is generated until a new calculated time is less than a predefined Tmax1, where Tmax1 is a maximum duration of time allowed for transmission of one letter. When all options are exhausted and an energy of white noise is 200 times or more than an energy of signal harmonics, a drill bit can be lifted from the bottom hole assembly and the single combinatorial alphabet letter T can be adjusted by varying T. A decoded downlinking command type and value can be transmitted via internal wires to the main controller of the bottom hole assembly for an execution. A surface sensor real-time information, downhole real-time data, remote center guidance, and onsite operations can be processed on the main onsite computer to produce appropriate downlinking instructions to apply the encoded combinatorial alphabet signal schemes at the bottom hole assembly.
Any combination and/or permutation of embodiments is envisioned. Other objects and features will become apparent from the following detailed description considered in conjunction with the accompanying drawings. It is to be understood, however, that the drawings are designed as an illustration only and not as a definition of the limits of the present disclosure.
To assist those of skillful at the art in making and using the method and system for downlinking signal transmission with alphabet frequencies, reference is made to the accompanying figures, wherein:
Drilling operations generally include the circulation of drilling fluid 32 (e.g. drilling mud) by a pump 34 through a mud line 36, into and through a drill string 6 down to the drill bit 8, and back to the surface (e.g., ground level and above) through the annulus 15 between the drill string 6 and the borehole wall 17. The drilling fluid 32 exits the wellbore 2 via a return conduit 39, which routes the drilling fluid 32 back to mud pits 30 through the mud cleaning system (not shown). The modulator 51 generates pressure wave signals in the drilling fluid traveling through the mud line 36 by applying forces to the external surface of the flow line pipe (e.g., the mud line 36). The modulator 51 can apply these pressure wave signals directly to the mud line 36 and/or indirectly (e.g., through an additional structural component connecting the modulator 51 to the external surface of the mud line 36). In some embodiments, the modulator 51 can include one or more brackets or jackets configured to tightly position or compress the modulator against the external surface of the mud line 36. In some embodiments, the brackets or jackets can position the modulator against a portion of the circumference of the mud line 36. In some embodiments, the brackets or jackets can surround the entire circumference of the mudline 36. The transducer 52 measures pressure changes near the modulator 51.
The bottom hole assembly (BHA) 22 at or near distal end 24 of the drill string 6 can include one or more other sensor modules 12. In some embodiments, sensor modules 12 of the BHA can include flow sensor 11, directional sensors, formation evaluation sensors, combinations thereof, or the like. The BHA 22 includes at least one-pressure transducer 13, one or more sources of energy 14 (e.g., batteries or/and generators, and down hole electronics (including controller 16) in communication with the sensors 12 including flow sensor 11, transducer 13 and a pulsar assembly 21. The pressure transducer 13 incorporates the embedded controller that is powerful enough to perform Fast Fourier Transform (FFT) operations in real time, filtering, detecting and decoding downlinking signals.
The pulsar assembly 21 can include a modulator 20, motor control and electronic power board 18. During operation in the uplink mode the pressure fluctuation 50 propagate to the surface through the mudflow in the drill string 6 and are detected at the surface by a transducer(s) 38 which is connected to flow line 36. The analog/digital device 40 transmits a digital form of the pressure signals to a processing 42 (e.g., a computer or some other type of a data processing device). Processing device 42 operates in accordance with software to process and decode the signals received from the analog/digital device 40. The resulting LWD data can be further analyzed and processed to generate a display of various useful information. For example, the system can include a graphical user interface (GUI) capable of displaying data acquired and/or processed by system during the drilling operation. The resulting data also can include information related to a confirmation of the downlink command.
The unit 10 of the BHA 22 in
Selection of a downlinking command to communicate with BHA is a comprehensive process, taking into account the readings of various surface sensors 55, 56, 57 (hook load sensor 56, depth tracking sensor 57, and the like) along with well planning trajectory, 3D geological model, mud log information and others the like data. All the above information can be revived in real time by different experts on site or remotely (54) in order to make a decision for controlling the drilling process and optimize data acquisition. Based on the comprehensive analysis of the above information, the downhole command is selected and then transmitted in real time (or substantially in real time) to the downhole BHA.
Each jacket 95 is mechanically and hydraulically connected to the stepped hydraulic cylinder 81 with hydraulic piston 82, which generates harmonic pressure in oil chamber 80. This pressure is transmitted through the thin inner wall of the jacket 95 to the outer surface of the mud line 36, and then from the outer surface of the mud line 36 to the drilling fluid inside the mud line 36. The modulator 51 thereby transfers the harmonic pressure changes through the jackets 95 to the drilling fluid in the mud line 36.
The stepped hydraulic cylinder 81 is connected by pressure hose 83 to hydraulic cylinder of lower pressure 84 with piston 102. The piston 102 performs reciprocating movements due to the cam mechanism 86 with flywheel of a special profile. The cam mechanism 86 is driven by an electric motor 74. The electric motor 74 is powered by a power source or unit 75. The electric motor 74 is controlled by a control unit 76 (e.g., a controller), which is configured to receive instruction signals for generating a particular downlinking command from computing device 42 of the system through communication device 77. Software of computing device 42 takes into account the initial amplitude of pressure waves generating by the modulator 51 by obtaining pressure measurement signals from transducer 52.
In order to reach the required working pressure p1 in the chamber 80 of the jacket 95, the volumetric change dV1 of the working oil is determined using Equation 2:
where K is a bulk modulus of working oil. The volume V0 of chamber 80 of the jacket 95 is determined using Equation 3:
where S0 is section area and L0 is a length of the chamber 80. The square of the high-pressure piston 87 with diameter d1 is determined using Equation 4:
The stroke of a piston 82 is determined using Equation 5:
The square of the big low-pressure piston 82 is determined using Equation 6:
The diameter d2 of the big low-pressure piston 82 is determined using Equation 7:
The stroke L2 of the piston 82 and stroke L1 of the piston 87 are equal because they are connected. The volume of big low-pressure piston chamber is determined using Equation 8:
and it is equal to the volume V3 of small low-pressure piston chamber 109, which is determined using Equation 9:
The square of the small low-pressure piston 102 is determined using Equation 10:
and its stroke is determined using Equation 11:
Additional stroke of the piston 102 due to compressibility of oil is determined using Equation 12:
On-peak and average power required to move piston 102 is determined using Equations 13 and 14:
Based on the results of numerical simulation (discussed below), the following input parameters for a modulator 51 were chosen as an illustrative example:
It should be understood that the values discussed herein are merely used for example purposes and are not limiting to the disclosure. In particular, different values for the modulator 51 can be used to achieve similar operational results. Based on the above formulas, the following derived values were calculated:
The jackets 95 can be dimensioned to extend along a certain length of the outside surface of the mud line 36 as measured in a direction parallel or substantially parallel to the central longitudinal axis of the mud line 36, such as, e.g., 0.1-1 meters inclusive, 0.1-0.9 meters inclusive, 0.1-0.8 meters inclusive, 0.1-0.7 meters inclusive, 0.1-0.6 meters inclusive, 0.1-0.5 meters inclusive, 0.1-0.4 meters inclusive, 0.1-0.3 meters inclusive, 0.1-0.2 meters inclusive, 0.2-1 meters inclusive, 0.3-1 meters inclusive, 0.4-1 meters inclusive, 0.5-1 meters inclusive, 0.6-1 meters inclusive, 0.7-1 meters inclusive, 0.8-1 meters inclusive, 0.9-1 meters inclusive, 0.2-0.9 meters inclusive, 0.4-0.7 meters inclusive, 0.1 meters, 0.2 meters, 0.3 meters, 0.4 meters, 0.5 meters, 0.6 meters, 0.7 meters, 0.8 meters, 0.9 meters, 1 meter, or the like. In some embodiments, two or more jackets 95 can be used adjacently (and optionally coupled to each other) to extend the overall length along which the jackets 95 are positioned. In such embodiments, the jackets 95 can operate in a corresponding or unitary manner to ensure consistent generation of pressure wave signals.
Referring to
The rotation of the cam 86 inside the casing 107 from the position shown in
Below is additional information describing the operation modes of the modulator 51, including the exemplary requirement for power, number of revolutions and selection of working fluid, based on the structure illustrated in
The initial oil pressure in the chambers of low pressure 117, high pressure 114, the drainage cavity of the stepped cylinder 175 and the drainage cavity of the flywheel housing 176 is the same and equal (or substantially the same and equal) to the pressure in the container—the oil tank. This is achieved by drain channels 113 and 103 in pistons 82 and 102, respectively. Starting the electric motor rotates the cam 86. Due to the curvature of the side profile of the cam 86, the low pressure piston 102 starts moving from bottom dead center (
For the modulator 51, an asynchronous three-phase electric motor with a squirrel-cage rotor, such as AIR 200 M8 18.5 kW 750 rpm, could potentially be used; although alternative motors could be used as well. Rotational speed must be not lower than the maximum required frequency of the generated pressure harmonical waves. The minimum engine power can be calculated using the formula W=2Vpmax Fmax, where V is the volume of the high pressure chamber, pmax is the maximum pressure in the high pressure chamber, and Fmax is the maximum frequency of harmonic signal.
Reducing the rotational speed of the electric motor can be carried out by a frequency converter, which is selected from the condition of matching the power to the selected electric motor. The coupling (not shown) for torque transmission is allowed of any design, selected from the following considerations: a) by torque, equal to the ratio of engine power to the pulsation frequency, and b) must allow misalignments that occur with the selected method of mounting the flywheel and electric motor.
The working fluid (oil) is selected based on the allowable temperature range of its operation, taking into account climatic factors and heating during operation. The viscosity of the oil in the considered temperature range should not exceed 500 cSt, and should not fall below 5 cSt. One example of oils that meet these requirements is SHELL Tellus OilsT-15 and MOBIL DTE 11M, although alternative oils can be used.
Such application of the external force on the pipe can be modeled in Multiphysics engineering software, such as COMSOL (Multiphysics Inc., C., 2020. COMSOL, Available at: http://www.comsol.com/products/multiphysics/), using modules for solid mechanics and pressure acoustics. The software is used to calculate the pressure of a compressible lossless fluid flow using the mass conservation equation (continuity equation), the momentum conservation equation (Euler's equation), and the energy equation (entropy equation). These are given by Equations 15, 16 and 17:
where ρ is the total density, p is the total pressure, u is the velocity field, s is the entropy, and M and F represent possible source terms.
The charts in
Signal generated by the device 51 propagate in the form of harmonic pressure waves inside the drill fluid acoustic channel. In the process of propagation, the amplitude of the downlinking signal decreases tens (or even hundreds) of times. Signal attenuation restricts application of the most of prior art methods. For example, a detection of individual negative pulses is feasible only by using expensive and bulky equipment, and large pulses with amplitude 300-600 psi which negatively affect mud pump operation. The present invention allows for use of pressure wave harmonics with an initial amplitude just 1 psi for 2 Hz and 10 psi for 20 Hz.
The attenuation of the signal increases with the smaller internal pipe diameter, greater compressibility and higher viscosity of drilling fluid, with higher signal frequencies and greater measure depth of the well. Commonly, the effect of the attenuation is calculated by using the following relationship in Equation 18 from Lamb, H., Hydrodynamics, Dover, New York, N.Y. (1945), pages 652-653, which is:
where, P—signal strength at a surface transducer; P0—signal strength at the downhole modulator; f—carrier frequency of the MWD signal; D—measured depth between the surface transducer and the downhole modulator; d—inside diameter of the drill pipe; μ—plastic viscosity of the drilling fluid; and K—bulk modulus of the volume of mud above the modulator.
The maximum frequency Fmax for downhole communication must provide sufficient amplitude of the signal for a robust detection for at least a half of the well length. At the same time Fmax must not exceed Fgen.max provided by the modulator 51. For the wells with significant length of measured depth it might be necessary to divide well trajectory (as shown by the example illustrated in
For example,
If signal transmission time is 1.0 see (1024 ms if using FFT—it will be simpler because FFT calculations require a number of points equal to a power of 2), the amount of orthogonal harmonic is equal 19 (19*2°), if transmission time will be increased by factor of 2, then amount of orthogonal harmonic doubled 38 (19*21) and distance between adjacent harmonics Δf will be equal 0.5 Hz. Each time the length of the signal transmission is doubled the amount of orthogonal harmonic is also doubled and distance between nearest-neighbor frequencies reduced by half. For example, if Δf=0.125 Hz, the total amount of orthogonal harmonic is equal 152 (19*23). Such amount of combinations is greater than a typical amount of instructions (including their value) used traditionally for downlinking in the industry.
The value of Δf minimum depends on the modulator 51 producing a single frequency with a particular accuracy. The value Δfmin can be determined by predrilling test of the generator accuracy by using data from pressure transducer 52.
The vast majority of modern well trajectory control system in the oil and gas industry, which include equipment for MWD/LWD measuring and RSS, are used to transmit a limited amount of different downlinking commands (typically less than 50-100 different commands). In such cases, for their transmission would be enough to use no more than 128 combinations or 6 bits. It is achievable, for example, to use a frequencies range of 16 Hz with duration of downlinking command equal 8 seconds and Δf=0.125 Hz. In such case, it is possible to use just only single letter of the combinatorial frequency alphabet. If a 2 letter scheme is used for 16 seconds 14 bits information is sent. The above examples demonstrate the speed of sending downlinking commands in the present invention, which is in order of about 1 bit per second as compared with traditional practice which is about 1 bit per minute.
A list of required downlinking commands depends on the tools included in BHA, presence of rotary steerable system and objectives of control and optimization of drilling process and data acquisition and transmission. Typically, as shown in
Measurements while drilling process implies making a certain number of measurements (points) per meter according to the specified requirements. For example, requirements may demand not less than 5 points per meter (1 point per 20 cm) of certain parameter measured and transmitted in real-time from the bottom hole to the surface. The telemetry system must provide the required density of measurements regardless of changing drilling conditions, for example, high or low rate of penetration.
In the present invention all downlinking commands can be divided into three groups:
A pressure sensor 13 continuously recording pressure measurements (584) in the presence of flow drilling mud with sampling frequency not less than fs=2*Fmax in accordance with Nyquist-Shannon sampling theorem, where Fmax is a maximum frequency in range used for downhole data transmission. The sensitivity of the pressure sensor determines a minimum detectable amplitude of harmonic, and it must be taken into account for estimation of the amplitude of decaying downlink signal. In the example which is used above to illustrate novelty of the present invention, the sensitivity of pressure sensor was assumed as 0.01 psi and minimum detectable downhole amplitude level as 0.1 psi. A controller of the pressure sensor appends new pressure readings into a memory buffer for further processing. It allows to accumulate a sequence of pressure values during time span t>Tmax (where Tmax is a maximum signal duration) that is sufficient for analysis.
Pressure readings in the buffer are being constantly monitored for a presence or absence of signal. The processing starts with applying FFT to the selected fragment of signal. Removing zero-frequency component and performing band-pass filter allow to remain only working range of frequency components between Fmin and Fmax. The presence of a certain frequency is determined by estimation of the corresponding FFT component. A particular firmware module of pressure sensor controller hereafter referred to as “decoder” performs FFT for the window sliding along the time axis with step Δt=1 second.
The decoder determines the decoded command (586), estimates decoding quality (587), and if criteria of a robust decoding is not satisfied then BHA starts the emergency uplink procedure (591) to inform surface about potential of incorrect decoding of downlinking command. In such case the uplink includes information on decoded command. If downlinking command was decoded incorrectly, the original command is downlinking again by using options to increase signal to noise ratio.
The following example illustrates the concept of signal detection. In the example, signal frequency is fs=20 Hz, duration of the signal is T=8 seconds, and it is presumed that amplitudes of fs meet the criteria Asignal>3σnoise.
The present invention method includes options designed to increase the ratio of signal-to-noise.
The method and apparatus of the present invention overcome the disadvantages of the prior art by providing the opportunity to generate pressure waves in the flow supply line by applying forces to the outside surface of the pipe without any restrictions of the mud flow (e.g., without any structures associated with the modulator being disposed inside of the pipe itself, and only positioned against the outer surface of the pipe). The modulator generates low amplitude harmonical pressure waves in the range of 0.1-10 psi and causes no interference with surface pumping equipment. A modulator 51 transmits commands and data to a downhole pressure transducer 13 disposed in BHA, as previously described with reference to
Pressure transducer may have a sensitivity 0.01 psi or in some situation with deep wells even 0.001 psi. Analysis of pressure wave attenuation 642 in
The present invention method allows for broadening of the range of downlinking commands and uses more bits to represent the command values. The method includes at least three group of commands: service/supporting commands; commands for managing RSS parameters; and commands to optimize data acquisition densities/parameters including instruction on saving energy sources. The final step of preparation to the downlinking during LWD operation includes an initialization stage.
After the drilling operation starts, pumps is on, at the BHA level, pressure transducer initiated by “flow stat” sensor, starts recording, processing and performs FFT on sliding base resulting calculation of signal to white noise ratio. If the ratio falls down below the threshold, the uplink command is initiated requesting a need to increase said ratio.
Thus, prior to generate a downlinking command, the system has information on downlinking command duration T, sufficient for robust detection and decoding of a downlinking command. A process of generating an immediate downlinking command includes receiving data from downhole sensors, surface located devices (block 654, 653 in
While exemplary embodiments have been described herein, it is expressly noted that these embodiments should not be construed as limiting, but rather that additions and modifications to what is expressly described herein also are included within the scope of the invention. Moreover, it is to be understood that the features of the various embodiments described herein are not mutually exclusive and can exist in various combinations and permutations, even if such combinations or permutations are not made express herein, without departing from the spirit and scope of the invention.
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Number | Date | Country | |
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20240240555 A1 | Jul 2024 | US |