• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
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    • 专利摘要:
    METHOD FOR CONTROLLING A DRILL ASSEMBLY AND SYSTEM FOR CONTROLLING A DRILL ASSEMBLY An example method for controlling a drilling assembly includes receiving measurement data from at least one sensor coupled to a positioned drill assembly element in a formation; an operational constraint for at least a portion of the drill assembly can be determined based, at least in part, on a model of the formation and a set of displacement data. A control signal can be generated to change one or more drilling parameters of the drilling set based, at least in part, on the measurement data and the operating restriction. The control signal can be transmitted to a controllable element of the drilling assembly.
    公开号:BR112016010704B1
    申请号:R112016010704-7
    申请日:2013-12-20
    公开日:2021-07-06
    发明作者:Richard Thomas Hay;Daniel WINSLOW;Neelesh Deolalikar;Michael Strachan
    申请人:Halliburton Energy Services, Inc;
    IPC主号:
    专利说明:

    [0001] Hydrocarbons, such as oil and gas, are commonly obtained from underground formations that may be located on land or in the sea. In most cases, formations are located thousands of feet below the surface, and a wellbore must intersect the formation before hydrocarbon can be recovered. As well-drilling operations become more complex, and correspondingly hydrocarbon reservoirs become more difficult to reach, the need to accurately locate a drilling assembly – vertically and horizontally – in a formation increases. Drilling the well holes to reach the formations of interest within the mechanical and operational limits of the drilling system and yet accurately and efficiently is difficult, but important to the profitability of the drilling operation. Brief description of the figures
    [0002] Some examples of specific embodiments of the disclosure may be understood by reference, in part, to the following description and accompanying drawings.
    [0003] Figure 1 is a diagram of an example drilling system in accordance with aspects of the present disclosure.
    [0004] Figure 2 is a diagram of an example information management system, according to aspects of the present disclosure.
    [0005] Figure 3 is an example of a block diagram of an earth model, according to aspects of the present disclosure.
    [0006] Figure 4 is a diagram of an example process for generating hold and output control signals, in accordance with aspects of the present disclosure.
    [0007] Figure 5 is a diagram of an example control system in accordance with aspects of the present disclosure.
    [0008] Figure 6 is an example diagram of a control system for a steering set, according to aspects of the present disclosure.
    [0009] Figure 7 is a graph illustrating an example of operational hold that corresponds to windings in a drill string, in accordance with aspects of the present disclosure.
    [0010] Figure 8 is a graph illustrating an example of operational retention to prevent drill whirl, in accordance with aspects of the present disclosure.
    [0011] Figure 9 is a diagram of an example drilling tool capable of changing one or more drilling parameters, in accordance with aspects of the present disclosure.
    [0012] Figure 10 is a diagram of an example impulse control unit in accordance with aspects of the present disclosure.
    [0013] Figure 11 is a diagram of an example downhole engine, in accordance with aspects of the present disclosure.
    [0014] Although embodiments of this disclosure have been represented and described and are defined by reference to examples of embodiments of the disclosure, such references do not imply limitation of disclosure, and no such limitation should be inferred. The disclosed subject matter is capable of considerable modifications, alterations, and equivalents in form and function, as will occur to individuals skilled in the pertinent art who come to benefit from this disclosure. The depicted and described modalities of disclosure are only examples and not exhaustive of the scope of disclosure. Detailed Description
    [0015] For the purposes of this disclosure, an information management system may include any instrumentality or aggregate of operable instrumentalities to compute, classify, process, transmit, receive, retrieve, originate, switch, store, display, manifest, detect, record , reproduce, manage or use any form of information, intelligence, or data for business, scientific, control or other purposes. For example, an information handling system can be a personal computer, a network storage device or any other suitable device and can vary in size, shape, performance, functionality and price. The information management system may include random access memory (RAM), one or more processing resources, such as a central processing unit (CPU) or hardware or software control logic, ROM, and/or other types of non-volatile memory. Additional information handling system components may include one or more secondary storage devices such as disk drives, solid state drives such as Flash RAM drives, cloud-type storage devices on a network, one or more network ports for communication with external devices, as well as various input and output (I/O) devices such as a keyboard, mouse, and video monitor. The information management system may also include one or more operable buses to transmit communications between the various hardware components. It may also include one or more interface units capable of transmitting one or more signals to a controller, actuator, or similar device.
    [0016] For purposes of this disclosure, computer readable media may include any instrumentality or aggregation of instrumentalities that may retain data and/or instructions for a period of time. Computer readable media may include, for example, without limitation, storage media such as a direct access storage device (eg a hard disk drive or floppy disk drive), a sequential access storage device (eg. , a tape disk drive), compact disk, CD-ROM, DVD, RAM, ROM, electrically erasable programmable read-only memory (EEPROM), and/or flash memory; as well as other means of communication, such as cables, optical fibers, microwaves, radio waves and other electromagnetic and/or optical carriers; and/or any combination of the above.
    [0017] Illustrative embodiments of the present disclosure are described in detail in this document. For the sake of clarity, not all attributes of an actual implementation can be described in this specification. It will obviously be understood that in the development of any of these modalities in fact, several implementation-specific decisions are made in order to achieve the objectives of a specific implementation, which will vary from one implementation to another. In addition, it will be appreciated that such a development effort can be complex and time-consuming, but would nevertheless be a routine endeavor for those skilled in the art who have the benefit of this disclosure.
    [0018] To facilitate a deeper understanding of the present disclosure, the following examples of certain modalities are provided. In no way should the following examples be read to limit or define the scope of disclosure. Embodiments of the present disclosure may be applicable to horizontal, vertical, deviated or otherwise non-linear wellbore holes in any type of underground formation. The modalities may apply to injection wells as well as production wells, including hydrocarbon wells. Modalities can be implemented using a tool that is suitable for testing, retrieval and sampling throughout training sections. The modalities can be implemented with tools which, for example, can be transported through a tubular column flow passage or using logging cable, slickline cable, coiled tubing, downhole robot or the like.
    [0019] The terms "couple" or "couple" as used in this document are intended to mean direct or indirect connection. Thus, if a first device couples to a second device, this connection can be through a direct connection or through an indirect mechanical or electrical connection through other devices and connections. Likewise, the term "communicatively coupled" as used in this document is intended to mean either a direct or indirect communication connection. Such a connection can be a wired or wireless connection such as Ethernet or LAN. Such wired and wireless connections are well known to individuals moderately skilled in the art and therefore will not be discussed in detail below. Thus, if a first device communicatively couples to a second device, this connection can take place through a direct connection or through an indirect connection via other devices and connections.
    [0020] Modern oil drilling and production operations require information regarding downhole parameters and conditions. There are several methods for collecting downhole information, including logging while drilling ("LWD") and measuring while drilling ("MWD"). In LWD, data is typically collected during the drilling process, thereby avoiding any need to remove the drill assembly to insert a wire rope forming tool. LWD therefore allows the driller to make precise real-time modifications or corrections to optimize performance while minimizing downtime. MWD is the term for measuring downhole conditions involving the movement and location of the drill assembly while drilling continues. LWD focuses more on training parameter measurement. While there may be distinctions between MWD and LWD, the terms MWD and LWD are often used interchangeably. For the purposes of this disclosure, the term LWD will be used with the understanding that this term encompasses both the collection of formation parameters and the collection of information relating to the movement and position of the drill rig.
    [0021] Fig. 1 is a diagram of an example drilling system 100 in accordance with aspects of the present disclosure. Drilling system 100 may comprise a drilling rig 102 positioned on surface 104. In the embodiment shown, surface 102 comprises the top of a formation 106 that contains one or more layers of rock 106a-d. Although the surface 104 is shown as being terrestrial in Fig. 1, the drilling rig 102 of some embodiments may be located offshore, in which case the surface 104 would be of the drilling rig 102 by a volume of water.
    [0022] Drilling system 100 may include rig 108 mounted on drill rig 102 and positioned above hole 110 within formation 106. In the embodiment shown, a drill assembly 112 may be at least partially positioned within hole 110 and coupled to rig 108. Drill string 112 may comprise a drill string 114, a wellbore assembly (BHA) 116, and a bit 118. Drill string 114 may comprise several segments of drill pipe that are threaded. . BHA 116 can be coupled to drill string 114, and drill 118 can be coupled to BHA 116.
    [0023] The BHA 116 may include tools such as the telemetry system 120 and LWD/MWD 122 elements. The LWD/MWD 122 elements may comprise downhole instruments - including sensors, antennas, gravimeters, gyroscopes, magnetometers, units inertial measurement tools etc.- - which can continuously or intermittently monitor downhole conditions and measure aspects of hole 110 and formation 106 around hole 110. LWD/MWD 122 elements can further measure an angle to the face of the tool. downhole elements, an angular position of the downhole elements with respect to formation 106. Such measurements can be provided as measurement data for a processor (for example, as described in Figure 2 below). In certain embodiments, the information generated by the LWD/MWD element 122 can be communicated as measurement data to the surface using the telemetry system 120. The telemetry system 120 can provide communication with the surface along various channels, including the data channels. wired and wireless communications, as well as mud pulses through a drilling mud in drill assembly 112.
    [0024] In certain embodiments, the BHA 116 may further comprise a steering assembly 124. The steering assembly 124 may be coupled to the drill 118 and can control the drilling direction of the drill assembly 112 by controlling the angle and orientation of the drill with respect to the BHA 116 and/or the formation 106. The angle and orientation of the drill 112 can be controlled by the steering assembly 124, for example, by controlling a longitudinal axis 126 of the BHA 116 and a longitudinal axis 128 of the drill 118 together with respect to formation 106 (eg a push-the-bit drill arrangement) or by controlling longitudinal axis 128 of drill 118 with respect to longitudinal axis 126 of BHA 116 (eg an arrangement to aim the drill - point-the-bit)
    [0025] In the illustrated embodiments, the longitudinal axis 128 of the drill 118 is offset relative to the longitudinal axis 126 of the BHA 116. The longitudinal axis 128 of the drill 118 may correspond to a drilling direction of the drill assembly 112, i.e., the direction in which drill 118 will cut into formation 106 when rotated. Notably, steering assembly 124 can be communicatably coupled to telemetry system 120, as well as one or more downhole and/or surface controllers that can determine and communicate to steering assembly 128 the drilling direction for the drill set 112.
    [0026] A pump 130 located on surface 104 can circulate drilling fluid at a pumping rate (e.g., gallons per minute) from a fluid reservoir 132 through a feed tube 134 to the kelly 136, through the bottom of the well through the interior of drill string 114, through holes in drill bit 118, back to the surface through the annular space around drill string 114, and into fluid reservoir 132. drilling transports debris from hole 110 to reservoir 132 and aids in maintaining integrity or hole 110. The pump rate in pump 130 can correspond to a downhole flow rate that varies from the pump rate due to loss of fluid within formation 106. In certain embodiments, the BHA 116 may comprise a fluid-driven downhole motor (not shown) that converts drilling fluid flow to rotational and t-movement. orque that is used to drive drill 118. The torque applied to drill 118 by the downhole motor and the resulting rotation rate of drill 118 may be based, at least in part, on the pump rate.
    [0027] In certain embodiments, portions of the drill assembly 112 may be suspended from the equipment 108 by a hook assembly 138. The total downward force exerted on the hook assembly 138 may be referred to as a hook load, characterized in that by the weight of drill string 114, BHA 116, drill 118, and other downhole elements coupled to drill string 114 minus any weight-reducing forces such as friction along hole wall 110 and buoyant forces on the drilling chain 114 caused by its immersion in drilling fluid. When the drill 118 contacts the bottom of the formation 106, the formation 106 will shift part of the weight of the drill assembly 112, and this displacement may correspond to the weight under the bit (WOB) of the drill assembly 112. The hook assembly 138 may include a weight indicator, which shows the amount of weight suspended from hook 138 at any given time. In certain embodiments, the position of hook assembly 138 relative to equipment 108 and therefore hook and WOB loading can be varied using a winch 140 coupled to mounting assembly 138.
    [0028] Drilling system 100 may further comprise a top drive mechanism or rotary table 142. Drill string 114 may be at least partially inside rotary table 142, which can transmit torque and rotation to the drill string. drill 114 and cause drill string 114 to rotate. Torque and rotation transmitted over drill string 114 can be transferred to BHA 116 and drill 118, causing both to rotate. The torque on drill 118 caused by rotary table 142 and/or downhole motor link described above can be referred to as torque on drill (torque-on-bit, TOB) and the rotation rate of drill 118 can be expressed in revolutions per minute (RPM). Rotation of drill 118 can cause drill 118 to engage with or pierce formation 106 and extend hole 110. Other drill assembly arrangements are possible.
    [0029] In certain embodiments, the drilling system 100 may comprise a control unit 144 positioned on the surface 104. The control unit 144 may comprise an information handling system that implements a control system or a control algorithm for the drilling system 100. Control unit 144 can be communicatably coupled to one or more controllable elements of drilling system 100, including pump 130, hook assembly 138/winch 140, LWD/MWD elements 122, rotary table 142 and steering assembly 124. Controllable elements may comprise elements of drilling assembly 112 that respond to control signals from control unit 114 to change one or more drilling parameters of drilling system 100, as will be described below. Control unit 144 can be communicably coupled to surface controllable elements via wired or wireless connections, for example, and can be communicably coupled to downhole controllable elements via telemetry system 120 and a surface receiver 146. In certain embodiments, the control system or algorithm may cause the control unit 124 to generate and transmit control signals to one or more elements of the drilling system 100.
    [0030] In certain embodiments, the control unit 144 can receive input data from the drilling system 100 and output control signals based, at least in part, on the input data. Input data may comprise measurement data or logging information from the BHA 116, including direct or indirect measurements of drill parameters for drill set 112. Examples of drill parameters include TOB, WOB, bit rotation rate, angle of drill face, flow rate, etc. Control signals may be directed to elements of piercing system 100 communicatably coupled to control unit 144, or to actuators or other controllable mechanisms between those elements. In certain embodiments, some or all of the controllable elements of drilling system 100 can include limited, integral control elements or processors that can receive a control signal from control unit 144 and generate a specific command to corresponding or other drivers. controllable mechanisms.
    [0031] The output of control signals by the control unit can cause the elements of the drilling system 100 to which the control signals are directed to change one or more drilling parameters. For example, a control signal directed to pump 130 can cause the pump to change the pump rate at which drilling fluid is pumped to drill string 114, which in turn can change a flow rate through a downhole motor coupled to the drill 118 and the TOB and rotation rate of the drill bit 118. A control signal directed to the hook assembly 138 can cause the hook assembly to change the load of the hook causing it to a 140 winch supports more or less the weight of the drill assembly, which can change the WOB and TOB. A control signal directed to the rotary table 142 can cause the rotary table to change the rotation speed and torque applied to drill string 110, which can change TOB, drill bit rotation rate 118, and angle of the tool face of the BHA 116. Although the control signals are described above in relation to the surface elements of the drilling system 100, in certain embodiments as will be described below, one or more downhole elements may receive control signals of a controller and change one or more drilling parameters based on the control signal. Other types of control signals would be appreciated by one of skill in the art in view of the present disclosure.
    [0032] Fig. 2 is a block diagram showing an example information management system 200, in accordance with aspects of the present disclosure. The information management system 200 can be used for example as part of a system or control unit for a drilling assembly, and can be located on the surface, at the bottom of the well (eg in a borehole) or partially on the surface. and partially at the bottom of the well. For example, a drilling operator may interact with information management system 200 located on the surface to change drilling parameters or to issue control signals to controllable elements of a drilling system communicatably coupled to information management system 200 In other embodiments, information management system 200 can automatically generate control signals that cause elements of the drilling system to change drilling parameters based, at least partially, on input data received from the background elements. well, which will be described in detail below.
    [0033] The information handling system 200 may comprise a processor or CPU 201 that is communicatively coupled to a memory controller hub or north bridge (north bridge) 202. The memory controller hub 202 may include a memory controller for directing information to or from various system memory components within the information management system, such as RAM 203, storage element 206, and hard disk 207. The memory controller hub 202 can be coupled to RAM 203 and a graphics processing unit 204 The memory controller hub 202 may also be coupled to an I/O controller hub or south bridge (south bridge) 205. The I/O hub 205 may be coupled to computer system storage elements, including a storage element 206, which may comprise a flash-ROM that includes a basic input/output system (BIOS) of the computer system. The I/O hub 205 is also attached to the hard drive 207 of the computer system. The I/O hub 205 can also be coupled to a Super I/O 208 chip, which is itself connected to several of the computer system's I/O ports, including the keyboard 209 and a mouse 210. information 200 may also be communicatably coupled to one or more elements of the punching system via chip 208. Information management system 200 may include software components that process input data and software components that generate commands or signals. control based, at least partially, on the input data. As used in this document, software or software components may comprise a set of instructions stored on a computer-readable medium that, when executed by a processor coupled to the computer-readable medium, causes the processor to perform certain actions.
    [0034] According to aspects of the present invention, a control unit may determine or receive at least one operating restriction for a drilling assembly, and may generate and produce control signals for the elements of the drilling assembly based, by less in part, on the operational constraint and on the input data received. Operating restrictions may comprise a range of drilling parameter values or a range of values relative to the drilling parameters of the drilling assembly. In addition, operating constraints can be calculated to ensure that the drill assembly stays within the physical and mechanical limits of the drill string elements, or to optimize the operation of the drill string or a drill string element.
    [0035] In certain embodiments, operating constraints can be determined using at least one of a terrestrial model and a set of displacement data. Figure 3 is a diagram of an example terrestrial model 300, in accordance with aspects of the present disclosure. As can be seen, the terrestrial model 300 comprises a formation 302 with layers 302a-d, each of which may contain a different type of rock with different mechanical and electromagnetic characteristics. Model 300 can identify the particular locations, orientations, rock types and characteristics of the formation of layers 302a-d, including the locations of boundaries 304-308 that separate layers 302a-d. In certain embodiments, the model 300 may be generated from on-site logging and survey data, including, but not limited to, acoustic, electromagnetic, and seismic survey data. Although terrestrial model 300 is shown as a visual representation for explanatory purposes, terrestrial model 300 may also comprise a mathematical model.
    [0036] In certain embodiments, a control unit may incorporate inward displacement data or to use it in conjunction with the 300 terrestrial model to determine operating constraints for the drilling assembly. As used in this document, data displacement can comprise actual data recorded from other drilling operations that correlates rock and formation types with certain drilling tools and parameters. Displacement data can, for example, identify torque interactions between rock types and drill bits, drill speed limits for certain types of formations, etc. Displacement data can be characterized by the rock types corresponding to the data, and associated with these rock types in model 300. Therefore, operational constraints determined using terrestrial model 300 and a displacement dataset can be layer specific , with each layer associated with a different operating constraint or set of operating constraints.
    [0037] Fig. 3 further illustrates a well plan 350 within formation 300. Well plan 350 may include the predicted trajectory of a well drilled in formation 300. Model 300 can be used to identify where and when the well will intersect boundaries 304-308, when and where the well will encounter certain types of rock formations in layers 302a-d, the expected downhole drilling parameters when a drilling set following well plan 350 is in contact with layers 302a-d, and operational constraints to use when emitting control signals. When a well is being drilled in accordance with well plan 350, a control unit can select the operating constraint or set of operating constraints associated with the formation layers in which the drilling set is positioned according to the terrestrial model 300 and well plan 350, and may use the selected set of operational constraints to generate and issue control signals to elements of the drilling set. In addition, the control unit can use input data from the drilling set to determine when a boundary has been crossed for different layers in the terrestrial model 300, and can select the operational constraint or set of operational constraints associated with the different layers. The control unit can also use the input data to verify terrestrial model 300 and to update terrestrial model 300 and operational restrictions if terrestrial model 300 is incorrect.
    [0038] Fig. 4 is a diagram of an example process for generating operational constraints and issuing control signals based, at least in part, on the operational constraints, in accordance with aspects of the present disclosure. The process can be implemented in an information management system or control unit, as described above. In the embodiment shown, a terrestrial model 400 and a set of displacement data 402 can be received in a processor, which can generate a set of expected measurement values 404 based, at least in part, on the terrestrial model 400 and the displacement data. 402. The set of expected measurement values 404 may include subsets that are associated with the different formation layers identified in the terrestrial model 400. In the depicted modality, the set of expected measurement values 404 is expressed as EXPi with i corresponding to a layer of the formation outside the formation layers in the terrestrial model 400. The expected drilling parameter set 404 may comprise the drilling parameters and/or downhole logging measurements that are expected within certain formation layers based on the type of layer from the ground model 400 and the drilling parameters and/or downhole logging measurements found and m similar layers from displacement data 402.
    [0039] In certain embodiments, a processor may receive the measurement set of expected values 404 and at least one physical, mechanical or operational boundary 406 of the drilling set, and may generate a set of operational constraints 408 based at least in part in the set of expected drilling parameter values 404 and at least one physical, mechanical or operational boundary 406 of the drilling set. The at least one physical, mechanical or operational characteristic 406 of the drill assembly may comprise limits beyond which the drill assembly or an element of the drill assembly will not function as intended. These limits can be based on the mechanical limits of the drill assembly, for example, the strength of downhole bearings, the tensile strength of downhole tools, etc. Thresholds can also be based on interactions between the different elements of the drill assembly. For example, as will be described below, a particular steering set may only be able to maintain the drilling direction of the piercing set when certain torque or rotation parameters come together in relation to the power available to the steering set.
    [0040] The set of operating constraints 408 can be generated or calculated by the processor and can reflect a series of drilling parameters or a range of values related to the drilling parameters of the drilling set that will ensure that the drilling set works as intended and/or function optimally. As the set of expected drilling parameter values 404, the set of operational constraints 408 may include subsets that are associated with the different formation layers identified in the terrestrial model 400, with the operational constraints 408 in Fig. 4 as indicated OpCi and corresponding i to a formation layer outside the formation layers in terrestrial model 400. In certain embodiments, operational constraints 408 may be multi-dimensional with respect to the drilling parameters of a drilling assembly. Specifically, operational constraints 408 may comprise two or more dimensional covers that limit combinations of two or more drilling parameters.
    [0041] In certain embodiments, the set of operational constraints 408 may be used by a control system or algorithm 410 to control the drilling system 412. Specifically, the control system 410 may receive input data 414 from elements of the drilling system 412 and can selectively output control signals 416 to drilling system 412 based, at least in part, on a comparison between input data 414 and set of operational constraints 408. 410 control can automatically generate 416 control signals for the 412 drilling system without operator involvement. Also, in certain embodiments, control system 410 can use input data 414 to update ground model 400 for formation or to monitor drilling assembly operating conditions.
    [0042] Fig. 5 is a diagram of an example control system process in accordance with aspects of the present disclosure. For explanatory purposes, the process below may comprise a variable formation current x which can be adjusted to values corresponding to one or more formation layers i, i+1, i+2, etc. The variable formation current x can be defined as i initially, with i being corresponding to the formation of layers closer to the surface. Step 500 may comprise receiving input data from at least one element of a drilling system. As described above, input data may comprise measurement or logging information from a BHA which may include direct or indirect measurements of drilling parameters from the drilling assembly. At step 502, the input data can be compared directly to a set of expected measurement values associated with actual formation layers x, EXPx, or input data can be compared with EXPx after the input data is processed.
    [0043] In step 504 it is determined whether the input data is within a range of the set of expected EXPx measurement values. If the input data is within the range of the set of expected measurement values EXPx, the input data can be compared to a set of operational constraints associated with the actual formation layers X, OpCx, in step 506. If the input data are not in the range of the EXPx expected measurement value set, this may indicate that a terrestrial model used to determine the EXPx expected measurement value set is incorrect, or the drill set depth is not known with precision to the terrestrial model, and the process may move to step 508. Step 508 may comprise determining whether the input data is in the range of the set of expected measurement values associated with the next i+1 layer formation. This can happen, for example, when the boundary for the next layers of formation i +1 is reached, and one or more parameters or downhole measurements reflect conditions in the next layers of formation x +1. If the input data is in the range of the set of expected measurement values associated with the nearby formation layers x+1, the current formation layers variable x can be set to i+1 in step 510, so that the set The correct operational constraints can be selected for comparison in step 506. If the input data is not in the range of expected drilling parameters for the i+1 formation layers, the terrestrial model can be updated in step 512 and the set of values expected measurement and operational constraints for layers i can be recalculated in steps 514 and 516, respectively.
    [0044] Step 518 may comprise determining whether the input data is in the range of the set of operational constraints associated with the current formation layers X, OpCx. If the input data is in range, then the drilling set may be operating within the set of OpCx operational constraints, and the process may return to step 500, where new input data is received. If the input data is not in range, the controller or processor can generate one or more control signals in step 520. As described above, the control signals can cause one or more elements of the drill assembly to change a parameter of drilling system so that the drilling assembly operates within operating limits.
    [0045] In other embodiments, the processor or control system may even monitor changes in one or more drilling parameters over time using the input data. Changes in drilling parameters within one of the forming layers indicate, for example, a mechanical condition of the tool. In one embodiment, the control system can receive input data from the drilling system and determine the TOB each time the input data is received. If the TOB changes over time with an identification gradient, or changes sharply when a formation boundary is not present, this may indicate that a mechanical failure has occurred in one or more elements of the drilling assembly, and the drilling operation may be stopped so that maintenance operations can be performed.
    [0046] The control and process system described above can be used with different elements and systems of a drilling set. In one embodiment, the control system described above can be used with a steering assembly similar to that described above with respect to Fig. 1 to ensure that the steering assembly accurately maintains a selected piercing direction. Some steering assemblies utilize downhole power sources (eg, electric motors, fluid flow, etc.) to maintain the drill bit's drilling direction while the bit engages with a formation. The energy available at the power source can impose limits on the direction set with respect to the drilling parameters that can be accommodated and adjusted to maintain the drilling direction. For example, in a 'point-the-bit' rotary steerable application, a steering assembly may use a counter-rotating force to counteract the torque and rotation applied to the drill by the drill string to maintain the desired angular orientation of the drill string. drill in relation to training. If the torque and rotation rate are kept within a certain range defined by the operational restrictions for the steering set, the steering set can have enough energy to compensate for the torque and rotation to maintain the piercing direction. If torque and rotation rate exceed that range, the steering assembly may not have enough power to compensate for the torque forces and the drilling direction may change.
    [0047] FIG. 6 is an example diagram of a control system for a steering assembly, in accordance with aspects of the present disclosure. As described above, the system may comprise a control unit or controller 600 that receives input data corresponding to drilling parameters. In the embodiment shown, the input data 602 comprises direct measurements for TOB, WOB and rotation rate of one or more sensors at or near the steering assembly. TOB, WOB and slew rate measurements can be communicated to controller 600, which can be located, for example, on the surface or downhole within a BHA. The 600 controller can also be given operational restrictions for TOB, WOB, and slew rate drilling parameters that can be calculated based, at least in part, on the operational capabilities of the steering set. If one or more of the measured TOB, WOB and slew rate exceeds the 604 operating restriction, the controller 600 can generate the 606 control signals for one or more elements of the drilling system to cause the elements to change one of the parameters of drilling. For example, controller 600 can generate a control signal to the hoist/hook assembly on the surface to lower downhole WOB and/or a control signal to the top unit to change rotation rate and torque applied to the drill string. As will be described below, controller 600 can also trigger a downhole mechanism to vary TOB or WOB.
    [0048] In many cases, the drill string to which the steering assembly is attached can be thousands of feet long and the torque applied to the drill string on the surface can cause the drill string to wind up. Depending on the amount of winding in the drill string, the drill string may encounter "stick-slip" operations, in which the steering assembly and drill temporarily interrupt stick rotation before starting abruptly again "slip". This sudden start can cause torque conditions on the drill, which can exceed the limits of the steering set.
    [0049] In certain embodiments, to take into account stick-slip conditions, the input data 602 can include measurements from which the number of windings in a drill string can be calculated and operating restrictions 604 can include limits on the number of acceptable windings to avoid stick-slip conditions. Specifically, the input data 602 may include tool face angle measurements from at least one tool face sensor attached to the downhole at or near the BHA and on the surface and at least one tool face sensor attached to a portion of the drill string on or near the surface. By comparing the tool face angle of the steering set with the tool face angle of the drill set on the surface, the amount of winding in the drill string can be calculated by the 600 controller. The 600 controller can then , compare the calculated amount of winding with the operating restriction, and if the number of windings is outside the operating restriction, controller 600 can generate one or more control signals to change the drilling parameters that will affect the amount of winding. For example, controller 600 can issue a control signal to change the WOB, TOB and/or slew rate, all of which can change the amount of windings in the drill string.
    [0050] FIG. 7 is a graph illustrating an example of operating restriction that corresponds to windings in a drill string, in accordance with aspects of the present disclosure. Graph 700 represents the amount of drill string windings on the X-axis with time on the y-axis and illustrates the potential amount of windings for different usage conditions. The 701 portion of the 700 graph reflects a usage condition where the drill string is not rotating, in which case the amount of windings in the drill string may be at or close to zero. Portion 702 reflects a situation in which the drill string is rotating but the bit is not engaged in the formation. Portion 703 reflects a situation in which the drill string is rotating and the bit is engaged in the formation, but the number of windings is kept within operating restrictions 704. Although the number of windings may fluctuate in portion 703, the conditions of resulting torque in the drill and steering assembly can remain substantially constant within the operating limits of the steering assembly. In contrast, portion 705 reflects a portion when the number of windings is outside the 705 operating restrictions, leading to stick-slip conditions in which the number of windings and torque conditions in the steering assembly and drill changes dramatically and exceeds the targeting set limits.
    [0051] In addition to using the control system to keep an element of a drilling assembly within operating limits, the control system can also be used to optimize aspects of the drilling system. For example, the control system can be used in connection with a bit and the BHA to optimize the penetration rate of the drill assembly and to protect downhole elements. As a drill assembly drills through a formation, axial and torque forces applied to the drill can cause the drill to move through the hole in a swirl pattern, contacting the formation at different locations at the end of the hole. over time. This drill whirl decreases the penetration rate of the drill assembly due to the incompatible contact point with the formation. The vortex of the drill can also cause lateral vibration within the BHA above the drill, which can damage sensitive mechanical and electrical elements.
    [0052] In accordance with aspects of the present disclosure, operating constraints for one or more drilling parameters can be selected to reduce drill whirl and a control system similar to the control systems described above can issue the control signals to ensure that the drill assembly remains within operating restrictions. In relation to the drill vortex, the operating constraints can comprise the two-dimensional operating constraints in terms of WOB and rotation rate, which identifies the combinations of the WOB values and the rotation rates, in which the vortex and lateral vibration of the drill are minimized. FIG. 8 is a graph illustrating a stable operating region 800 between two unstable regions 801 and 802, represented in terms of WOB on the x-axis and rotational speed in RPM on the y-axis. Notably, not all drills, hole conditions and formation types will have the same stable and unstable ones, or such a distinctly stable operating zone, but similar operating constraints can be calculated using known drills, hole conditions, and drill types. training for a given drilling operation. When a particular combination of WOB and measured spin speed drilling parameters leaves stable region 800, a controller can issue control signals to change one or both of the spin speed and WOB drilling parameters until the system returns for stable region 800.
    [0053] Although the above systems are described in relation to the drilling system elements (for example, the hook assembly, pump, top unit, etc.) positioned on the surface and the modification or change of drilling parameters by issuing from the control signals to the surface drilling system elements, the control system can also be implemented in a closed loop system downhole, wherein the downhole elements receive the control signals from a downhole controller and change drilling parameters in response to control signals. Control systems can also be split between surface level and downhole elements, where some drilling parameters are adjusted at the surface and some at the downhole. In still other embodiments, certain drilling parameters can be adjusted, both at the surface and at the bottom of the well.
    [0054] FIG. 9 is a diagram of an example BHA capable of changing one or more drilling parameters, in accordance with aspects of the present disclosure. In the embodiment shown, the BHA 900 comprises an LWD/MWD 901 section, a controller 902, an impulse control unit 903, a downhole motor 904 and a drill 905. The controller 902 may be communicatively coupled to the controllers and/ or measuring devices 901a, 903a and 904a of the LWD/MWD section 901, impulse control unit (TCU) 903 and a downhole motor 904, respectively. Some of all controllers and/or measurement devices 901a, 903a, and 904a can communicate as measured drilling parameters of input data to controller 902. For example, controller and/or measurement devices 901a of LWD section /MWD 901 can measure a tool face angle of BHA 900, the controller and/or measurement devices 903a of the TCU 903 can measure the WOB and the controller and/or measurement device 904a of the downhole motor 904 can measure TOB and 904 drill rotation rate. The 902 controller can function similar to the control systems described above and can compare input data received from one or more operating constraints for the drill assembly. Operating restrictions may be stored downhole within controller 902 on a separate storage medium or within memory integrate within controller 902. Controller 902 may then generate control signals to one or more of the controllers and/ or measurement devices 901a, 903a and 904a of the LWD/MWD 901 section, the TCU 903 and the downhole motor 904, to change one or more drilling parameters.
    [0055] In the mode shown, the 904 downhole motor is responsible for driving the 905 drill and therefore can control the torque exerted on the 904 drill and the rotation rate of the 904 drill. The 904 downhole motor it can comprise, for example, an electric motor, a mud motor or a positive displacement motor. In the case where the downhole motor 904 comprises an electric motor, the torque and rotation rate of the drill 905 can be changed by varying the thrust level or power of the motor 904. downhole 904 comprises a mud motor or positive displacement motor, the rotation rate and torque applied to drill 905 may depend, in part, on the flow rate of drilling fluid through downhole motor 904. Therefore, the torque and rate of rotation applied to the drill including one or more bypass valves that can divert a portion of the drilling fluid either in a ring that surrounds the 904 wellbore motor or through the bottom motor of well 904 without contributing to the rotation of drill 905. In the examples, the controller and/or measuring device 904a can transmit signals to one or more electrical components (eg, diverter valves or electric motors) of the bottom motor. well 904 to change TOB and the rotation rate of drill 905.
    [0056] In certain embodiments, the impulse control unit 903 can be used to change the WOB. In the embodiment shown, the TCU 903 comprises extendable arms 906 which contact the wall of wellbore 907. Extendable arms 906 may be powered by a clean oil and pump system (not shown) within the TCU 903 or may be fed using drilling mud flowing through the BHA 900. The TCU 903 can comprise an anchoring section 903b from which the extendable arms 906 are coupled and a thrust section 903c to which the anchoring section can impose an axial force . Similar to the 906 extender arms, axial force can be provided by a clean oil system and pump located on the TCU 903.
    [0057] The thrust section 903c can be coupled to the downhole motor 904 and the axial force transmitted to the thrust section 903c by the anchor section can be transferred to the downhole motor 904 and drill 905. , the WOB can be changed by changing the axial force transmitted to the thrust section 903c. As drilling progresses, extendible arms 906 can be fully or partially retracted, disengaging with hole 907 and allowing arms 906 to extend and readjust to a lower position in hole 906 to maintain a constant WOB. Similar to the 904 downhole motor, the control and/or measuring device 903a of the TCU 903 can transmit the signals to one or more components (eg pumps and valves) of the TCU 903 to change the WOB when requested by a controller control signal 902.
    [0058] In an alternative embodiment, the thrust section 903 may comprise extendable arms, each with one or more rails that grip the wall of hole 907. The rails may comprise tank-like rails with continuously rotating rails. Instead of using the extendable arms that anchor against the wall of hole 907 and separate the anchor and thrust sections 903b and 903c, the rails can apply a constant axial downward force on drill 905 without having to retract and readjust. Other modalities would be observed by one skilled in the art in view of the present disclosure. For example, the WOB could also be varied by controlling a piston attached to the drill string, such as in the Reelwell™ system, which interacts with the liner or casing to create a piston thrust force in the drill string through equipment surface hydraulics.
    [0059] To assist the TCU 903, real-time or recorded data from previous measurements, both in the current well and in the offset wells, can be used to determine the mechanical properties of the formation, such as a compressive strength and profile. hole wall tension 907. An earth model stored in the system can be updated based on measurements located at or near the TCU 903 to refine the existing model and thereby improve the predictive ability of formation characteristics. For example, if the extension distance of the extendable arms 906 is measured by the system for a given force the elastic constant of the formation and, therefore, the compressive strength can be determined. If the overall compressive strength gradient is increasing or decreasing in the area of hole 907 at a different rate than that of displacement data from a nearby well, updating the earth model will assist in refining the ideal weight needed with a given drill and current sharpness of the drill to determine what the WOB limits should be for drilling.
    [0060] FIG. 10 is a diagram of an example TCU 1000, in accordance with aspects of the present disclosure. As can be seen, the TCU 1000 comprises an anchoring portion 1002 and a thrust portion 1004. One or more extendable arms 1006 may be coupled to anchoring portion 1002 and may engage with bore wall 1008. In the embodiment shown, thrust portion 1004 is coupled to clamping portion 1002 through spline 1010 and pistons 1012. Spline 1010 can keep thrust portion 1004 axially aligned within clamping portion 1002 and pistons 1012 can be used to impart an axial force to low in the 1004 thrust portion. Notably, the 1012 spools can be bi-directional with a long stroke length and fast response time for fine control of the WOB. In certain embodiments, a drill string can rotate within hole 1014 of the TCU 1000, allowing the TCU 1000 to be used when a drill is rotated from the surface through a top unit.
    [0061] Fig. 11 is a diagram of an example downhole engine 1100, in accordance with aspects of the present disclosure. Engine 1100 may comprise a positive displacement engine, an outer housing 1102 which may be coupled to other elements of a BHA. In certain embodiments the motor 1100 may comprise a rotor 1104 and a stator 1106, the rotor being coupled to a bit and driving the bit in response to a flow of drilling fluid through the motor 1100. In the embodiment shown, the motor comprises a diverter valve 1108, which can be opened to divert drilling fluid in the opposite direction from rotor 1104, away from motor 1100. In an alternative embodiment, the valve may divert fluid through rotor 1104 in such a way as to avoid the interface between rotor 1104 and stator 1106.
    [0062] The flow of drilling fluid between the rotor 1104 and the stator 1106 can create a differential pressure that creates a downward axial force on the rotor 1104, which can be transmitted from the rotor 1104 to the 1110 CV shaft and the shaft of support section 1112 for a drill (not shown). Rather than transmitting this axial force to housing 1102 as is typical with downhole motors, the bearing section may allow rotor 1104 to travel relative to stator 1106 and apply the axial force to the drill. Therefore, TOB, WOB and drill rotation rate can be changed by controlling the 1108 bypass valve.
    [0063] According to aspects of the present disclosure, an example method for controlling a drilling assembly may include receiving measurement data from the at least one sensor coupled to an element of the drilling assembly positioned in a formation. An operational constraint for at least a portion of the drill assembly can be determined based, at least in part, on a model of the formation and a set of displacement data. A control signal can be generated to change one or more drilling parameters of the drilling set based, at least in part, on the measurement data and the operating restriction. The control signal can be transmitted to a controllable element of the drilling assembly.
    [0064] In certain embodiments, generating the control signal to change one or more drilling parameters may comprise generating a control signal to change one or more of a weight-on-drill (WOB) parameter, a torque parameter -on-bit (TOB), a drill rotation rate, a drilling fluid flow rate, and a drill assembly tool element face angle. Receiving measurement data from at least one sensor may comprise receiving a first tool face angle measurement from a steering assembly; determining the operating restriction for at least the portion of the drill string may comprise determining upper and lower limits on the amount of windings in a drill string of the drill string; and generating the control signal for changing one or more drilling parameters of the drilling assembly may comprise determining an actual amount of windings based on the first tool face angle and a second tool face angle of a portion of the string of drilling near the surface, and generate a control signal to change one or more of the TOB, WOB, and drill rotation rate if the actual amount of winding goes outside the upper and lower limits.
    [0065] In certain embodiments, receiving measurement data from the at least sensor may comprise receiving a WOB measurement and a TOB measurement; determining the operating restriction for at least a portion of the drill assembly may comprise determining combinations of the WOB and TOB drilling parameters for the drill assembly that minimize the drill vortex; and generating the control signal for changing one or more drilling parameters of the drilling assembly may comprise generating the control signal for changing one or more of the drilling parameters of TOB and WOB such that the drilling parameters of TOB and WOB are changed comprise one of the combinations of TOB and WOB drilling parameters that minimize drill whirl. In any of the embodiments described above, transmitting the command signal to the controllable element of the drill assembly may comprise transmitting the control signal to at least one of a controllable element of the drill assembly positioned on a surface of the formation and a controllable element of the drill assembly positioned in the formation.
    [0066] In certain embodiments, the controllable element of the drilling assembly positioned on the surface may comprise at least one of a hook assembly, a pump and a top unit. In certain embodiments, the controllable element of the drilling assembly positioned in the formation may comprise at least one of a downhole motor and an impulse control unit. In such embodiments, the downhole engine may comprise a positive displacement mud engine and the thrust control unit may comprise at least one extendable arm for anchoring the thrust control unit against the formation.
    [0067] In any of the modalities described above, the example method may further comprise updating the model using the received measurement data if the received measurement data is not within a set of expected measurement data generated from the model and the displacement dataset, and determine the new operating constraints based, at least in part, on the updated model. Likewise, in any of the modalities described above, the example method may further comprise determining at least one drilling parameter of the drilling set based on the received measurement data and identifying a defect in one or more elements of the set based, at least in part, on the determined perforation parameter.
    [0068] According to aspects of the present disclosure, an example system for controlling a drilling assembly may comprise a sensor within a hole in a formation, a controllable element, and a processor communicatively coupled to the sensor and controllable element. The processor can be coupled to a memory device that contains a set of instructions that, when executed by the processor, causes the processor to receive the measurement data from the sensor; determining an operating constraint for the drill assembly based, at least in part, on a model of the formation and a set of displacement data; generating a control signal to change one or more drilling parameters of the drilling assembly based, at least in part, on the measurement data and the operating constraint; and transmitting a control signal to the controllable element.
    [0069] In certain embodiments, one or more drilling parameters may comprise at least one of a weight-on-drill (WOB) parameter, a torque-on-drill (TOB) parameter, a rotation rate of a drill , a drilling fluid flow rate and a tool face angle of the drill assembly element. In any of the embodiments described above, the processor and the controllable element may be at least partially within the bore and the controllable element may comprise at least one of a downhole motor and an impulse control unit. In certain embodiments, the downhole engine may comprise a positive displacement mud engine and the thrust control unit may comprise at least one extendable arm for anchoring the thrust control unit against the formation.
    [0070] In some of the above embodiments, the processor is positioned on a forming surface and the controllable element comprises at least one of a hook assembly, a pump and a top unit. The controllable element can be positioned on a forming surface; the processor may be located on either a forming surface or within the hole; and the instruction set which causes the processor to transmit the control signal to the controllable element may further cause the processor to transmit a first control signal to the controllable element and transmit a second control signal to a second controllable element within of the hole. In certain embodiments, the measurement data may comprise a first tool face angle measurement of a steering assembly to which the sensor is coupled; the operating restriction may include upper and lower limits on the amount of windings in a drill string of the drill assembly; and the set of instructions that cause the processor to generate the control signal can additionally cause the processor to determine an actual amount of windings based on the first tool face angle and a second tool face angle of a portion of the drill string near the surface and generate the control signal to change one or more of TOB, WOB and the drill rotation rate if the actual amount of windings goes outside the upper and lower limits.
    [0071] In certain embodiments, the measurement data may comprise a WOB measurement and a TOB measurement; the operating constraint may comprise combinations of WOB and TOB drilling parameters for the drill assembly that minimize drill vortex; and the set of instructions that cause the processor to further generate the control signal can cause the processor to generate the control signal to change one or more of the TOB and WOB piercing parameters so that the TOB piercing parameters and modified WOB comprise one of the combinations of WOB and TOB drilling parameters that minimize drill vortex. In certain embodiments, the instruction set may additionally cause the processor to update the model using the received measurement data, if the received measurement data is not within a set of expected measurement data generated from the model and of the displacement dataset and determine the new operating constraints based, at least in part, on the updated model. Likewise, in certain embodiments, the instruction set may additionally cause the processor to determine at least one puncturing parameter of the puncturing set based on the received measurement data; and identifying a defect in one or more piercing assembly elements based, at least in part, on the determined piercing parameter.
    [0072] Therefore, the present disclosure is well suited to achieve the aforementioned purposes and advantages, as well as those that are inherent thereto. The particular embodiments disclosed above are merely illustrative, as the present disclosure may be modified and practiced in different but equivalent ways by those skilled in the art who have benefited from the teachings herein. Furthermore, no limitations on the construction or design details shown in this document are intended, other than as described in the claims below. Thus, it is evident that the specific illustrative modalities disclosed above may be altered or modified and that all such variations are considered part of the scope and spirit of this disclosure. Furthermore, the terms in the claims have their clear and common meaning, unless otherwise explicitly and clearly defined by the patent holder. The undefined articles "a" or "an" as used in the claims is defined herein to mean one or more than one of the elements introduced.
    权利要求:
    Claims (20)
    [0001]
    1. Method for controlling a drilling assembly, characterized in that it comprises: - receiving measurement data from at least one sensor coupled to a drilling assembly element (112) positioned in a formation (106); - determining an operating constraint for at least a portion of the drilling set based at least in part on a formation model and a set of displacement data, the displacement data comprising current data recorded from of at least one of one or more rock types and one or more formation types with one or more drilling parameters, and the operating restriction being specific formation layer; - generating a control signal to change one or more drilling parameters of the drilling set (112) based, at least in part, on the measurement data and the operating restriction; - transmitting the control signal to a controllable element of the perforation assembly (112); - determining that the perforation assembly (112) has been crossed to a different layer; and - select the operating constraint associated with the different layer.
    [0002]
    2. Method according to claim 1, characterized in that generating a control signal for changing one or more drilling parameters comprises generating a control signal for changing one or more of a weight-in-drill parameter (WOB), a torque-on-bit (TOB) parameter, a rotation rate of a drill bit (118), a drilling fluid flow rate, and a tool face angle of the drill assembly element (112).
    [0003]
    3. Method according to claim 2, characterized in that: - receiving the measurement data from the at least one sensor comprises receiving a first tool face angle measurement of a steering assembly; - determining the operating restriction for at least a portion of the drill assembly (112) comprises determining upper and lower limits on the amount of windings in a drill string (114) of the drill assembly (112); and - generating the control signal for changing one or more drilling parameters of the drilling assembly (112) comprises: - determining a current amount of windings based on the first tool face angle and a second tool face angle of a portion of the drill string (114) near the surface (104); and - generate a control signal to change one or more of TOB, WOB and the rotation rate of the drill bit (118) if the actual amount of winding goes outside the upper and lower limits.
    [0004]
    4. Method according to claim 2, characterized in that: - receiving measurement data from the at least one sensor comprises receiving a WOB measurement and a TOB measurement; - determining the operating restriction for at least a portion of the drill assembly (112) comprises determining combinations of WOB and TOB drilling parameters for the drill assembly (112) that minimize the drill bit vortex (118); and - generating the control signal for changing one or more drilling parameters of the drilling assembly (112) comprises generating the control signal for changing one or more of the TOB and WOB drilling parameters so that the TOB drilling parameters and WOB comprise one of the combinations of WOB and TOB drilling parameters that minimize drill bit vortex (118).
    [0005]
    5. Method according to any one of claims 1 to 4, characterized in that transmitting the command signal to the controllable element of the drilling assembly (112) comprises transmitting the control signal to at least one of a controllable perforation assembly element (112) positioned on a forming surface (104) and a controllable perforation assembly element (112) positioned on the formation.
    [0006]
    6. Method according to claim 5, characterized in that the controllable element of the perforation assembly (112) positioned on the surface (104) comprises at least one of a hook assembly (138), a pump (130 ), and a top unit.
    [0007]
    7. Method according to claim 5 or 6, characterized in that the controllable element of the drilling assembly (112) positioned in the formation comprises at least one of a downhole motor (904, 1100) and a impulse control unit (903).
    [0008]
    8. Method according to claim 7, characterized in that: - the downhole motor (904, 1100) comprises a positive displacement slurry motor; and - the impulse control unit (903) comprises at least one extendable arm for anchoring the impulse control unit (903) against the formation.
    [0009]
    9. Method according to any one of claims 1 to 8, characterized in that it further comprises: - updating the model using the measurement data received if the measurement data received is not within a measurement data set expected generated from the model and displacement dataset; and - determine new operating restrictions based, at least in part, on the updated model.
    [0010]
    10. Method according to any one of claims 1 to 9, characterized in that it further comprises: - determining at least one drilling parameter of the drilling set (112) based on the received measurement data; and - identifying a defect in one or more elements of the perforation assembly (112) based, at least in part, on the determined perforation parameter.
    [0011]
    11. System for controlling a drilling assembly, characterized in that it comprises: - a sensor inside a hole in a formation; - a controllable element; and - a processor communicatively coupled to the sensor and the controllable element, the processor coupled to a memory device containing a set of instructions which, when executed by the processor, causes the processor to: - receive measurement data from the sensor; - determine an operating constraint for the drilling set (112) based, at least in part, on a formation model and a set of displacement data, the displacement comprising current data recorded from at least one operation a drilling that correlates at least one or more rock types and one or more formation types with one or more drilling parameters, and the operating constraint being specific formation layer; - generates a control signal to change one or more drilling parameters of the drilling set (112) based, at least in part, on the measurement data and the operating restriction; and - transmit the control signal to the controllable element; - determining that the perforation assembly (112) has been crossed to a different layer; and - select the operating constraint associated with the different layer.
    [0012]
    12. System according to claim 11, characterized in that one or more drilling parameters comprise at least one of a weight-on-drill (WOB) parameter, a torque-on-drill (TOB) parameter, a rotation rate of a drill bit (118), a flow rate of drilling fluid, and a tool face angle of the drill assembly element (112).
    [0013]
    13. System according to claim 11 or 12, characterized in that: - the processor and the controllable element are, at least partially, inside the hole; and - the controllable element comprises at least one of a downhole motor (904, 1100) and an impulse control unit (903).
    [0014]
    14. System according to claim 13, characterized in that: - the downhole engine (904, 1100) comprises a positive displacement slurry engine; - the impulse control unit (903) comprises at least one extendable arm for anchoring the impulse control unit (903) against the formation.
    [0015]
    15. System according to any one of claims 11 or 12, characterized in that: - the processor is positioned at a surface (104) of the formation; and - the controllable element comprises at least one of a hook assembly (138), a pump (130) and a top unit.
    [0016]
    16. System according to any one of claims 11 or 12, characterized in that: - the controllable element is positioned at a surface (104) of the formation; - the processor is located on either a surface of the formation or inside the hole; and - the instruction set which causes the processor to transmit the control signal to the controllable element further causes the processor to: - transmit a first control signal to the controllable element; and - transmit a second control signal to a second controllable element within the hole.
    [0017]
    17. System according to claim 12, characterized in that: - the measurement data comprise a first tool face angle measurement of a steering assembly to which the sensor is coupled; - the operational restriction comprises upper and lower limits on the amount of windings in a drill string (114) of the drill assembly (112); and - the set of instructions that cause the processor to generate the control signal further causes the processor to: - determine an actual amount of windings based on the first tool face angle and a second tool face angle tooling a portion of the drill string (114) near the surface (104); and - generate a control signal to change one or more of TOB, WOB and the rotation rate of the drill bit (118) if the actual amount of winding goes outside the upper and lower limits.
    [0018]
    18. System according to claim 12, characterized in that: - the measurement data comprise a WOB measurement and a TOB measurement; - the operating constraint comprises combinations of WOB and TOB drilling parameters for the drill assembly (112) that minimize the drill bit vortex (118); and - the instruction set that causes the processor to generate the control signal further causes the processor to generate the control signal to change one or more of the TOB and WOB piercing parameters so that the piercing parameters TOB and WOB comprise one of the combinations of WOB and TOB drilling parameters that minimize drill bit vortex (118).
    [0019]
    19. System according to any one of claims 11 to 18, characterized in that the set of instructions causes the processor to still: - update the model using the received measurement data if the received measurement data is not within a set of expected measurement data generated from the model and the displacement data set; and - determine new operating constraints based, at least in part, on the updated model.
    [0020]
    20. System according to any one of claims 11 to 19, characterized in that the set of instructions causes the processor to still: - determine at least one perforation parameter of the perforation set (112) on the basis of in the measurement data received; and - identifies a defect in one or more elements of the perforation assembly (112) based, at least in part, on the determined perforation parameter.
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    同族专利:
    公开号 | 公开日
    GB2537259B|2020-06-24|
    CN105683498A|2016-06-15|
    AU2013408249A1|2016-05-26|
    RU2639219C2|2017-12-20|
    RU2016117319A|2017-11-13|
    US10907465B2|2021-02-02|
    NO20160809A1|2016-05-12|
    MX2016006626A|2016-12-16|
    US20150369030A1|2015-12-24|
    CA2931099C|2019-03-26|
    AU2013408249B2|2017-04-13|
    WO2015094320A1|2015-06-25|
    GB2537259A|2016-10-12|
    CA2931099A1|2015-06-25|
    BR112016010704A2|2017-08-08|
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    法律状态:
    2020-03-31| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2021-04-27| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-07-06| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 20/12/2013, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    PCT/US2013/076802|WO2015094320A1|2013-12-20|2013-12-20|Closed-loop drilling parameter control|
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