method for directing a drill bit to form a well hole in a subsurface formation

专利摘要:
METHODS FOR DIRECTING A DRILL DRILL TO FORM A HOLE HAVING A SLOPE AND AN AZIMUTE IN A SUBSURFACE FORMATION USING A PLANNED WELL PATH AND AT LEAST FIRST AND SECOND SURVEYS The invention relates to a method for directing a drill bit to form a hole having a slope and azimuth in a subsurface formation using a planned well path and at least first and second surveys, comprising the steps of: a) determining a distance from the design of a well, where the design distance is the difference between the drill position in the second survey and the planned well path; and, b) determine an angle offset from the design of the well, where the angle offset from the design is the difference between the slope and azimuth of the planned well path; c) where at least one distance from the design and at least one angle offset from the design are determined in real time based at least in part on a portion of the hole in the first survey, at a position at a location chain projected from the drill, and in a position (...).
公开号:BR112012025973B1
申请号:R112012025973-3
申请日:2011-04-11
公开日:2021-04-20
发明作者:David Alston Edbury；Jose Victor Guerrero；Duncan Charles Macdonald；Jason B. Norman；James Bryon Rogers；Donald Ray Sitton
申请人:Shell Internationale Research Maatschappij B.V；
IPC主号:

专利说明:

FIELD OF THE INVENTION
[001] The present invention relates generally to methods and systems for drilling in various subsurface formations such as hydrocarbon-containing formations. DESCRIPTION OF RELATED TECHNIQUE
[002] Hydrocarbons obtained from underground formations are generally used as energy resources, as feed loads, and as consumables. Concerns about depletion of available hydrocarbon sources and concerns about declining global quality of produced hydrocarbons have led to the development of processes for recovery, processing and/or more efficient use of available hydrocarbon sources.
[003] In drilling operations, drilling personnel are commonly assigned various control and monitoring roles. For example, drilling personnel can control or monitor drilling rig positions (such as a rotary drive or transport drive), collect drilling fluid samples, and monitor agitators. As another example, drilling personnel adjust the drilling system (“maneuver” a drill string) on a case-by-case basis to adjust or correct the drill rate, trajectory, or stability. A driller can control drilling parameters using sticks, manual switches, or other manually operated devices, and monitor drilling conditions using gauges, gauges, dials, fluid samples, or audible alarms. The need for manual control and monitoring can increase the costs of drilling a formation. Additionally, some of the operations performed by the driller may be based on subtle signals from the drilling apparatus (such as unexpected vibration from a drill string). Because different drilling personnel have different experience, knowledge, skills, and instincts, drilling performance that depends on such manual procedures may not be reproducible from formation to formation or from equipment to equipment. Additionally, some drilling operations (whether manual or automatic) may require a drill bit to be stopped or pulled from the bottom of the well, for example when changing from a rotary drilling mode to a slip drilling mode. Suspension of drilling during such operations can reduce the overall rate of drilling progress and efficiency.
[004] Downhole sets in drilling systems generally include instrumentation such as Drill During Measurement (MWD) tools, data from downhole instrumentation can be used to monitor and control drilling operations. Providing, operating and maintaining such downhole measurement tools can substantially increase the cost of a drilling system. Additionally, as downhole instrumentation data must be transmitted to the surface (such as by mud pulse or periodic electromagnetic transmissions), downhole instrumentation can only provide limited "instant copies" at periodic intervals during the drilling. For example, a punch may have to wait 20 or more seconds between updates from an MWD tool. During gaps between updates, downhole instrumentation information can become outdated and lose its value for drilling control. SUMMARY
[005] Modalities described here generally refer to systems and methods for automatically drilling in underground formations.
[006] A method of evaluating, for a particular mud engine, a relationship between engine output torque and differential pressure across the mud engine includes applying torque to a drill string on the surface of the formation to rotate the drill string forming at a specified drill string RPM; pump drilling fluid at a specified flow rate to the mud engine; operate the mud motor at a specified differential pressure to turn the drill bit to drill in the formation; reduce the torque applied to the drill string to reduce the drill string rotational speed to a target drill string speed while continuing to operate the mud motor at the specified differential pressure; measure the drill string torque at the formation surface that is required to keep the drill string at the target drill string speed while the mud motor is at the specified differential pressure (and the drill bit then continues to drill); and model a relationship between the torque on the drill bit and the differential pressure by the mud motor based on the measured clamping torque and the specified differential pressure.
[007] A method of evaluating the weight on a drill bit used to form an opening in a subsurface formation includes evaluating a relationship between a weight on a drill bit and a differential pressure by the mud motor based on at least one weight. analytical model; measure a differential pressure by the mud engine; evaluating a relationship between torque in a drill bit used to form the opening and the differential pressure by a motor used to operate the drill bit using at least one measurement of torque in a drill string on the surface of the formation; evaluate the weight on a drill bit using the analytical model, the evaluated relationship between torque on the drill bit and the differential pressure by the motor, and the evaluated relationship between that on the drill bit and torque on the drill bit.
[008] A method of evaluating the weight in a drill bit used to form an opening in a subsurface formation, includes measuring at least one pressure to determine a differential pressure by the mud engine; determine a motor output torque based on the measured differential pressure; measure torque on a drill string; measure a rotating torque from outside the bottom; and determine a weight on the drill necessary to induce weight in the drill-induced lateral load torque in at least one of the measurements.
[009] A method of evaluating a pressure in a system used to form an opening in a subsurface formation, comprising: evaluating a basal pressure when a drill bit is freely rotating in the opening in the formation; assess a basal viscosity of a fluid flowing through the drill bit based on basal pressure; assess the flow; density, and the viscosity of the fluid flowing through the drill bit while the drill bit is used to drill the opening further into the borehole; and reassess the basal pressure based on the assessed flow rate, density and viscosity of the fluid flowing through the drill bit.
[0010] A method of automatically positioning a drill bit used to form an opening in a subsurface formation on a bottom of the opening being formed includes increasing the flow rate in a drill string to a target flow; controlling the flow of fluid into the drill string to be substantially the same as the flow of fluid out of the opening; allowing a fluid pressure to reach a relatively steady state; automatically move the drill bit toward the bottom of the opening at a selected rate of feed until a consistent increase in measured differential pressure indicates that the drill bit is at the bottom of the opening.
[0011] A method of automatically picking up a drill bit out of the bottom of an opening in a subsurface formation includes setting a predetermined level of differential pressure by the motor at which pickup of the drill bit is initiated; monitor the differential pressure across the engine; allow differential pressure by an engine to decrease to the predetermined level; and when the predetermined level is reached, automatically pick up the drill bit.
[0012] A method of automatically detecting a loss in a mud engine that provides rotation to a drill bit used to form an opening in a subsurface formation and responding to the loss includes designating a maximum allowable differential pressure in a mud engine used to operate the drill bit; assess a slurry engine stall condition when the rated differential pressure is at or above the designated maximum differential pressure; and automatically shuts off flow to a slurry engine when the leak condition is assessed.
[0013] A method of evaluating drilling hole cleanup efficiency includes determining a mass of cutouts removed from a well, wherein determining the mass of cutouts removed from a well includes measuring a total mass of fluid entering a well ; measure the total mass of fluid leaving a well; determine a difference between the total mass of fluid leaving the well and the total mass of fluid entering the well; determine a mass of rock excavated from the pit; determining a mass of cutouts remaining in the well, where determining the mass of cutouts remaining in the well includes determining a difference between the determined mass of rock excavated in the well and the determined mass of cutouts removed from the well.
[0014] A method of monitoring the performance of a solids handling system includes monitoring the mass density and flow rate leaving a well; monitor the density and mass flow of fluid returning to the well; and comparing the density of fluid leaving the well with the density with the density of fluid returning to the well.
[0015] A method for controlling a direction of a tool face of a hole set below for slide drilling includes synchronizing the tool face, wherein synchronizing the tool face includes determining a relationship between the rotational position of the tool face downhole having a rotational position on the surface of the formation for at least one point in time; stop the rotation of the drill string attached to the hole set below; control torque on the surface of the drill string to control a rotational position of the tool face; and start sliding drilling.
[0016] A method of controlling a drilling direction of a drill bit used to form an opening in a subsurface formation includes varying a speed of the drill bit during rotary drilling such that the drill bit is at a first speed during a first portion of the rotational cycle and at a second speed during a second portion of the rotational cycle, where the first speed is greater than the second speed, and where operating at the second speed in the second portion of the rotational cycle causes the drill to perforation change the direction of the perforation.
[0017] A method of predicting a drilling direction of a drill bit used to form an opening in a subsurface formation includes evaluating the depth of the drill bit at one or more selected points along the opening; estimate the postures at the start and end points of at least one slip-perforated section; and evaluating virtual measurement depths by projecting back relative to one or more previously measured depths.
[0018] A method for evaluating a vertical depth of a wellbore, drilling tool operating within a wellbore or a drill bit used to form an opening in a subsurface formation includes evaluating a static borehole pressure at a known and fixed location with respect to the wellbore, drilling tool or drill bit; assess the density of fluid flowing into the wellbore; and evaluating a vertical depth of the drill bit based on the assessed drillhole pressure and the assessed density.
[0019] A method for directing a drill bit to form an opening in a subsurface formation includes taking at least one survey taken with an MWD tool; establish a definitive MWD sensor path with the survey data from the MWD tool; and project drill bit posture and position using real-time data in combination with the path from the MWD tool.
[0020] A method for directing a drill bit to form an opening in a subsurface formation includes determining a distance from the design of a well; determine an angle offset from the design of the well, where the angle offset from the design is the difference between the slope and azimuth of the hole and the plane, where at least one distance from the design and at least one angle offset from design are determined in real-time based on a portion of the hole in the last survey, a position at a current projected drill location, and a projected drill position.
[0021] A method for estimating the tool face of a downhole set between drillhole updates during drilling in a subsurface formation includes coding a drill string; run the drill string in the formation in a calibration mode to model the completion of the drill string in the formation; during drilling operations, measuring a rotational position of the drill string on the formation surface; and estimate the tool face of the drill string below based on the rotational position of the drill string on the surface and the drill string completion model.
[0022] In various embodiments, a system includes a processor and memory coupled to the processor and configured to store program instructions executable by the processor to implement automatic puncturing, such as using the methods described above.
[0023] In various embodiments, a computer-readable memory medium includes computer-executable program instructions to implement automatic punching, such as using the methods described above. BRIEF DESCRIPTION OF THE DRAWINGS
[0024] Advantages of the present invention may be apparent to those skilled in the art with the benefit of the following detailed description and with reference to the accompanying drawings in which:
[0025] FIG. 1 and 1A illustrate a schematic diagram of a drilling system with a control system for performing drilling operations in accordance with an embodiment;
[0026] FIG. 1B illustrates a bore assembly embodiment below including a curved connection;
[0027] FIG. 2 is a schematic illustration of an embodiment of a control system;
[0028] FIG. 3 illustrates a flowchart for a method for evaluating a relationship between engine output torque and slurry engine differential pressure according to an embodiment;
[0029] FIG. 4 illustrates a mode of torque measured in a drill string on the surface of a formation against time during a test to determine a torque/differential pressure ratio in a transition from a rotary drill to a slip drill;
[0030] FIG. 5 is a plot of slurry engine output torque against differential pressure by the slurry engine according to an embodiment;
[0031] FIG. 6 illustrates a flowchart for a method for assessing weight on a drill bit using differential pressure according to an embodiment;
[0032] FIG. 7 illustrates an example of a relationship established using multiple test points;
[0033] FIG. 8 illustrates a flowchart for a method for evaluating a weight ratio in the drill that includes a weight determination in drill-induced lateral load torque measurements of surface torque and differential pressure;
[0034] FIG. 8A illustrates a rotary drilling graph showing measured and calculated torques at each time;
[0035] FIG. 9 illustrates a relationship between differential pressure and viscosity in a pipeline;
[0036] FIG. 10 illustrates a flowchart for a method for detecting a loss in a slurry engine and recovering from the method according to an embodiment;
[0037] FIG. 11 illustrates a flowchart for a method for determining hole cleaning efficiency;
[0038] FIG. 12 illustrates surface tool synchronization using measurement data during drilling according to an embodiment;
[0039] FIG. 13 illustrates a flowchart for a method of transitioning a drilling system from rotary drilling to slide drilling;
[0040] FIG. 14 is a time plot illustrating adjustment in a transition from rotary drilling to slip drilling with surface adjustments at intervals;
[0041] FIG. 15 illustrates a flowchart for a method of a transition from rotary drilling to slip drilling including transport motion according to an embodiment;
[0042] FIG. 16 illustrates a flowchart for a method of a drilling mode in which the rotation speed of the drill string is varied during the rotation cycle;
[0043] FIG. 17 illustrates a diagram of a multi-speed rotation cycle according to an embodiment;
[0044] FIG. 18 illustrates a drill string in a drillhole for which a virtual continuous survey can be evaluated;
[0045] FIG. 18A is a diagram illustrating an example of slip drilling between MWD surveys.
[0046] FIG. 18B is a tabulation of the original survey points for an example of drilling in rotary drilling and slip drilling modes;
[0047] FIG. 18C is a tabulation of survey points including added virtual survey points.
[0048] FIG. 19 illustrates an example of pressure recording during addition of a side seam according to an embodiment;
[0049] FIG. 20 illustrates an example of full vertical depth density results;
[0050] FIG. 21 illustrates is a graphical representation illustrating a method for carrying out a design to drill;
[0051] FIG. 22 is a diagram illustrating an embodiment of a plan for a hole and a portion of the hole that has been drilled based on the plan;
[0052] FIG. 23 illustrates one embodiment of a method for generating direction commands;
[0053] FIG. 24 illustrates one mode of a user input screen for entering the adjustment of setpoints. DETAILED DESCRIPTION
[0054] The following description generally refers to systems and methods for drilling in formations. Such formations can be treated to produce hydrocarbon, hydrogen, and other products.
[0055] "Continuously" or "continuously" in the context of signals (such as magnetic, electromagnetic, voltage, or other magnetic or electrical signals) include continuous signals and signals that are pulsed repeatedly for a selected period of time. Continuous signals can be sent or received at regular intervals or at irregular intervals.
[0056] A "fluid" can be, but is not limited to, a gas, a liquid, an emulsion, a slurry, and/or a stream of solid particles that has flow characteristics similar to a liquid flow.
[0057] “Fluid pressure” is a pressure generated by a fluid in a formation. "Lithostatic pressure" (sometimes referred to as "lithostatic stress") is a pressure in a formation equal to one weight per unit area of an overlapping rock mass. “Hydrostatic pressure” is a pressure in a formation exerted by a column of fluid.
[0058] A "formation" includes one or more layers containing hydrocarbons, one or more layers of non-hydrocarbons, an overlying formation and/or an underlying formation. Hydrocarbon layers can contain non-hydrocarbon material and hydrocarbon material. The "overlying formation" and/or the "underlying formation" includes one or more different types of impermeable materials. For example, the overlying formation and/or the underlying formation may include rock, shale, clay, or wet/hard carbonate.
[0059] "Formation fluids" refer to fluids present in a formation and may include pyrolysis fluid, synthesis gas, mobilized hydrocarbons, and water (vapor). Formation fluids can include hydrocarbon fluids as well as non-hydrocarbon fluids. The term "mobilized fluid" refers to fluids in a hydrocarbon-containing formation that are able to flow as a result of heat treatment of the formation. “Produced fluids” refers to fluids removed from the formation.
[0060] "Thickness" of a ply refers to the thickness of a ply cross section, where the cross section is normal to a ply face.
[0061] “Viscosity” refers to kinematic viscosity at 40 °C unless otherwise specified. Viscosity is as determined by ASTM Method D445.
[0062] The term “wellbore” refers to a hole in a formation made by drilling or inserting a conduit into the formation. A wellbore may have a substantially circular cross-section, or another form of cross-section. As used herein, the terms "well" and "opening" when referring to an opening in the formation can be used interchangeably with the term "wellbore".
[0063] In some modalities, part of or all drilling operations in a formation are performed automatically. A control system can, in certain modalities, perform monitoring functions usually assigned to a drill through direct measurements and corresponding model. In certain embodiments, a control system can be programmed to include control signals that emulate control signals from a punch (eg, control inputs from sticks and manual switches). In some modes, trajectory control is provided by unmanned survey systems and integrated steering logic.
[0064] FIG. 1 illustrates a drilling system with a control system for performing drilling operations automatically according to a modality. Drilling system 100 is provided in formation 102. Drilling system 100 includes drill rig 104, pump 108, drill string 110, downhole assembly 112, and control system 114. Drill string 110 is made of a series of drill pipe 116 that are sequentially added to drill string 110 as well 117 is drilled in formation 102.
[0065] Drilling rig 104 includes transport 118, rotary drive system 120, and pipe handling system 122. Drilling rig 104 is operable to drill well 117 and to advance drill string 110 and assembly of drills. down hole 112 in formation 104. Annular openings 126 may be formed between the outside of drill string 110 and the sides of well 117. Lining 124 may be provided in well 117. Lining 124 may be provided over the entire length of well 117 or over a portion of well 117, as depicted in FIG. 1.
[0066] The hole assembly below 112 includes a drill collar 130, mud motor 132, drill bit 134, and measurement while drilling (MWD) tool 136. Drill bit 134 can be driven by the mud motor 132. The mud engine 132 can be powered by a drilling fluid that passes through the mud engine. The speed of drill bit 134 can be approximated proportionally to the differential pressure across the slurry engine 132. As used herein, "differential pressure across the slurry engine" can refer to the difference in pressure between fluid flowing into the slurry engine and fluid flowing out of the mud engine. Drilling fluid may be referred to here as “mud”.
[0067] In some embodiments, the drill bit 134 and/or the mud motor 132 are mounted in a curved connection of the hole set below 112. The curved connection can slide the drill bit at an angle (off axis) with regarding the posture of the downhole assembly 112 and/or the end of the drill string 110. A curved connection can be used, for example, for directional drilling of a well. FIG. 1B illustrates a bore assembly embodiment below including a curved connection. The curved connection 133 can establish a drilling direction that is angled with respect to the axial direction of the hole assembly below and/or the wellbore.
[0068] The MWD tool 136 can include various sensors to measure features in drill system 100, well 117, and/or formation 102. Examples of features that can be measured by the MWD tool include natural range, posture (slope and azimuth ), tool face, borehole pressure, and temperature. The MWD tool can transmit data to the surface via mud pulse, electromagnetic telemetry, or any other form of data transmission (such as wired or acoustic drill pipe). In some embodiments, an MWD tool may be spaced from the hole assembly below and/or from the mud engine.
[0069] In some embodiments, the pump 108 circulates the drilling fluid through the mud distribution line 137, the core passage 138 of the drill string 110, through the mud motor 132, and back to the formation surface through the annular opening 126 between the exterior of the drill string 110 and the side walls of the well 117, as illustrated in FIG. 1A. Pump 108 includes pressure sensors 150, suction flow meter 152, and return flow meter 154. Pressure sensors 150 can be used to measure fluid pressure in drilling systems 100. In one embodiment, one of the sensors pressure 150 measures the vertical pipe pressure. Flow meters 152 and 154 can measure the mass of fluid flowing into and out of drill string 110.
[0070] A control system for a drilling system may include a computer system. In general, the term “computer system” can refer to any device having a processor that executes instructions from a memory medium. As used herein, a computer system can include a processor, a server, a microcontroller, a microcomputer, a programmable logic controller (PLC), an application-specific integrated circuit, and other programmable circuits, and these terms are used interchangeably herein.
[0071] A computer system typically includes components such as CPU with an associated memory medium. The memory medium can store program instructions for computer programs. Program instructions can be executed by the CPU. A computer system can additionally include a display device such as a monitor, an alphanumeric input device such as a keyboard, and a directional input device such as a mouse or joystick.
[0072] A computer system may include a memory medium in which computer programs according to various embodiments may be stored. The term "memory medium" is intended to include an installation medium, CD-ROM, computer system memory such as DRAM, SRAM, EDO RAM, Rambus RAM, etc., or non-volatile memory such as media magnetic, for example, a hard disk or optical storage. The memory medium can also include other types of memory or combinations thereof. Additionally, the memory medium may be located on a first computer, which runs the programs, or it may be located on a different second computer, which connects to the first computer over a network. In the latter case, the second computer can provide the program instructions to the first computer for execution. A computer system can take various forms such as a personal computer system, mainframe computer system, workstation, network application, Internet application, personal digital assistant (“PDA”), television system or other device.
[0073] The memory medium may store a software program or programs operable to implement a method for processing insurance claims. The software program(s) may be implemented in a variety of ways, including, but not limited to, procedure-based techniques, component-based techniques, and/or object-oriented techniques, among others. For example, software programs can be implemented using Java, ActiveX controls, C++ objects, Javabeans, Microsoft Foundation Classes (“MFC”), browser-based applications (eg, Java applets), traditional programs, or other technologies or methodologies, as desired. A CPU such as a host CPU that executes code and data from the memory means may include means for creating and executing the software program or programs in accordance with the embodiments described herein.
[0074] FIG. 2 is a schematic illustration of one modality of a control system. Control system 114 can implement control of various devices, receive sensor data, and perform computations. In one modality, a programmable logic controller (“PLC”) of a control system implements the following subroutines: Start; Lower drill to the bottom; Start drilling; Monitor drilling; Start sliding from rotary drilling; Maintain tool face and slip drilling; Initiate slip drilling from the slip; Stop drilling; Raise column to final position.
[0075] Each subroutine can be controlled based on user defined setpoints and the output of various software routines. Once each drill pipe joint is made, control can be delivered to a PLC of the control system.
[0076] Drilling operations may include rotary drilling, slip drilling, and combinations thereof. In general, rotary drilling can follow a relatively straight path and slip drilling can follow a relatively curved path. In some modalities, rotary drilling and slip drilling modes are used in combination to achieve a specified trajectory.
[0077] Various parameters that can be monitored include mud engine loss detection and recovery, surface thrust limit, mud inflow/outflow balance, and torque stability. A PLC can automatically implement out-of-range condition responses for any of all these parameters.
[0078] In certain embodiments, an opening in a formation is made using rotary drilling only (no slip drilling). Drilling parameters are controlled to adjust slope. In certain modalities, the drop is achieved by a combination of decreased RPM and decreased flow with increased penetration rate.
[0079] In certain embodiments, a drilling system includes an integrated automated tube handle. The integrated automated tube handle can allow the drilling system to drill through entire sections automatically. Services such as drilling fluid, fuel, and waste removal can be maintained.
[0080] A PLC can automatically control one or more of the parameters.
[0081] In some embodiments, a control system provides a package of engineering calculations needed to drill a well. Engineering modules can be provided, for example, for lifting, well planning, directional drilling, torque and drag, and hydraulics. In one embodiment, calculations are performed against real-time data received from drilling rig sensors, mud rig sensors and MWD and reporting to the control system via a database (such as a database of SQL server). Calculation results can be used to monitor and control drilling equipment while drilling is being performed.
[0082] In some embodiments, a control system includes a graphical user interface. The graphical user interface can display, and allow input for, various drilling parameters. The graphical user interface screen can constantly update while the program is running and receiving data. The display can include such information as: - the current depth, pressure and torque of the wellbore and drill string, and a BHA performance analysis that provides the directional performance summary of the slip and rotary drilling ranges; - a summary of the position of the last survey position, current end of the hole, the point on the well plane that represents the closest point from the end of the hole, and finally the position of a projected distance from the well plane. These can all be represented as a survey position illustrating depth, slope, azimuth and actual vertical depth at each position; - the distance and direction between the hole end and the hole plane, and the current drilling state and directional adjustment results.
[0083] In some drilling operations, tests are performed to calibrate instruments and to determine relationships between various parameters and characteristics. For example, at the beginning of a drilling operation, a drill test can be run to determine flow against pressure and so on. Conditions during calibration tests may not, however, reflect conditions currently encountered during drilling. As a result, data from some commonly used calibration tests may be inadequate to effectively control drilling. In addition, some existing calibration tests do not provide enough accurate information to optimize performance (such as an optical penetration rate or directional control), or to deal with adverse conditions that can arise during drilling, such as mud engine loss. .
[0084] In some embodiments, a relationship is evaluated, for a particular slurry engine, between engine output torque and differential pressure across the slurry engine. The rated ratio can be used to control drilling operations using the mud engine. FIG. 3 illustrates the evaluation of a relationship between engine output torque and slurry engine differential pressure according to a modality. At 160, torque is applied to a drill string on the formation surface to rotate the drill string in the formation at a specified drill string RPM. In some embodiments, the drill string can be specifically rotated to perform a calibration test to evaluate a relationship between engine output torque and differential pressure as described in this FIG. 3. In other embodiments, the drill string may already be rotating as part of the rotary drilling of a portion of the formation by the time calibration is started.
[0085] At 162, drilling fluid is pumped to the mud motor at a specified rate to rotate the drill bit for drilling in the formation. In 164, the mud motor is operated at a specified differential pressure (which can be proportional to the flow of drilling fluid) to turn the drill bit to drill in the formation.
[0086] At 166, the torque applied to the drill string is reduced to reduce the rotational speed of the drill string to zero while continuing to operate the mud motor at the specified differential pressure. The reduction in torque can be achieved by reducing the speed of a rotary drive of the drilling system.
[0087] At 168, a clamping torque on the drill string on the surface of the formation is measured. The clamping torque can be the torque required to keep the drill string at zero drill string speed while the mud motor is at the specified differential pressure (and the drill bit then continues to drill).
[0088] In 170, a relationship is modeled between torque in the drill bit and differential pressure by the mud motor based on the measured clamping torque and the specified differential pressure. In certain embodiments, the torque on the drill bit is assumed to be the value indicated by the mud engine pressure differential.
[0089] FIG. 4 illustrates a torque modality measured in a drill string on the surface of a weathered formation during a test to determine a torque/differential pressure ratio in a transition from rotary drilling to slip drilling. Curve 176 plots torque on the drill string against time. Initially, a rotary drive may be turning a drill string such that the torque measured on the formation surface is at a relatively stable level (about 5500 ft.lbs (760.4 m.kg) in this example). At time 178, the rotation is decelerated. As the drill string is slowed down, torque in the drill string decreases. At 180, torque can reach a relatively stable value (about 650 ft.lbs (89.86 m.kg) in this example). The surface torque will reduce to a torque equal to the mud motor torque output. So, the stable torque reading of the surface torque at 180 can approximate the torque in the mud engine.
[0090] The relationship between torque in the drill bit and differential pressure by the mud motor can have a linear relationship. FIG. 5 is a plot of engine slurry against differential pressure by engine according to an embodiment. Curve 182 illustrates the relationship between drill bit torque and differential pressure in this example. In some embodiments, a linear relationship is established using two points: the first point being [Torque = clamping torque at specified differential pressure, Differential pressure = Specified differential pressure] and the second point being at [Torque = 0; Differential pressure = 0]. Since the [Torque = 0; Differential pressure = 0] can be assumed without running a test, the linear relationship can then be determined with just one test point, namely, [Torque = clamping torque at specified differential pressure, Differential pressure = specified differential pressure].
[0091] For comparison, FIG. 5 includes engine specification curve 184. Engine specification curve 184 represents what a manufacturer's engine specification curve might typically look like for a slurry engine tested to produce curve 182.
[0092] In some arrangements, a drill string is allowed to unwind before measuring the clamping torque. Referring to FIG. 4, curve 186 illustrates sliding a hole assembly down as the drill string unrolls. The plot shows the relationship between torque and BHA face tool roll when the column RPM on the surface is zero. With the drill in the bottom drilling, while the drill pipe RPM is set to zero, the torque trapped in the column rotates the BHA to the right until the torque in the column on the surface is balanced with the reactive torque of the motor trying to turn the BHA in the opposite direction. So, at 188, while rotation of the rotary is stopped, the drill string is in a 0 degree right roll. As time passes, the drill string unwinds until the drill string reaches a stable level at 190 (about 750 degrees, 2.1 turns, in this example). The surface torque measurement when the BHA roll stabilizes can be a direct measurement of engine torque output. Unwinding can take, in one example, about 2.5 minutes.
[0093] In some embodiments, a test to evaluate a relationship between torque in the drill bit and differential pressure by the mud engine is periodically repeated. The test can be used, for example, to check engine performance while drilling progresses in a formation. Additionally, the test can be performed any time that slip drilling occurs and the surface torque has stabilized.
[0094] The differential pressure across the mud engine can be measured directly, or estimated from other measured characteristics. In some embodiments, the differential pressure across the slurry engine is estimated from vertical pipe pressure readings. Periodically “zeroing” can be performed to minimize error in the captured “bottom” standpipe pressure measurement. In other embodiments, the differential pressure across the slurry engine can be established by calculating the bottom circulation pressure and comparing it to the actual standpipe pressure.
[0095] In some embodiments, multiple drill weight calculations are monitored as a diagnostic tool. In one modality, values are automatically monitored. For example, a control system can monitor conditions and ratings: (1) current surface tension - background surface tension; (2) drag and torque drill weight model (“WOB”) using surface tension and background friction factor; (3) WOB drag and torque model using torque and background friction factor; and (4) WOB drill test against engine differential pressure.
[0096] In some embodiments, the control system may include logic to control drilling based on different subsets of assessments described above. For example, in slip drilling, methods 1 and 3 above may not be valid. If, during slip drilling the BHA turns off, method 2 may also become invalid (method 2 may, for example, read too high while not all of the weight is transferred to the drill. In some embodiments, monitoring logic may be based on one or more comparisons between two or more of the assessment methods given above. An example of logical monitoring is “If during slip drilling, method 4 differs from method 2 by more than (user setpoint %) , 'shutdown' detected.” As another example, if, during rotary drilling, WOB from evaluation method 3 is greater than evaluation method 2 by more than (user setpoint %), then the system Automated can report detection of an “excess torque to spin column.” In some modalities, column ROP or RPM may be reduced until the drill weight ratings return to tolerance.
[0097] In certain embodiments, mechanical specific energy (“MSE”) calculations are used in an automatic drilling process. In the case described above, for example, “excess torque to spin column” may register as high MSE.
[0098] In one embodiment, weight on a drill bit used to form an opening in a subsurface formation is evaluated using differential pressure measurement by the mud engine.
[0099] FIG. 6 illustrates drill bit weight evaluation using differential pressure according to a modality. In 200, a relationship between torque in a drill bit used to form an opening and differential pressure by the motor used to operate the drill bit is established. In some embodiments, the relationship is established using torque measurement on a drill bit on the surface of the formation, as described above with respect to FIG. 4.
[00100] In 202, a drill bit weight ratio to engine differential pressure is modeled. In one embodiment, the drill weight is modeled based on a difference in hook loading method. In another embodiment, the weight in drill is based on a dynamic torque and drag model eg the estimate of torque from drill induced lateral load to drill weight can be used.
[00101] At 204, during drilling operations, differential pressure across the engine is measured. At 206, the weight on the drill bit is estimated using the model established in 202. A relationship between weight on the drill bit and motor differential pressure (torque on the drill bit) evaluated as described above may remain valid while drilling in a given lithology.
[00102] In some embodiments, WOB is evaluated for multiple differential pressure readings taken over the course of a drilling operation. Data points can be fitted to points to continuously estimate WOB based on measured differential pressure. Curve fit can define a linear relationship between WOB and differential pressure. In one modality, differential pressures are read during one or more drill tests. FIG. 7 illustrates an example of a relationship established using multiple test points. Points 210 can be curve fitted to produce linear relationship 212.
[00103] In some embodiments, a test to refer WOB to differential pressure is performed while the sinus of the drill string is inside an internal drill pipe. When the core of the drill string is inside an internal drill pipe, the measured bit weight using either the “hook load difference” method or a dynamic torque and drag model can be relatively accurate, such as the factor uncertainty of open hole friction can be minimized. In one embodiment, a test is run when you first drill out of an inner pipe string in a new formation. In some embodiments, a WOB/differential pressure ratio is determined across a horizontal section of a well.
[00104] In some embodiments of a drill weight for a formation, an increase in lateral load associated with increased drill weight is taken into account to use torque measurements taken when the drill string is in the formation. For example, torque measurement can be used to solve for unknown drill weight using a drag and torque model. In one embodiment, measurements are taken, and drill weight assessed, at each joint, eg each drilling time is initiated as part of a drill test. In certain modalities, a constant friction factor is assumed.
[00105] FIG. 8 illustrates evaluation of a drill weight ratio that includes a drill weight-induced lateral load torque determination using surface torque and differential pressure measurements. At 214, pressure is measured to determine a differential pressure across a mud engine while drilling. The measurement can be, for example, as described above with respect to FIG. 3. At 216, a motor output torque is determined based on differential pressure. In some embodiments, the drill torque and motor output torque are assumed to be the same. The determination of torque in drill can be, for example, as described above with respect to FIG. 3.
[00106] At 218, torque on the surface drill string can be measured while drilling. Torque on the surface drill string can be measured directly with instrumentation on the formation surface.
[00107] At 220, the rotating torque off the bottom is measured. In some embodiments, the background rotary torque is self-sampled using a control system.
[00108] In 222, a lateral load induced by weight in drill is determined from torque estimates and measurements. In one embodiment, an increase in torque due to drill weight is determined using the following equation: WOB-induced lateral load torque = Surface torque (during drilling) - Motor output torque - Bottom rotary torque
[00109] At 224, a bottom friction factor is determined from the rotating torque data outside the bottom. Drill weight and drill torque can both be zero.
[00110] At 226, a WOB required to induce the lateral load torque induced by weight in drill is determined. The WOB is based on a drag and torque model using the off-bottom friction factor determined in 224. In 228, drill weight estimates are used to control drilling operations.
[00111] FIG. 8 illustrates a rotary drilling graph showing pressures and torques measured and calculated over time. Curve 231 shows the vertical pipe pressure. curve 232 shows the motor torque. Motor torque can be determined from differential pressure calibration. Curve 233 shows the measured surface torque. Curve 234 shows the lateral load torque induced by WOB. The WOB-induced lateral load torque can be calculated as described above with respect to FIG. 8. Curve 235 shows column torque. Column torque can be the difference between surface torque and motor torque. Curve 236 shows the bottom surface torque.
[00112] In some embodiments, an automatic drill operation is performed using differential pressure by a pump motor as the primary control variable. In some embodiments, a relationship between differential pressure across a pump motor and output motor torque is established using the measurement of torque in a drill string on the surface of the formation, as described above with respect to FIG. 3. A control system can automatically monitor conditions such as mud flow, WOB, and surface torque. In one embodiment, an automatic control system seeks a target differential pressure by increasing the rate of forward movement of a drill string in a hole while predefined conditions are met. Predefined conditions can be, for example, user-defined setpoints or ranges that cannot be exceeded. Examples of setpoints include: WOB is within (user setpoint) of maximum WOB, surface torque is within (user setpoint) of maximum torque, mud flow falls below (user setpoint) of target flow, torque instability exceeds (user setpoint), outflow differs from flow by more than (user setpoint), loss is detected, shutdown is detected, excess torque to drill is detected, pressure of standpipe differs from calculated circulation pressure by more than (user setpoint). In one modality, target differential pressure is 250 psi (1.72 MPa).
[00113] In one modality, directional drilling includes lowering by increasing mud flow and building by decreasing an RPM and/or flow. In some modalities, rotary drilling parameters are adjusted to adjust the tilt adjustment path control to the sides (without, for example, the need for slip drilling).
[00114] In one embodiment, individual subroutines in a PLC are incrementally joined together to allow complete joints to be drilled autonomously with combinations of sliding and rotary drilling. In certain embodiments, a drill is held at the bottom and low RPM drilling to synchronize the BHA tool face with the surface position prior to slip drilling. This can allow a PLC to stop the BHA on the tool face target and continue drilling in slip mode without the need to stop drilling or lift the drill from the bottom.
[00115] In certain modalities, a torque, a drag, column limit, and hydraulic model are run live. The model can estimate the column boundary and generate continuous tool face estimation to support the autonomous control system while drilling at a high Penetration Rate (ROP). In certain modalities, the model can generate threshold output at any time and fill gaps between downhole updates. Hydraulic pressure can be calculated as accurately as desired to have engine torque. The drill weight can also be obtained, for example, for specific mechanical energy analysis (“MSE”) purposes.
[00116] In some embodiments, a friction factor can be determined from test measurements. For example, a friction factor can be established from the motor output and torque measured on the surface. With input of drilling parameters such as RPM, ROP, surface rotation torque, surface hook load, the drill torque can be calculated. By matching the motor torque value with the calculated drill torque, an open hole friction factor can be determined (for example, by iterating to determine a value of a friction factor where the torques match). In some embodiments, drill weight, torque along the string, and string limit are achieved, for example, by using open hole friction factors automatically measured during drill string bottom moves. In certain embodiments, if the friction factor is at or below a specified minimum value (such as 0.2) or at or above a specified maximum value (such as 0.7), drilling can be stopped and the solution of the problem performed.
[00117] Once the bore WOB provided below and motor torque are available, torque as a function of the WOB can be computed, plotted, and displayed. In certain modalities, an MSE curve is determined and displayed. Drilling can be performed automatically using calculated values such as calculated WOB. In certain modalities, the friction factor can be recalculated while drilling is being carried out and used in automatic drilling.
[00118] In one embodiment, a method of evaluating a pressure used to form an opening in a subsurface formation includes measuring a basal pressure when the drill bit is freely rotating in the opening in the formation. A basal viscosity of fluid flowing through the drill bit is evaluated based on the measured basal pressure. As the drill bit drills further into the formation, the flow rate, density, and viscosity of fluid flowing through the drill bit are evaluated. As the drilling operation continues, the basal pressure may be re-evaluated based on the assessed flow rate, density and viscosity of the fluid flowing through the drill bit.
[00119] In some embodiments, viscosity can be determined from differential pressure. In one embodiment, Coriolis flowmeters are used to measure flow and density into and out of the well. Differential pressure is measured over a defined length of mud distribution line (which can be between the pump and drilling equipment of a drilling system). FIG. 9 illustrates the relationship between differential pressure and viscosity in a pipe. The example illustrated in FIG. 9 is based on a 20 m long 2 inch (5.08 cm) mud distribution line. Curve 240 is based on a flow rate of 400 gallons per minute (1514.16 liters per minute). Curve 242 is based on a flow rate of 250 gallons per minute (946.35 liters per minute).
[00120] Determining viscosity using differential pressure can eliminate the need for a viscosity meter. In some embodiments, however, a viscosity gauge can be included in a drilling system.
[00121] In one embodiment, a drill bit is automatically positioned at the bottom of the opening of a subsurface formation. Mud pumps are turned on and after a predetermined time the flow shifts (at a predetermined rate) to the target flow. Fluid flow to the drill string is monitored and controlled to be the same (within user setpoints) as the flow out of the well. The vertical pipe pressure is allowed to reach a relatively steady state. The drill string is rotated at a predetermined RPM. The drill bit is moved towards the bottom of the opening at a selected rate of feed until a consistent increase in measured differential pressure indicates that the drill bit is at the bottom of the opening. In some modalities this corresponds to drill depth (caves at the bottom of the hole or errors in depth measurement can however cause the “bottom” to be detected despite not matching the depth of the calculations). A number of setpoints can be established and variables monitored during the “Drill Lowering to Bottom” routine. The rotation of the drill string can be performed before the mud pumps are engaged to reduce pressure when the mud flow in the annulus resumes. The drill bit can be supported at the bottom of the opening if the fluid flow in the drill pipe is not substantially the same as the fluid flow out of the opening.
[00122] During drilling operations, once drilling progresses to the maximum available depth for a given length of drill pipe, the drilling equipment is used to finish drilling and prepare to add another length of drill pipe.
[00123] In one embodiment, a drill pipe is advanced in a formation. Pipe advance is stopped (eg when the maximum available depth for the drill pipe length is reached). The differential pressure across the mud engine is allowed to decrease. In some modes, the differential pressure is allowed to decrease to a user setpoint. Once the differential pressure has decreased to a prescribed level, the drill string can be trapped. A drag and torque model can be used to monitor the forces needed to perform the pickup. In one modality, forces themselves can predict and use as alarm markers (if exceeded, for example, by a user-defined amount). In another modality, the background friction factor is used. For example, if the background friction factor is over a specific amount (such as > 0.5), a “tight bore drawing” alarm condition may be triggered. After triggering an alarm, a mitigation procedure can be initiated.
[00124] In one modality, the open hole friction factor is evaluated during drilling. In certain embodiments, the open hole friction factor is continuously evaluated. For example, in modality, the open hole friction factor is continuously evaluated to verify that “normal” wellbore conditions exist as a permit to complement the selected task(s). Error handling stanzas can be defined to avoid and mitigate bad drillhole conditions.
[00125] Mud engine loss is a common event. Typically, the engine power section contains a rotor that is driven to rotate by the flow of drilling fluid through the unit. Rotation speed is controlled by fluid flow. The power section is a positive deflection system as rotational resistance (a breaking torque) is applied to the rotor (from the drill), the pressure needed to keep fluid flow fixed increases. Under various conditions, the power section's ability to keep the rotor rotating can be exceeded and the bit stops turning, ie a loss. A stall condition can sometimes occur within a second.
[00126] FIG. 10 illustrates a method of detecting a loss in a slurry engine and recovering from the loss according to a modality. At 260, a maximum differential pressure is defined for the drilling operation. At 261, drilling can be started. At 262, differential pressure can be evaluated. If the rated open bore friction factor is at or above the designated maximum differential pressure, a motor stall condition is rated at 263.
[00127] Upon detection of a loss, flow to the mud motor is automatically turned off (for example, by turning off a pump to the motor) at 264. In some embodiments, rotation of the drill string coupled to the drill bit is automatically stop at 265. In some modes, by detection of loss, drill pipe movement is automatically stopped (drill string forward movement is reduced to zero). At 266, the differential pressure is allowed to drop below the maximum designated differential pressure before allowing the engine to restart. In some modalities, excess pressure is relieved or allowed to be relieved. At 268, the drill bit can be lifted from the bottom of the well. At 270, the engine is restarted. At 272, drilling is restarted.
[00128] In one embodiment, bottom vertical pipe pressure is measured during drilling. A maximum mud engine differential pressure is evaluated. A loss is indicated when the sum of the bottom standpipe pressure and the maximum engine differential pressure exceeds a specified level. In one embodiment, the standpipe pressure is measured with an equipment standpipe pressure sensor.
[00129] Excessive accumulation of cutouts in a well while drilling can adversely affect a drilling operation. In one embodiment, mass balance measurement of drilled cutouts is used to monitor well conditions. In some embodiments, mass balance measurement information is used to automatically perform drilling operations.
[00130] In some embodiments, a method to assess drill hole cleaning efficiency in a subsurface formation excavated from the well can be determined, in one embodiment, by using offset log, logging log during drilling (" LWD”) in real-time, volume density of the formation. The length and diameter of the hole can be used to provide the volume, and the volume density record can provide the density estimate.
[00131] A mass of cutouts removed from the well can be determined by measuring the total mass of fluid entering the well and the total mass of fluid leaving the well, and then subtracting the total mass of fluid entering the well from the total mass of fluid leaving the well. The mass of cutouts remaining in the well can be estimated by subtracting the determined mass of cutouts removed from the well from the determined mass of rock excavated in the well. In certain embodiments, a measured amount of hole cleaning efficiency can be evaluated based on the determined mass of cutouts remaining in the well. FIG. 11 illustrates one embodiment of a method of determining hole cleaning efficiency. Partial fluid losses can be taken into account by excluding the lost fluid mass from the reconciliation.
[00132] In some embodiments, continuous monitoring of drilling fluid density and flow rate is achieved using Coriolis mass flow meters. In one embodiment, Coriolis meters are provided on both the suction and return lines to physically measure incoming fluid mass flow and temperature data. In one embodiment, a hydrometer, flowmeter, and viscometer are mounted in-line (eg, on a slide positioned between the active mud tank and mud pumps). In one embodiment, a viscometer is a TT-100 viscometer. The hydrometer, flowmeter, and viscometer can measure fluid entering the well. A second Coriolis meter is installed in the flow line to measure the fluid leaving the well.
[00133] In some embodiments, a control system is programmed to provide an autonomous drilling and data collection process. The process can include monitoring various aspects of drilling performance. A portion of the control system may be dedicated to processing drilling fluid data. The control system can use manual drilling fluid data inputs, sensory measurements, and/or mathematical calculations to help stabilize indicators and trends to validate real-time drilling performance. In some modalities, collected data can be used to determine a Hole Cleaning Efficiency.
[00134] In some embodiments, drilling fluid parameters are measured in real time. Real-time measurements can also increase data objectivity to facilitate immediate response to drilling fluid fluctuations. In some modalities, density, viscosity and flow are measured in real time while drilling. Real-time control and data collection of mud flow and density in and out of the well can enable accurate drilling parameter optimization. A control system can, for example, automatically react and make optimization adjustments based on sensor signals (with or without human involvement).
[00135] In some embodiments, mass balance measurement of perforated cutouts is used to provide trend indication for hole cleaning efficiency. In one embodiment, a mass balance calculation for a hole cleaning index (HCI) is determined by calculating the volume of cutouts left in the well and making an assumption that all cutouts are spread evenly along the horizontal section of the well. . The height of the cutout bed can be calculated and converted to a cross-sectional area occupied by the cutouts.HCI = Drill opening area/Area occupied by the cutouts
[00136] The fluid wellbore string can be independent of the surface system. Powder products or liquid additives transferred to the active system (if any products or additives exist) may not have any support in the mass balance of fluid being circulated through the well in real time. The excavated perforated cutouts can then be the only “additive” to the fluid column. An exception is the hypothesis that the perforated cutouts are the only additive there should be if there is an inflow of water from the formation. In some embodiments, the inflow of water is determined by monitoring for any unexpected decrease in rheological properties measured from an in-line viscometer. In other modalities, the aggregation of incoming volumes versus outgoing volume may indicate fluid inflows. The HCI can be adjusted based on any decrease to account for the incoming water flow.
[00137] In one modality, a Coriolis meter has a predefined calibration schedule. The Coriolis meter can have built-in high/low level alarms to confirm accurate data being received. In one example, a Coriolis 6’’ meter has two flow tubes, each having a diameter of 3.5’’ (88.9 mm). In one modality, the Coriolis meter controls material flow to an accuracy of +0.5 percent of the preset flow rate.
[00138] The use of automatic monitoring of cleaning efficiency can eliminate or reduce a need for human monitoring of operations, such as monitoring agitators. For example, personnel may not be needed on agitators to measure the viscosity and weight of slurry at periodic intervals. As another example, a mud engineer does not need to take a mud sample at periodic intervals.
[00139] Examples of mass balance monitoring are given below: Example #1 - Start circulation
[00140] A suction meter and a flow line meter are read and evaluated for balance.
[00141] (There may be a slight discrepancy due to fluid temperature, where the outgoing fluid will be warmer therefore possibly slightly lighter.)
[00142] In/Out Fluid: 2 m3/min x 1040 kg/m3 = 2080 kg/min
[00143] In-line fluid viscometer can measure at readings of 600, 300, 200, 100, 6 and 3 rpm. Collection time can be 1 second at each RPM speed. 6 seconds to process all six readings.
[00144] A temperature correction can be made based on an “observation” table. Example #2 - Start of drilling
[00145] A rock mass generated can be based on penetration rate and hole size.
[00146] The calculated mass of generated rock can be graphically represented in real time.
[00147] Hole size @ 311 mm x ROP @ 100 m/h = 7.59 m3 of excavated cutouts/h (7.59 m3/h x 2600 kg/m3)/60 min = 329 kg/min
[00148] 2600 kg/m3 can be an assumed value for the density of cut-offs - alternatively, an “observation” table recording density from offset wells can be used to distinguish the density for each formation.
[00149] A look-up table can be provided that includes offset data gauge record data to increase accuracy.
[00150] A look-up table can be provided that includes a VS wash percentage. Depth of offset wells.329 kg/min x 5% wash = 345 kg/min of rock being generated
[00151] A wash percentage can be plotted as a separate set of data points
[00152] The delay time can be computed based on the time it takes to empty the circular mud crown calculated from the annular volume and flow (an “upside down” time)
[00153] Cutout shape, size, fluid slip velocity, vertical VS horizontal perforation can be evaluated Example #3 - Mass balance
[00154] The total mass of fluid entering the well and the total mass of fluid leaving the well are measured. The total mass of fluid entering the well is subtracted from the total mass of fluid leaving the well. The difference could indicate the mass of perforated cutouts removed from the well.
[00155] Incoming fluid: 2.0 m3/min x 1040 kg/m3 = 2080 kg/min
[00156] Outgoing fluid: 2.0 m3/min x 1180 kg/m3 = 2360 kg/min
[00157] The difference is 280 kg/min
[00158] By subtracting this difference from the actual excavated rock mass, an indicator is obtained from a theoretical mass of drilled cutouts that were not removed from the well. Therefore 345 kg/min - 280 kg/min = 65 kg/min left in the well .
[00159] In one modality, flow measurements can be used to set permissions in the control system. For example, a permit can be set based on whether the flow out of the well is equal to the flow into the well within an established tolerance.
[00160] In some modalities, the performance of a mud solids handling system is monitored with the Coriolis measurement system. Density and rate (mass flow) of slurry from the ring crown of the well can be measured by going to the solids control system. The system's efficiency in removing solids can be measured by the Coriolis gauge on the other side of the system at the point where the slurry enters the slurry pump to be sent back to the borehole. By tracking the base mud density against the back hole mud density, the system's ability to remove drilled solids is assessed.
[00161] In some embodiments, solids left in the well are determined. An overall solids control system performance is determined based on an overall rock mass removal from both the well and drilling fluid. Overall solids control system performance can provide an indicator of how many cutouts are left in the well. In one modality, the measured rock mass is plotted against the theoretical generated rock mass. The result can be displayed to an operator in a graphical user interface. In certain modalities, a certain maximum solids limit is established. The boundary can be automatically displayed to a driller to provide the driller with a visual signal that the well is not being cleaned properly. The limit can be wired as a setpoint to be monitored by an automatic drill control system. If the system determines that wellbore cleaning is inadequate, mitigation subroutines can be initiated such as reducing penetration rate, increasing flow, increasing circulation time and rotational speed in the post-junction drilling phases and rpe.
[00162] One challenge encountered in directional drilling is to control the slippage of the drill bit, or the tool face of the hole set below (“BHA”). As used here, “BHA tool face” can refer to the rotational position at which the direction deflection device (such as a bent fitting) of a drill assembly is aimed. In a hole set below including a bent fitting, for example, the BHA tool face always slides off axis of the drill string placement at the end of the string. Commonly, when a section is drilled in a drill rotation mode, the BHA tool face continuously changes while the drill string rotates. The aggregate result of this continuously changing tool face can be that the direction of bottom drilling is generally straight. In a slip drilling mode, however, slipping the BHA tool face during the slip will define the drilling direction (while the BHA tool face can generally remain dotted in one direction over the slip course), and therefore can be controlled within acceptable tolerances. In addition, when changing from one drilling segment to another drilling segment or from one drilling mode to another drilling mode, re-establishing the BHA tool face may require substantial involvement of an operator and/or may require that the drill bit of drilling is stopped, both of which can slow down the rate of progress and drilling efficiency.
[00163] The challenge of controlling the BHA tool face can be compounded by winding the drill string. During drilling, the drill bit and drill string are subjected to various torque loads. In a typical rotary drilling operation, for example, a rotary drive, such as a top drive or rotary table, is operated to apply torque to the drill string on the surface of the formation to rotate the drill string. Since the hole assembly below and lower portions of the drill string are in contact with the sides and/or bottom of the formation, the formation can exert counteracting, resistive torque on the drill string in the opposite direction while the rotary actuator ( eg counterclockwise as seen from above). These counteracting torques at the top and bottom of the drill string cause the drill string to twist, or “roll,” within the formation. The magnitude of winding changes dynamically changes as external loads imposed on the drill string change. Additionally, the drill bit and drill string may also have torque related to drilling operations (such as torque resistant rotation of the drill bit in the opening). In drilling systems where the angular slip of the drill bit is used to control the direction of drilling (such as during slip drilling), the drill string winding can limit an operator's ability to control and monitor drilling processes.
[00164] One way to measure tool face direction is with downhole instrumentation (for example, an MWD tool in a hole set below). As with any MWD tool measurement, however, tool face measurements may not provide continuous tool face measurement, but only intermittent “snapshot copies” of the tool face. Furthermore, these intermittent readings may take some time to reach the surface. Thus, when the drill string is rotating, the most recently reported rotational position of the tool face of the MWD tool may delay the actual rotational position of the tool face.
[00165] In some embodiments, the rotational position of a drill string on the surface of a formation is used to estimate the rotational position of the BHA tool face. In one embodiment, a rotational position of a BHA is correlated with a rotational position of a top driver rotating a spindle on the surface of the formation. For example, it can be stated that under a particular condition, if the tool face is pointed upwards, then the rotational position of the top driver is within 25 degrees of a given reference. The process of correlating the rotational position of the BHA tool face with a rotational position on the formation surface is referred to here as "synchronization". In some embodiments, synchronization includes dynamically computing a “top side tool face”. The “top side tool face” at a given time can be the estimated rotational position of the tool face determined using the actual rotational position measured from the top driver, in combination with recent BHA tool face data received from the MWD tool . As the rotational position on the top driver is continuously available, the top side tool face can be a continuous indicator of the BHA tool face. This continuous indicator can fill time gaps between intermittent MWD tool downhole updates, such that better tool face (and thus trajectory) control is achieved than could be done with MWD tool face data alone . Once synchronized, the top side tool face can be used by a control system to stop the drill string with the BHA tool face in a desired rotational position, for example, to drive skid drilling.
[00166] In some embodiments, tool face synchronization is performed with the drill string at a specific RPM setpoint and a target motor differential pressure, while other drilling setpoints and targets are maintained.
[00167] In some embodiments, the synchronization is based on tool face BHA data from the MWD tool. A gravity tool face value (“GTF”) is received from the MWD tool. Synchronization can include synchronizing a BHA tool face with a rotating position on the surface of the formation. In certain embodiments, a top-side tool face is used to predict where the BHA tool face value will fall when a BHA tool face value is received from the MWD tool. The delay time between tool face sampling and surface data decoding can be taken into account by programming the delay time in a PLC or by measuring and taking into account a deviation based on RPM (eg by stopping of the top side tool face early by the “offset” amount. As noted above, once the tool face is synchronized, a programmable logic controller can stop the BHA tool face at a desired position to initiate slide drilling.
[00168] FIG. 12 illustrates tool face synchronization using MWD data according to an embodiment. At 300, the surface rotor can be decelerated to a tool face float RPM. In 302, tool face reading BHA can be read from the MWD tool until a designated number of samples is reached.
[00169] In 304, high and low rotor position limits can be determined around a BHA tool face setpoint. In one modality, the angle deviation between the desired tool face set point is calculated from models and/or the stable average of the last tool face readings. The Low Target Tool Face Setpoint and High Target Tool Face Setpoint Limit can be determined from the desired MWD tool face. Top-side tool face (a rotational position) can be calculated based on the current rotating position and the calculated angle offset.
[00170] In 306, an assessment is made if the top side tool face is within the established tolerance. If the top side tool face is not within the established tolerance, a rotor may continue to turn at floating RPM. The top side tool face can be re-evaluated until the top side tool face comes within the established tolerance. When the top side tool face is within established tolerances, the drill string can be stopped by being neutralized at 308. In some embodiments, a BHA tool face timing as described above is used in the drilling transition rotary for slip drilling. In other embodiments, a BHA tool face sync can be used in a stop drilling routine. In certain embodiments, tool face synchronization is used when a drilling system is pulled at the “stop” level to position the MWD in the same rotational position at each time, which can minimize roll dependent azimuth measurement variation .
[00171] In some embodiments, a drilling operation is performed in two modes: rotary drilling and slip drilling. As discussed above, rotary drilling can follow a relatively straight path and slip drilling can follow a relatively curved path. The two modes can be used in combination to achieve a desired trajectory. In some embodiments, a drill bit can be held at the bottom and rotating (at full speed or at reduced speed) during an automatically controlled transition from one drilling mode to another (such as rotary to slip, or slip to rotary ). In some embodiments, the drill can be held at the bottom and rotating (at full speed or at reduced speed) during an automatically controlled transition from one segment to another (such as from one slid segment to another slid segment). Continuing to drill during transitions can increase the efficiency and overall rate of the drilling process. In one embodiment, a transport driver (such as a rack or pinion drive) of a drilling rig provides force to maintain the engine's differential pressure at a target level. In other embodiments, the weight of the drill pipes within the wellbore provides the strength while the drilling rig at work allows the string to feed into the wellbore.
[00172] In some embodiments, controlling a slip drilling operation includes dynamic adjustment of the BHA tool face. In some embodiments, dynamic adjustment is performed during transition from a rotary punch mode to a slip punch mode. For example, to initiate a transition to a slip drilling mode, the drill string rotation can be slowed down to a stop. While slip drilling is decelerated to stop, the BHA tool face can be synchronized. Once the BHA tool face is synchronized, the BHA tool face can be adjusted (using, for example, clamping torque applied to the surface of the drill string to keep the BHA tool face in a desired rotational position during drilling by slip and using surface rotation to adjust the clamping torque up or down intermittently to effect a change in the BHA tool face. In some embodiments, a drilling system is prepared for slip drilling by tool face timing BHA and the "top side" tool face to allow rotation of the drill string to be stopped when the BHA tool face is in the desired position. Once the BHA tool face is stopped in the desired position, unwinding the drill string can be carried out to reduce the surface torque to the required clamping torque. Once the drill string is developed Held, the BHA tool face can be maintained with a clamping torque transmitted by a rotary drive system on the formation surface.
[00173] FIG. 13 illustrates a transition of a drilling system from rotary drilling to slide drilling. In this modality, the transition includes dynamic adjustment of a BHA tool face. At 318, the BHA tool face is synchronized. In one embodiment, synchronization may be as described above with respect to FIG. 12. In some embodiments, during or after synchronization, the rotary drive is stopped such that the BHA tool face is within tolerance of a desired rotational position setpoint.
[00174] In some embodiments, during tool face synchronization, the differential pressure by the mud motor that operates the drill bit (which can correlate to TOB and/or WOB) is brought to and/or maintained at a point of target setting for slip drilling. In other embodiments, differential pressure may be at a different level than the differential pressure for slip drilling. In certain embodiments, differential pressure by the slurry engine is controlled as a function of the BHA tool face. In one embodiment, if the BHA tool face is within a range of a target setpoint, then the differential pressure can be set. for a slip drilling differential pressure setpoint. In some embodiments, differential pressure across the mud motor may start at a reduced setpoint (such as 25% of the slip drill target differential pressure) based on deviation from a BHA tool face target.
[00175] At 320, a rotary drive can be stopped with the BHA tool face at the desired setpoint. At 322, the drill string can be unrolled. Unwinding can be both quick and practical for the drilling system. In some embodiments, unwinding can be based on a drag and torque model that includes column winding. In other embodiments, unwinding can be based on surface torque. In some embodiments, the column is unrolled to a neutral clamping torque. In other embodiments, the column can be unrolled to a left-roll clamping torque. As used here, “left roll hold torque” can equal drill torque as calculated from differential pressure minus a user-defined BHA “left roll hold torque” variable. A left roll clamping torque may be adequate, for example, if a system tends to stop with the BHA tool face rolled too far to the right.
[00176] For the initial transaction for slip drilling for rotary drilling, if the left roll clamping torque is being maintained, the tool face roller BHA can be monitored. If the BHA tool face is rolling to the right (forward), the BHA tool face will start to roll back as long as there is negative torque on the surface. The more negative torque, the faster the BHA tool face must stop and go back. The BHA tool face can also be rotated backward (“left”) or forward (“right”) with differential pressure changes.
[00177] If the BHA tool face is rolling to the left (backward), by contrast, the rotary can be turned to neutral clamping torque (drill torque) as soon as the BHA tool face reaches tolerance.
[00178] The BHA tool face is hardly stable initially. If the BHA tool face is stable for a long period, a fault alarm can be triggered.
[00179] At 324, the controller can monitor for stable BHA tool face. In 326, if the BHA tool face moves out of tolerance, the rotary drive on the surface can be adjusted to bring the BHA tool face back into tolerance.
[00180] In certain embodiments, a clamping torque is approximately equal to the slurry motor output torque as computed using a differential pressure ratio. Surface clamping torque is increased/decreased by surface rotation to maintain the equivalent torque as emitted by the mud motor, unless downhole tool face changes are required. In one example, an increase in motor output torque of 200 ft.lb (27.65 kg.m) may require a 45 degree forward surface rotation before a surface torque increase of 200 ft.lb ( 27.65 kg.m) be measured. The top side tool face can remain the same while adjusting the clamping torque.
[00181] In one embodiment, a control system automatically reduces the target differential pressure during a transition from rotary drilling to slip drilling. Once slip piercing is established, the control system can automatically resume the original target differential pressure.
[00182] BHA tool face monitoring can be based on measurements from downhole instrumentation, surface instrumentation, or a combination thereof. In one modality, the BHA tool face monitoring is based on a hole-down MWD tool. In one modality, the MWD delta tool face ratio (“DTF”) is monitored. If the BHA tool face moves outside the tolerance window, a surface rotor can be set to 328. For a given penetration rate, the DTF can be approximately constant for a given right roll clamping torque. As the BHA rolls in response to left-roll clamping torque, the surface torque will decrease. Surface torque can be maintained with rotation to maintain left-roll clamping torque and DTF rate. The left roll clamping torque is dynamic (based on drill torque), so if the motor torque increases due to formation change, the left roll clamping torque in the PLC may need clockwise rotation of surface (this surface clockwise rotation may counteract a tendency for the BHA tool face to roll to the left). As soon as the BHA tool face enters the tolerance window (based on the projection of the last measured DTF forward in time), the surface torque can be returned to neutral clamping torque (which can be the same as drill torque as calculated from the differential pressure) by the rotation of the rotary actuator on the surface.
[00183] At 330, slip drilling can be performed. The controller can monitor for stable BHA tool face, and the rotary drive can be adjusted to keep the BHA tool face in a desired rotational position. As discussed above, in some embodiments, drilling may continue through the transition from rotary drilling mode to slip drilling mode.
[00184] In some embodiments, since the BHA tool face installs on the window (based on the DTF) with surface torque equal to the neutral clamping torque, the column can optionally be balanced, oscillated or shaken to mitigate drag. Enhancement of the BHA tool face can be done by rotating the necessary increment in the surface, clamping position and allowing the surface torque to naturally return to the clamping torque.
[00185] Table 1 is an example of user setpoints for turn.

[00186] In one embodiment, to adjust the rotor to return the BHA tool face to the set point, the rotor can be turned until the current rotor top side tool face (TTF) is within the tolerance of the face of desired BHA tool. As used in this example, the top side tool face refers to the BHA MWD hole-down tool face transposed to the top side rotary position. The top side BHA tool face can make use of the last good MWD tool face reading and the current rotary position. For example, if the drill string is wound and the last tool face is 30 degrees from the model fit point, the top side rotary position can be rotated 30 degrees in the direction the drill string is wound.
[00187] In some embodiments, a method of adjustment includes decreasing the rate of progress, reducing the surface drill string RPM to zero, unwinding to a user-defined "unwind torque" (which corresponds to a negative clamping torque ), and pausing between surface adjustments based on the projected BHA tool face that takes the DTF into account against time. As the projected BHA tool face enters the desired range, the surface rotating position can be adjusted to resume neutral clamping torque. As shown in FIG. 4, the greater the negative or positive clamping torque (in the case indicated by the torque at the actuated connection), the greater the rate of change in the DTF (see the rate of change in roll to the right of the BHA). In certain modalities, the relationship between the magnitude of negative/positive clamping torque and the rate of change in TDF is automatically mapped.
[00188] In some embodiments, a turning method includes making two more adjustments to a surface rotor to achieve a desired BHA tool face. Between each adjustment, the rotor can be paused until the BHA tool face stabilizes. FIG. 14 is a time plot illustrating the turn in a transition from rotary drilling to slip drilling with surface adjustments at intervals. Curve 340 represents a tool face target. Points 342 represent readings from a gravity tool face (for example, from an MWD tool). Curve 344 is a point fitted curve 342. Curve 346 represents the rotational position of an encoder on the rotary drive. Curve 348 represents a top side BHA tool face. Curve 350 represents surface torque. Curve 352 represents zero torque.
[00189] Initially in 354, the drilling system is operated in a rotary mode. At point 356, tool face synchronization is started at 5 rpm. At 358, a reverse rotary adjustment is made. On 360, a forward rotary adjustment is made. At 362, the BHA is stable and the surface torque can equal the drill torque. On 364 and 366, forward rotation adjustments are made. At 368 the BHA is again stable and the surface torque can equal the drill torque. At 370, the drilling system can re-enter a rotary drilling mode.
[00190] In some embodiments, a transport or other drill string lifting system may be controlled (eg raised and lowered during a transition from rotary drilling to slip drilling). FIG. 15 illustrates a transition from rotary drilling to slip drilling including transport movement in accordance with an embodiment. At 390, transport movement of a drilling system is stopped. In 392, the transport can be lifted (eg to bring the drill bit from the bottom system). In one mode, the transport is raised by about 1 meter.
[00191] In 394, the BHA tool face is synchronized. In one embodiment, synchronization may be as described above with respect to FIG. 12. The rotary drive can be stopped with the BHA tool face at the desired setpoint. At 396, the drill string can be unrolled. Unwinding may be as described above with respect to FIG. 13.
[00192] In 398, the drill string can be struck while checking for a stable BHA tool face. A blow can include a lift and then a lowering of the carriage by an equal amount (such as two meters up and two meters down). The controller can monitor for BHA tool face stable at 400. At 402, if the BHA tool face moves out of tolerance, the surface rotor can be adjusted at 404 to bring the BHA tool face back into the tolerance. tolerance.
[00193] At 406, the drill bit can be lowered to the bottom of the formation. In some modalities, the BHA tool face can be lowered to the bottom at a preset angle to the right of the target BHA tool face. This can allow the BHA tool face to move to the left while the bit torque increases during drilling. In some embodiments, monitoring and adjustment as described in 402 and 404 can be continued while slip drilling is performed.
[00194] In some embodiments, a method of controlling drilling directions includes automatically rotating a drill string at multiple speeds during a rotation cycle. In certain embodiments, drilling at multiple speeds in one rotation cycle can be used in a course correction procedure. For example, drilling at multiple speeds in one rotation cycle can be used to shift the hole path back to line with a straight section of the well. In one modality, automatically rotating a drill string at multiple speeds is used as a course correction going sideways forward.
[00195] FIG. 16 illustrates a drilling mode in which the rotation speed of the drill string is varied during the rotation cycle. At 410, a target trajectory is established. In 412, during drilling operations, a drill string is rotated at one speed during a portion of the rotation cycle. At 414, the drill string is rotated at a second, lower speed during another “target” portion of the rotation cycle. Slower rotation in the target portion of the rotation cycle may tilt the drilling direction towards the target portion.
[00196] In some embodiments, a sweep angle of the target portion of the rotation cycle is equal to the sweep angle of the other portion of the rotation cycle (ie, 180 degrees in each portion). In other embodiments, the sweep angle of the target portion of the rotation cycle is unequal to the sweep angle of the other portion of the rotation cycle. In one example, the lowest target speed is 1/5 of the initial speed for the spin cycle. However, various other velocity ratios and angular proportions can be used in other modalities. For example, a target speed might be 1/6, 1/4, 1/3, or some other fraction of the starting speed. In certain embodiments, the speed of a rotor can be varied continuously over at least a portion of a rotation cycle. In certain modalities, a rotator can rotate at three or more speeds during a rotation cycle.
[00197] FIG. 17 illustrates a diagram of a multispeed rotation cycle according to an embodiment. In the example shown, the rotor speed is 5 RPM for 270 degrees of rotation cycle, and 1 RPM for the remaining 90 degrees of rotation cycle.
[00198] In some embodiments, a desired turn rate is achieved based on rotor speeds and sweep angles. In one example, the turn rate is estimated as follows: Assumptions:
[00199] At a target range is 90 degrees (+/- 45 degrees of intended angle change direction), a net half of the build rate can be expected in the average target range direction. If the engine pulls 10 degrees over 30 meters at full slip, liquidity can be 5 degrees over 30 meters. RPM is 5 and 1, 270 degrees at 5 rpm (30 degrees/sec), then 90 degrees at 1 rpm (6 degrees/s).
[00200] In the target range, the BHA resides for 15 seconds while on the opposite side, the BHA takes 3 seconds to cross the opposite target range. The discount of 5 degrees per 30 meters is then 3/15 x 5 = 1 degree per 30 meters. Any gauges drilled in a slip can be counteracted by gauges drilled in the opposite orientation.
[00201] Based on the preceding calculations, 4 degrees per 30 meters may be the expected construction rate. This build rate is further reduced, however, as there are two tool face quadrants to be traversed off-target and backside that also do not contribute to net angle change. In particular, for 6 seconds per revolution or 6 seconds per 24 seconds the BHA is to the left or right of the target quadrant so 6/24 x 4 degrees per 30 minutes = 1. This results in an expected build rate of 3 degrees per 30 minutes using a 10-degree slide BHA for 30 minutes, which translates, for example, 0.2 degrees of angle change if the procedure was employed to 2 m outside a 9.6 m junction.
[00202] Minimum curvature is commonly used in calculating trajectories in directional drilling. Minimum curvature is a computational model that fits a three-dimensional circular arc between two survey points. Minimum curvature can, however, be a poor choice if the sample interval used to take surveys does not capture tangent points along the varying curvature. Ideally, surveys can be taken each time drilling is changed from rotary drilling to slip drilling or each time the BHA tool face slip has been changed. Such a repeated survey can be time consuming and costly.
[00203] In one modality, placements (azimuth and slope) at known points along the well path can be used, in combination with the rotational drilling angle change trend, to estimate the placements at the start and end points of the section perforated by sliding without the need for extensive lifting. The tendency to change the rotary pierce angle is determined by observing the change in pierce angle as measured during a preceding section of rotary piercing. Estimated placements can be used as “virtual” measured depths to better represent the current drillhole path and thus improve position calculation.
[00204] In one embodiment, a method for predicting a drilling direction of a drill bit used to form an opening in a subsurface formation includes evaluating a drill bit depth at one or more selected points along the wellbore. An estimate is then made, based on the assessed depths, of the placements at the start and end points of each slip-drilled section. For slipped drilled sections contained within measured surveys, virtual measured depths, with position estimates, are evaluated by projecting a current survey back to one or more previously measured depths. These pre-measured depths, in some embodiments, can be used to assess the severity of slip drilling direction (“DLS”) and tool face performance (eg, where the well path was actually compared to where the BHA was appointed). The severity of slip drilling direction sharp deviation and tool face performance can also be evaluated based on sampling sections of full drilled hole in rotation mode that contain at least two surveys.
[00205] In some embodiments, a drill projection is refreshed based on drill mode and samples DLS trends each time a measured depth is updated. In certain embodiments, a projection back to previous measured depth is made to set up virtual measured depths, with positioning estimates, for perforated sections slid by slip within measured depth limits.
[00206] In some embodiments, the path of a wellbore made using a combination of rotary drilling and slip drilling is estimated using a combination of current survey data (such as from MWD tools below hole) and at least one drilling angle change trend established during rotary drilling. For example, if a wellbore is formed by rotary drilling, slip drilling, and rotary drilling in succession, a trend of angle change while rotary drilling is initially determined (eg using survey data). A directional change value (such as a sharp deviation angle of direction) is determined for the slip-perforated section based on current surveys (for example, using current surveys that flank the slip-perforated section). The directional change value of the slip pierced section can be adjusted based on flank lifts. The directional change value can take into account, for example, any portion between current surveys that were rotary drilled and for the trend of angle change during such rotary drilling. A net angle change across the slip-drilled section can be determined using pre-determined design forward data (which may include, for example, the slip start and end placements). A projection for drill value can be renewed using the net angle shift. The revamped projection can be used to estimate the path of the wellbore, for example, as part of a continuous “virtual” survey.
[00207] FIG. 18 illustrates a schematic of a drill string in a wellbore for which a virtual continuous survey can be evaluated. In FIG. 18, drill string 450 includes drill pipe 452. Drill string 450 has been advanced into a formation. Portion 454 was advanced using rotary drilling, portion 456 was advanced by slip drilling, and portion 458 was advanced by rotary drilling. Stations 460 (marked by asterisks) are the survey depths (“measurements”). Lift depths correspond to the position of the MWD sensor behind the drill. For this example, the distance between the drill and the MWD sensor is around 14 meters so, for example, while the drill is drilled to 20m, the MWD sensor only reaches 6m. while the drill is drilled to 30 m (assuming 10 m length of drill pipe) the MWD sensor only reaches 16 m. the first three joints are rotated to 30m. At this point, there are 30m of rotated hole and 2 complete sample intervals of rotary drilling. Surveys at 6m and 16m, along with surveys previously taken, are all taken in the hole that has been drilled rotationally. The trend of rotary drilling angle change can be determined by analyzing the drift (eg positioning) at the MWD sensor position for at least three surveys. In one modality, the first and last surveys are used to determine the change in positioning during rotary drilling, this change in positioning can be used to determine the tendency to change the rotary drilling angle. For purposes of this example, the trend of rotary drilling angle change during drilling was determined to be 0.5 degrees per 30 minutes @ 290 degrees.
[00208] For this example, the last 3m of junction 4 are slip drilled. This takes the hole depth from 37m to 40m. the next two joints are rotary drilled to bring the hole depth to 60m. at this point the drill is at 60m, the MWD sensor is at 46m, and a slip-drilled section is contained within the depth range of 36 to 46m.
[00209] The sharp deflection angle of direction (“DL”) and tool face (“TF”) for the slip drilled section can be calculated using the current surveys traversing the slip drilled section. In the context of the surveys described with respect to FIGS. 18 to 18C, “tool face” refers to the actual change in the direction of a hole. For purposes of the surveys described in FIGS. 18 to 18C, “TFO Fit Offset”, or “Tool Face Offset Offset” refers to the difference between the direction in which the motor (for example, the curve in a curved connection motor) was pointed and where the hole really went. For purposes of this example, the values for the current survey are as shown below:

[00210] The sharp deviation angle of direction due to rotational drilling angle change tendency, about 7m at 0.5 degree per 30 meters @ 290 can be determined as 7/30*0.5 = 0.12 @ 290 0.12 in 290 degrees can be considered to represent a polar coordinate.
[00211] This value can be converted to rectangular coordinates

[00212] Dx and Dy can be converted back to polar coordinates:
[00213] Based on the above calculations, the slip drilled section weaves an angle change of a 4.49 degree sharp deviation angle on the tool face of 28.01.
[00214] From the original design forward data, a net angle change across the slip drilled section can be determined, for example, by taking the initial slip drill azimuth and slope and again the rotary drill azimuth and slope and then using these values to calculate a tool face and net direction sharp deflection angle.
[00215] The projection can be renewed. Assuming the projection estimate was that the slip drilling DL was 0.5 @ 045 degrees, a projection based on 30/3 x 4.49 = 44.9 degrees per 30 meters. Tool face offset offset is approximately 45 - 28 = 17 degrees.
[00216] The recalculated projection can now approximate the positioning by 46m as the measurement from the MWD.
[00217] In certain embodiments, the goal search can be performed to make the projection DL the same as the current (measured) DL by changing an original slip DLS prediction. In certain modalities, target search can be performed to make Projection Tool Face Offset (“TFO”) the same as the current TFO (measurement) by changing the TFO adjustment offset. In some modalities, “virtual surveys” are entered into the survey file. In one modality, the virtual survey can be used to assess performance for a slip drilling BHA. Example
[00218] Non-limiting examples are shown below.
[00219] FIG. 18A is a diagram illustrating an example of slip drilling between MWD surveys. In the example illustrated in FIG. 18A, a 4m slip is performed from a lift depth of 1955.79 to 1959.79, at a tool face fit of 130. The net angle change between lifting to 1955.67m and lifting to 1974.5m was determined to be 0.75 degrees and the direction of the angle change was determined to be 90.00438 degrees with respect to the higher side (at 1955.67m). for this example, in the original forward projection, the sharp steering deviation severity for the slip drilling section was 12 degrees for 30 minutes and the TFO adjustment deviation was -10 degrees. Steering sharpness severity for rotary drilling was 0.6 degrees per 30 meters at a tool face fit of 290.
[00220] Based on the information mentioned above, the sharp deviation of direction caused by the slip-perforated section and the actual tool face deviation of the angle of change that occurred in the slip-perforated section was determined as follows: The pursuit of the target was performed to make sharp deviation from the projection direction equal to the sharp deviation from current direction (MWD) by changing the original slip direction sharp deviation prediction. Based on the pursuit of the sharp turnaround objective, the sharp turnaround severity for the slip was reduced to 7.83 degrees per 30 meters. The target search was then performed to make Project Tool Face Offset equal to the current tool face offset (MWD) by changing the tool face Fit Offset. Based on this TFO target search, the sharp steering deviation severity was further reduced to 7.7517 degrees per 30 meters and the TFO adjustment deviation was changed to -34.361511 degrees. New points representing the start and end of the skid section were then determined to produce two virtual surveys.
[00221] FIG. 18B is tabulation of the original survey points for this example. FIG. 18C is tabulation of the survey points for this example with two new virtual survey points added in rows 460. Additionally, in FIG. 18C the trajectory estimate for the final lift position at 1974.5m has been updated in cells 462 (compared to the values in corresponding cells 464 for the original final lift position at 1974.5m shown in FIG. 18B).
[00222] In certain embodiments, an updated Tool Face Offset Offset and new estimate for slip direction sharp offset severity are used for real-time design for drill and direction calculations.
[00223] Vertical appraisal wells can provide some top elevation data with respect to a formation. Unfortunately, horizontal well MWD survey elevation data may have a higher uncertainty than the thickness of the oil production well “sweet spot” (for example, a 4m thick sweet spot with a MWD survey of +/- 5m). additionally, from structure contours made from horizontal well MWD data, significant variance can be found.
[00224] In some embodiments, a true vertical depth (“TVD”) is evaluated using fluid density measurements. In one embodiment, a method of evaluating a vertical depth of a drill bit used to form an opening in a subsurface formation includes measuring downhole pressure exerted by a column of fluid in a drill pipe. The density of the fluid column is evaluated based on a density measurement at the surface of the formation (eg with a Coriolis gauge on the suction side of a mud pump). An actual vertical depth of the drill bit can be determined based on the hole pressure evaluated below and the density evaluated. The actual vertical depth is used to control subsequent drilling operations to form the opening. In some cases, a control system automatically adjusts for variations in mud density within the system.
[00225] In some cases, TVD measurement data is used to control jet drilling.
[00226] In one embodiment, a method of determining actual vertical depth includes installing a Coriolis gauge as a slip current at the mud tank outlet. An optimum range and precision pressure gauge can be attached to an MWD tool. A pressure transducer is installed on the MWD tool. A density column is modeled on a PLC to account for mud density variation in the time taken to fill the constructed section. The internal BHA pressure is sampled. Internal pressure can be transmitted to the surface and/or stored. In one embodiment, the pumping pressure signature is detected (see, for example, FIG. 19) and the static fluid column pressure is measured and reported to the surface PLC as at 502.
[00227] In one embodiment, the pressure exerted by a column of fluid within a drill pipe is recorded using a pressure sensor (attached, for example, to the end of the MWD apparatus within a first non-magnetic collar). Fluid column density can be measured with a Coriolis gauge on the suction side of a slurry pump. Real-time full vapor density can be measured in the suction line of pumps using, for example, a Coriolis meter accurate to +/- 0.5 kg/m3. Datasets can be used can be used to calculate TVD. In one modality, internal pressure in the BHA is recorded using, for example, a +/- 0.5 psi (3.45 kPa) pressure transducer.
[00228] FIG. 19 illustrates an example of recording pressure during added “pumping” of a drill pipe joint according to an embodiment. In the example shown in FIG. 18, smooth line pressure was extracted along with slurry density data to calculate the vertical height of the fluid column. The 500 curve is a pressure plot recorded during connection. Flat section 502 represents a stationary, complete column of fluid with the top driver disconnected waiting for the next joint to be added.
[00229] FIG. 20 illustrates an example of density TVD results. Stitch set 504 and stitch set 506 each correspond to a different side. Lines 508 and 510 (TVD positive and negative, respectively) correspond to a curve fit of the data. Lines 512 and 514 (TVD positive and negative, respectively) correspond to a standard ISCWSA 2 sigma survey. The TVD density data obtained in this example may resemble position calculations on magnetic stripes.
[00230] Each value is unique and not subject to the cumulative error that can be obtained using systematic MWD slope measurement error. The longer the horizontal, the greater the advantage of TVD based on TVD rating of MWD over density. For example, as reflected in FIG. 20, the density-based DTV data cloud may only have about half the spread of the standard MWD ISCWSA 2 sigma survey model.
[00231] A best fit using this dataset suggests the current location of the well path is equivalent to 0.15 degree of systematic slope measurement error below the calculated position.
[00232] In some embodiments, compensation may be made, in a density TVD calculation, for one or more of the following sources of error: (1) contaminated pressure measurements from imperfections/deficiencies in use/floating connection design ; (2) mud pump charge pumping system malfunction and cavitation bubbles causing density measurement noise; and (3) mud density variation not taken into account in the construction section. In one embodiment, the TVD density measurement is used to verify hole position for hole manipulation below tools or at critical depths such as tangents in the well path.
[00233] MWD tools often include sensors that rely on magnetic effects. The large amount of steel in a downhole assembly can cause a significant error in MWD survey data. One way to reduce this error is to space the MWD tool a significant distance (such as 16 meters) away from the main BHA steel components. Such large spacing between the MWD and BHA sensors can, however, make directional guidance much more difficult, especially in horizontal drilling. In some embodiments, a calibration procedure is used to measure and account for the interference at Bz of a downhole assembly. In one embodiment, a method for measuring and accounting for magnetic interference from a BHA includes: (1) measuring the mast strength of steel BHA components; (2) record MWD net correction/declination/Btotal & Bdip measurement locally with a tool roll test site at a known alignment, (3) calculate the Bz interference at the chosen non-magnetic spacing; (4) use the planned well path geometry to plan spacing needs; (5) apply an offset (during or post-drilling) allowing for known interference to MWD Bz measurements; and (6) recalculate the azimuth using modified Bz measurement. In some embodiments, BHA components can be demagnetized.
[00234] In some embodiments, inertial navigation sensors such as fiber optic gyroscopes can be used for drilling navigation. Optical gyroscope sensors can, in some cases, replace magnetic sensors, thus alleviating the interference effects of steel in a BHA.
[00235] One method of directing a drill bit to form an opening in a subsurface formation includes using real-time design for drill data. Real-time data can be, for example, data collected between periodic updates (“snapshots”) from a measurement while drilling tool (MWD) on a hole bottom set. In one method, a survey is taken with the MWD tool. Survey data from the MWD tool establishes a definitive path for the MWD sensor. The placement measured on the sensor is used as a starting point from which to project the placement and position of the drill bit in real time. Real-time projection for drill can take into account drilling parameters such as tool face values recorded against slip intervals. When a subsequent survey is taken with the MWD tool to produce a new definitive position and positioning, the real-time design for the drill is updated based on the new definitive path and the values used for tool face offset offset and offset severity brusque slip direction are updated for subsequent drill projections.
[00236] In some embodiments trajectory calculation is based on surveys (such as silent surveys collected while adding drill pipe to the column). Survey data can be collected by direct connection to the MWD hardware/software interface. Data can be appended to Measured Depth as generated by the drill depth value - drill drive value. Path calculation can be treated as a “final” path for the purpose of drilling a hole.
[00237] In some modalities, the system automatically accumulates a database. In the database, rotation drilled intervals and slip drilled intervals can be recorded. Slip drilled ranges can be updated each time tool face data point is received from the MWD. The tool face value is recorded against this slip interval.
[00238] A drilling of the next joint is prepared, the definitive path updates to as close as possible to the drill (hole depth - drill lead).
[00239] While a definitive path is updated before starting a new drill joint, the design for drill calculation can update as follows:
[00240] (1) if the forward section of the drill is all in rotation, the positioning on the drill is estimated accordingly.
[00241] (2) if there is a slip perforation in the forward section of the sensor, the positioning can be estimated by the accumulation of dl (differential length) on the tool faces received at the recorded intervals.
[00242] (3) position change can be accumulated to current drill position taking into account all tool face v. interval steps and rotating drill sections.
[00243] Real-time design drill placement can be used for a real-time drill position calculation (which can be tied to the last definite path position point).
[00244] FIG. 21 is a plot of actual vertical depth versus measured depth illustrating an example of a drill design. Point 550 is a definite prior slope point. Point 552 is a projected slope point. Point 554 is a definite “close to receive” slope point. The 556 point is a new projected true vertical depth (TVD) point. For a 15m lead drill, the drill bit starts 15m away as the system starts to drill a new joint. The drill design extends to 15m + joint length just before the next silent survey is received. In one embodiment, a non-rotating sensor housing can be used. Difference 558 represents an error projection. In some modalities, error projection is followed for slope and azimuth for placement on the drill (eg up/down position, left/right).
[00245] One method of driving a drill bit to form an opening in a subsurface formation using an optimal alignment method includes surveying with an MWD tool. Survey is used to calculate hole position. A drill design is determined (eg using best fit curves). The drill bit design is used in combination with an optimal alignment method to keep the drill bit within a predetermined tolerance of a drill plan.
[00246] In one embodiment, implementing direction in a PLC includes taking a survey and adding the survey to a calculated hole position. A drill design is performed (using, for example, best fit curves for build rate (“BUR”) or tool face results, or rotary vector). Formation corrections (such as lift shots/gamma shots) and piercing corrections (tool face errors, differential pressure out of range) can be applied. In certain modalities, learned knowledge can be taken into account (eg, an average BUR run) when correcting best-fit curves. A drill projection can be added to the survey. A project ahead can be determined.
[00247] Slip recordings can be kept in a database manually or automatically. While the drill performs slip and rotation intervals, the system can automatically generate slip recordings. These recordings can also be entered and edited by a user. Slip recordings can be recorded with Time, Depth, Slip (Yes/No), Tool Face and DLS. Slip recordings have two main functions: (1) to project from the last survey to the hole end (the project can be a real-time calculated position of the hole end; and (2) to analyze the slip performance.
[00248] In certain embodiments, a system includes an engine interface. The motor interface can be used after tests have been performed (eg a pressure vs. flow rate test) and an adequate number of samples have been captured. From testing, trend lines (such as pressure vs. flow) can be generated.
[00249] In one embodiment, a method for generating direction commands includes calculating a distance from design and an angle (positioning) offset from design. The angle deviation from the design can represent the difference between the slope and azimuth of how fast the hole is diverging/converging with respect to the plane. In some embodiments, the distance from the design and an angle (positioning) deviation from the design are calculated in real time based on the hole position in the last survey, the position at the current projected drill location, and the position of the drill (eg a forward design position).
[00250] In certain embodiments, a tuning interface enables a user to adjust driving instructions, for example, by defining setpoints in a graphical user interface. In certain modalities, adjustment controls can be used to establish a “ahead view” distance for computing driving instructions.
[00251] FIG. 22 is a diagram illustrating an embodiment of a plan for a hole and a portion of the hole that has been drilled based on the plan. Plane 57- is a curve representing the path of a hole as designated. Plan 570 may be a line from the beginning to the end of a well that defines the desired path of the well. Hole 572 is a curve representing a hole that has been partially drilled based on plane 570. Survey points of MWD 574 represent points at which current surveys are taken while hole 572 is drilled. Current surveys can be taken using MWD instruments as described here. MWD surveys at each of the MWD 574 survey points can provide, for example, a position (defined, for example, by actual vertical depth, bearing and east components) and positioning (defined, for example, by slope and azimuth ). As previously discussed, MWD instrumentation can be uphole (such as about 14 meters) from drill 576. Points 576 represent a projected position of one end of a drill bit used to drill the hole. Line 577 represents a placement of the drill at point 576.
[00252] In certain embodiments, from the last MWD survey, the angle of a hole is calculated for the current drill position based on a slide table. If the hole is rotary drilled to the current drill location from the last MWD survey, the projection can use the rate of angle change (severity sharp deviation of direction) at a particular tool face direction that is selected for a drill. rotating. In some embodiments, a controller uses the automatic BHA performance analysis values for sharp deviation from rotary drilling direction and direction. In other embodiments, a controller uses manually entered values. Once the rate and direction of the curve that the BHA will follow is defined, the system can track the drill depth in real-time and perform angle shift vector additions to maintain a real-time estimate of slope and azimuth in the drill. .
[00253] A similar method can be used for slip drilling, with in some cases an additional user definition step to define where the slip tool face will be taken from. For example, the sliding tool face can be taken from real-time MWD updates, or from tool face adjustment before joint drilling (for example, a controller can calculate that a 5m slip with adjustment of tool face at 50 degrees is required).
[00254] In certain embodiments, an upper Aldo tool face adjustment can be used to determine the projected drill position. A top side tool face can be used, for example, for a system having a slow MWD tool face refresh rate.
[00255] FIG. 23 illustrates one embodiment of a method for generating direction commands. A method for generating direction commands can be used, for example, in fabricating a hole such as the hole shown in FIG. 22. At 580, a current lift on a drill for an actual hole being drilled is determined. The survey can include a drill position and placement. In some modalities, a current survey can be used to project the future position of a drill in real time, for example, from current MWD survey data. For example, with reference to FIG. 22, a current position for drill 576 can be projected from an MWD survey taken at the most recent MWD survey point 574A.
[00256] In 582, a distance from the determined position of the drill to the planned (projected) position of the drill is determined. In some modalities, a three-dimensional “closest approach” distance of the drill from the plane is calculated. (A flat closest approach point is shown, for example, at point 590 shown in FIG. 22). From the three-dimensional closest approach distance calculation, the depth of the planned path (“depth in plane”) that corresponds to the three-dimensional point that is determined. Using the depth at the plane value, the planned position and positioning values such as plane slope, azimuth, east, north, and TVD at the depth determined at the plane point can be calculated (by interpolation, for example). The calculated position and positioning values can be used to calculate tool face changes to return the hole back to the planned position.
[00257] A direction from the current drill location to the planned drill position can be calculated. For example, the tool face from the point of the drill plane (determined from the closest three-dimensional approximation) can be determined. The reverse direction, the tool face from the drill back to the plane, can also be determined.
[00258] In 584, a plane placement (azimuth and tilt) is determined at a specified forward check distance. (a forward checkpoint on a plane and correspondingly positioning are shown, for example, at point 592 and positioning 594 shown in FIG. 22). In some modalities, the slope and azimuth are interpolated into the forward check distance. The specified distance can be, for example, a user-defined distance. In one mode, the forward check distance is 10m. The design front for the forward check can be determined in a similar way as used to design the lift in a design drill position.
[00259] In 586, a tuning convergence angle is determined based on distance from the drill to the plane. The tuning convergence angle can be, in certain embodiments, the angle that the tool face is changed to bring the drill back to the intended position. In some embodiments, the tuning convergence angle varies based on the three-dimensional drill separation from the plane.
[00260] In certain embodiments, a convergence angle can be determined on a slip scale. The table below gives an example of a slip scale for determining a tuning convergence angle.

[00261] At 588, a target placement (azimuth and slope) is determined. The hoist placement can be based, for example, on the plane placement of the check distance ahead. In some embodiments, the target positioning is adjusted to account for a tuning convergence angle, such as the tuning convergence angle determined in 586.
[00262] In 590, one or more direction instructions are determined based on the target placement relative to the current drill placement determined in 588. In some embodiments, a direction solution corresponds to an angle as determined in the forward check distance , plus an additional angle of convergence required in the forward check position. (A direction for an instruction is represented, for example, in arrow 596 shown in FIG. 22).
[00263] In some embodiments, once a target angle has been defined in the check distance ahead, the tool face required to get there and the required slip drilling length are calculated (eg, in the defined direction sharp deviation severity for slip motor performance). In one modality, a sharp deviation of direction and required TFO are calculated between a current drill survey and a target slope/azimuth. Using slip direction sharp deviation expected input, a slip length to achieve the required direction sharp deviation can be calculated. The tool face can be calculated as, for example, a gravity tool face or a magnetic tool face. In certain embodiments, a controller automatically uses a magnetic tool face when the bit placement has an inclination of less than 5 degrees. In some embodiments, direction sharp deviation severity/tool face response values are fixed, for example, by a user. In certain modalities, BHA performance analysis automatically generates a necessary steering solution to respond to output.
[00264] In some embodiments, a PLC incorporates a direction control response slip scale via setpoint adjustment parameters. The further (in distance) the hole is away from the design, the greater the convergence angle can be used to calculate as a course correction. FIG. 24 illustrates a modality of a user input screen for entering setpoint adjustment. The convergence adjustment angle can be used as the convergence angle back to the plane. For example, when the hole is closed to the plane, the PLC can put “zero convergence” in the forward check to generally maintain a parallel path. While the hole is further away, the system can increase the toe-in angle depending on how far the hole is from the hole. For example, when 0 to 0.5m away from the plane, the system can look at the angle of the plane 10m beyond which the current drill position and use that slope and azimuth, plus 0 degree convergence angle, to determine whether a direction is needed. If 0 to 3m away from the plane, the system can look at the plane angle 10m beyond the current drill position and use the slope and azimuth, plus 1 degree of tuning convergence angle, to determine if a direction is required.
[00265] In certain modes, additional setting criterion of maximum or minimum slip distance can be established in a command to be passed through the PLC. For example, based on the set points shown in FIG. 24, only slips greater than 1m or less than 9m of slip may be allowed.
[00266] In some embodiments, while drilling, surveys are captured and projections are made to the end of the hole. The control system can calculate the point at which a slip must be performed. Setpoints can drive calculations to tell the system when to slip and for how long.
[00267] Entries may include one or more of the following:
[00268] - Maximum three-dimensional plane offset - Sets the maximum plane offset the wellbore is allowed to go before the controller provides a slip correction.
[00269] - Minimum slip distance - Restricts minimum slip length, ignoring required slips that are less than this value.
[00270] - Maximum slip distance - Restrict the maximum slip length.
[00271] - Average Junction Length - Average Junction Length Estimate
[00272] - TFO Slip Tolerance - Allows slip drilling to continue with the current TF when the live MWD TF slips from the desired TF.
[00273] - BHA performance check - Hole distance to analyze BHA performance
[00274] - BHA slip performance analysis - Option to calculate real-time slip performance
[00275] - BHA Rotating Performance Analysis - Option to calculate real-time rotating performance
[00276] - Lead distance seeking TF - Issues command to go to slip mode early by specified depth.
[00277] In some embodiments, information describing the current wellbore location and directional drilling needs to return to a plane is provided in the control system in the form of drilling directives. Directives are automatically calculated as each join is completed. The user has the option of leaving the calculated results or modifying them. Under ideal conditions, the user will simply leave this screen alone. And each subsequent join will automatically update as the punched join is completed.
[00278] Drill directives can be used to instruct the drill sequence to be performed for the next join. Directives can be automatically calculated as each join is completed. Each subsequent join can automatically update as the punched join is completed.
[00279] In some embodiments, adjustment of direction decisions can be achieved by radial adjustment. Radial adjustment can include, for example, keeping within a given distance from the design that is the same in any up/down - left/right direction. In other modalities, fit can be used to implement “rectangular” steering decisions. In an example of rectangular direction, the lateral position specification for the drill path is allowed to be greater than the vertical position. For example, the drill may be allowed to be 10 m to the design right but held vertically within 2 m offset from the design.
[00280] In some modalities, a set of limiting setpoints are established based on geotargeting. Geosteering-based setpoints can work in a similar way to drilling setpoints, except that they operate to affect a planned trajectory. For example, planned path may remain valid unless gamma counts (or other geosteering indicator signal) exceeds a user setpoint then planned slope is reduced by an angular user setpoint until new trajectory is defined quantity per user setpoint below the previously planned trajectory.
[00281] A method for estimating tool face orientation between downhole updates during drilling in a subsurface formation that includes coding a drill string (such as with an encoder on a top driver) to provide angular orientation of the drill string on the surface of the subsurface formation. The drill string in the formation is run in calibration to model drill string winding in the formation. During drilling operations, angular orientation values from the drill string are read using the encoder. The tool face orientation can be estimated from the angular orientation of the drill string on the surface, with the drill string winding model taking into account the winding between the tool face and the drill string on the surface. Tool face estimation in surface measurement can fill the gaps between telemetric updates from measurements while drilling tools (MWD) in the downhole assembly (which are “instant copies” that can be spaced out in more than 10 seconds ).
[00282] In some embodiments, a column closure template is created based on a calibration test. In one embodiment, the drill string can be rotated in one direction until the BHA is rotating and the friction factor is stabilized, at which time the winding is measured. The drill string is then rotated in the opposite direction until the BHA is rotating and the friction factor is stabilized, at which time the winding is measured again. Based on the results of the calibration test, a live estimate of the BHA tool face is used to fill in gaps between bore measurement readings below.
[00283] As discussed previously, in certain embodiments, a friction factor can be determined from test measurements. For example, a friction factor can be established from the motor output and torque measured on the surface. A column winding can be analytically determined by calculating a torque for each element and the cumulative torque below that element using the friction factor determined from test measurements. From calculated torques, the torsional turns for each element and total torsional turns on surface can be determined. From calculated torques, the torsional turns for each element and the total torsional turn on surface can be determined.
[00284] In some embodiments, a surface rotating position is synchronized with hole-down position to allow tool face estimates of hole-down to be made based on winding variation caused by measured touch changes during drilling between face updates. tool.
[00285] In certain embodiments, a system includes a graphic display of winding on a drill string. For example, a graphical display can show wraps/rotation movement traveling up and down the string while torque turns the shift from each end of the drill string.
[00286] Additional modifications and alternative embodiments of various aspects of the invention may be apparent to those skilled in the art in view of this description. Accordingly, this description is to be construed as illustrative only and is for the purposes of teaching those skilled in the art the general mode of carrying out the invention. It is to be understood that the forms of the invention shown and described herein are to be taken as preferred embodiments at present. Elements and materials may be substituted for those illustrated and described herein, parts and processes may be reversed, and certain features of the invention may be used independently, all as should be apparent to those skilled in the art having benefited from this description of the invention. Changes may be made to the elements described herein without departing from the spirit and scope of the invention as described in the following claims. Additionally, it should be understood that features described herein may independently, in certain embodiments, be combined.

权利要求:
Claims (9)
[0001]
1. Method of driving a drill bit (134) to form a wellbore (572) in a subsurface formation (102), comprising: a) determining (582) a distance from the wellbore design (572) , where the distance from the wellbore design (572) is a distance from the current position (576) of the drill bit (134) to a design position (590) of the drill bit (134) wherein the current position of the drill bit (134) being projected from a last survey; b) determine an angle offset from the wellbore design (572), where the angle offset from the wellbore design (572) is a difference between a drilled wellbore slope and azimuth and a design slope and azimuth, the angle offset from the design of the wellbore (572) is an indication of how fast the wellbore is diverging or converging from the design; c) wherein at least one distance from the wellbore design (572) and at least one angle offset from the wellbore design (572) are determined in real time based at least in part on a drillstring position (134) in the last survey, the current position of the drillstring (134), and a forward observation position (592) of the drillstring (134); automatically determining one or more driving instructions based, at least in part, on the wellbore design determined distance (572) and the wellbore design determined angle offset (572); and automatically directing the drill bit (134) based, at least in part, on at least one of the driving instructions, characterized in that it comprises: establishing a specific observation distance ahead; where automatically determining one or more driving instructions comprises: determining a project attitude at the forward observation distance; determine a target attitude based on the project's attitude at the forward observation distance; and where one or more steering instructions are also based on the target's attitude relative to the current drill's attitude.
[0002]
2. Method according to claim 1, characterized in that the observation distance ahead is specified by a user.
[0003]
3. Method according to any one of claims 1 or 2, characterized in that it further comprises specifying (586) a convergence angle and adjusting the target attitude to take the convergence angle into account.
[0004]
4. Method according to claim 3, characterized by the fact that it varies depending on how far the location of the bit (134) is from the design, in that the greater the distance from the location of the bit to the design, the greater the convergence angle .
[0005]
5. Method according to claim 3, characterized in that the convergence angle is determined automatically, wherein the convergence angle is based on a slip scale.
[0006]
6. Method according to any one of claims 3 or 4, characterized in that at least one of the direction instructions is based on a given angle to the plane at the established forward observation distance plus the specified convergence angle.
[0007]
7. Method according to claim 2, characterized in that it further comprises the step of establishing at least one of a minimum slip distance and a maximum slip distance for a driving instruction.
[0008]
8. Method according to claim 1, characterized in that it further comprises: receiving at least one input from a user; and, automatically adjust at least one driving instruction using user input.
[0009]
9. Method according to claim 1, characterized in that it further comprises: receiving at least one setpoint from a user; and automatically determine at least one steering instruction using the setpoint.

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法律状态:
2020-09-29| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-02-02| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-04-20| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 20/04/2021, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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US32325110P| true| 2010-04-12|2010-04-12|

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US61/323,251|2010-04-12|

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US61/323251|2010-04-12|

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PCT/US2011/031920|WO2011130159A2|2010-04-12|2011-04-11|Methods and systems for drilling|

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