巴西专利BR112012015949B1 frontal sensing apparatus and automated methods of operation of frontal sensing tool, formation asse

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专利摘要:
FRONT SENSING APPARATUS AND AUTOMATED METHODS OF OPERATING FRONT SENSING TOOLS, EVALUATION OF FORMATION AND EVALUATION CONTROL, WELL CONTROL, OPTIMIZED PRESSURE DRILLING, ACTIVATION AND DEACTIVATION AND USE OF FRONT SENSORY APPLIANCE MAKE REFERENCE MEASUREMENTS TO ESTABLISH BACKGROUND NOISE. Apparatus, tool and method for evaluating advance formation of frontal sensing which investigates formation or formation characteristics in advance of the drill bit before the formation or formation feature of interest has been penetrated or traversed. A closed-loop real-time forward sensing formation evaluation tool that provides acoustic and/or electromagnetic formation data beyond the drill bit using a new angular sensor orientation that also allows for optimized signal propagation and signal signal returns. according to an axial plane and vertical depth.
公开号:BR112012015949B1
申请号:R112012015949-6
申请日:2010-12-10
公开日:2021-04-20
发明作者:Wajid Rasheed
申请人:Wajid Rasheed；
IPC主号:

专利说明:

DESCRIPTIVE REPORT FIELD OF THE INVENTION
[001] This invention relates to an apparatus or tool for evaluating formation of forward or early sensing during drilling that is capable of evaluating the characteristics of the well and formation ahead of a drill bit or directional control system tubular, especially for use in wellbore in the oil and gas industry. The device and the tool find particular use in the characterization of formations and their geophysical and petrophysical resources, mainly using ultrasonic means, but they can also be configured with electromagnetic sensors to provide other types of characterization within the well.
[002] On average, 65% of hydrocarbons are left underground, this equates to a 35% recovery rate. A front sensing profiling tool could potentially help increase recovery rates. It should be understood that the term "front sensing" as used herein refers to the ability of the invention to evaluate the formation according to a determined angular orientation and thus define a formation or formation feature within a 3D cone of investigation that extends from the tool at a given angle and reaches a given true axial and vertical depth in front of the drill. In contrast, prior art profiling tools are differentiated as behind the drill. The present invention has as a main objective a capability of “front sensing to investigate formations ahead of the drill that distinguishes it from the prior art. The tool itself can also be configured with stabilization or directional control features, such as a rotating orientable, without necessarily affecting the means of investigation.
[003] Other aspects of the invention include a method of operating a front sensing apparatus or tool to determine formations ahead of the drill bit or before the formations are penetrated and thereby increasing hydrocarbon recovery factors by optimally placing the drilling wells; a method of focusing signal orientation angularly, axially and vertically ahead of a drill bit; a method of focusing signal propagation angularly, axially and vertically ahead of a drill bit; an optimized detection zone and use of additional sources, receivers or transducers housed in a drill bit together with the apparatus or tool. In another aspect, the invention relates to an apparatus for controlling the logging and placement operation of the well in real time.
[004] Although sonic investigation is a main route to characterize certain formations and their characteristics, the invention is not limited to acoustic means. An additional modality is provided with additional investigative means similarly integrated with the tool's front sensing capability. These additional means can include electromagnetic waves suitably combined with acoustic measurements for better well placement. Such a combination will allow acoustic or porosity measurements to be correlated with resistance or conductivity measurements for oil, gas and water zone identification.
[005] When deciding the optimal trajectory and placement of an exploration or production well, numerous activities within the well are carried out to ensure the greatest recovery of hydrocarbons and minimize water production during the lifetime of the well. Geophysical data such as formation porosity, permeability, oil, water, gas contact zones, formation beds and depressions are required to guide the well to its best location. A variety of drilling logging technologies, such as neutron density, gamma ray, resistivity and acoustic investigation tools, are commonly used to identify formations and assess their characteristics. (Figure 1).
[006] The present invention details an embodiment of a sound-based training evaluation tool, which can be configured as a single tool, housing or module or multiple tools, housings or modules as an apparatus optimally located along a column of drilling to form an improved logging measurement based on projecting an acoustic or electromagnetic signal ahead of the drill bit, reflecting back to a receiver, and thus achieving the aim of the invention, which is to evaluate formation before she has been penetrated.
[007] Several types of sound-based investigation tools exist, such as passive seismic, which record natural seismic events, active seismic events that generate and record sound waves from artificial sources, and those known as acoustic (below 20,000 Hz) and those known as ultrasonic (above 20,000 Hz). It is understood that the term “acoustic” can encompass other frequencies or ultrasonics.
[008] Seismic tools provide large-scale geological data, however, these have low resolution of formation details and the drilling itself is the true test of geophysical formation characteristics. Therefore, there is a need and reliance on acoustic tools during real-time drilling. These tools use transducers or sources to create high-frequency sound waves that propagate as shear or pressure waves in solids and liquids, respectively. Sound waves are further classified as those traveling inside the wellbore (Stoneley waves), close to the formation (bending waves) and away from the formation (body waves). Through an evaluation of the echo pulse, its maximum and minimum, which are received back by the sensor/receiver, and derivations thereof, calculations can be made as for the time interval between signal transmission and echo profiling to determine the distance to an object or feature of the formation. Furthermore, using algorithms of various characteristics, such as formation density, empty spaces, fluid saturations, fluid trapping and formation direction changes, such as beds or depressions, all have defined velocity signatures that correspond to their capacity reflective.
[009] In all these applications, the prior art suffers from two main limitations (Figures 2, 90, 100). First, sensors that can be defined as sources and receivers or transducers in any configuration are located far behind the drill for quick formation assessment (100). The distances [30 meters (100 feet] or more) between the sensors and the drill bit restrict the formation assessment to the area closest to the sensor, which is always in the zone that has already been penetrated and drilled because it is behind the drill bit. Second, the orientation of such sensors and the propagation of their acoustic pulses are lateral (90). This severely limits the signal focus to allow only orthogonal investigation (Fig. 2). Even where signal propagation is increased due to a plurality of receiver sensor sets or due to deeper readings, the distance between such arrays and the drill bit remains substantially unchanged, so formations are only evaluated after they have been drilled. Thus, the prior art can only provide the subsequent assessment of the perforation formation. This is unsatisfactory as it prevents optimal wellbore placement due to late arrival of formation data after wellbore placement has already taken place.
[0010] The measurement may involve the acquisition and communication to the surface of various types of well data, such as resistivity, porosity, permeability, azimuth, slope and well diameter or roughness, formation dips or stratification angles.
[0011] The measurement itself takes place in two modes, either with wire rope or profiling during drilling. Wire rope drilling is carried out as a separate and consecutive activity to drilling involving the transport of measuring instruments on a wire or cable. Wire rope forming tools generally cannot be rotated and are not used in the application during drilling for this reason.
[0012] The logging tools during drilling acquire various data from the well. Acoustic or ultrasound tools can be integrated with profiling tools. As they can be rotated, such tools can be used during drilling to acquire sonic measurement data. However, they are restricted in terms of depth, placement and investigation (Figure 2). Placement is restricted due to directional control system requirements, such as a rotatable steerable or steerable motor, which need to be configured close to the drill bit in order to provide deflection forces or guidance for the drill bit. Therefore, the location of the acoustic tool is within the BHA above the directional control system (Figure 3). Furthermore, the acoustic tool can be placed behind other profiling tools, which are numerous. These include Neutron Density, Resistivity, Gamma Ray. The cumulative distance of such profiling tools can exceed 100’ (30m) behind the drill bit and these tools can only take readings after the section has been drilled. Often, the sonic tool itself is 36’ (10m) long.
[0013] The sonic tools group echo pulses in flight time to identify a given formation or interval transit time, designated "õt". Each formation has a sonic velocity or signature that is a measure of a formation's ability to transmit sound waves. Formation lithology, compressive strength and rock types, notably, porosity or voids within the rock matrix have a great influence on sonic velocities. In porous rocks there is a higher percentage of empty space containing fluids that alter the sonic displacement time, compared to a rock that has no empty space at all. Sonic tools in this way measure displacement time and many equations can be solved using displacement time derivatives and relationships. These include the average time equation which has total displacement time dependent on the time the sound wave spends traveling to the solid part of the rock, called the rock matrix, and the time spent traveling through the fluids in the hollow part of the rock. , called pores.
[0014] Measurements of acoustic formation or ultrasound strongly depend on the lateral orientation of acoustic sensors. Typically, in an attempt to increase the depth of investigation as well as create a wider investigation zone, it is routine for prior art acoustic sensors and receivers to be placed in consecutive arrays. Regardless of the number of dies, this approach does not solve the problem of being ahead of the drill bit, as measurements are taken from considerable distances behind the drill bit or after the drilling has completed the well path.
[0015] In the event that a hydrocarbon production zone has been bypassed or left behind, there is a retrospective time lag between the data being received showing where the hydrocarbons are located and the subsequent correction of the wellbore placement. Often the time delay leads to uncertainty, additional costs and can be accompanied by a loss of production as hydrocarbons are diverted or the best heel-to-tip configuration within a low permeability zone is lost. In the case of producing zones, characterization takes place only after drilling and the area has been traversed, which means that the reservoir's zone of interest can be left behind and additional correction drilling must take place to place the well hole in the zone of desired interest. Such delayed formation data cycles and subsequent corrections can be eliminated with the present invention. BACKGROUND OF THE INVENTION
[0016] Geological mapping and geophysical surveys allow oil companies to characterize their acquired lands and the age and sedimentation patterns of the rock formation contained therein. This characterization process can be reconstructed as a visual earth model that delineates the position and shape of the structure, including anticlines, stratigraphic faults, which structure helps to increase the production of subsequent wells and the field as a whole. However, the land model and well plan have inherent uncertainties.
[0017] The geological uncertainties and challenges are related to the location of hydrocarbons, water contacts, traps, formation stresses, movements and porosity and permeability of the reservoir. To overcome these challenges, a highly detailed well plan is developed, which contains the well objective, coordinates, legal, geological, technical and well engineering data and calculations. To resolve the uncertainties, however, drilling is the ultimate test.
[0018] The data is used to accurately trace a drillhole profile, which is drawn in consecutive telescopic sections - surface, intermediate and reservoir. To accomplish the well purpose and maintain the well's integrity over the life cycle, a given well path with various sections and diameters is drilled from the surface. While there are many variants, a simple vertical well design could include a surface or top hole diameter of 445mm (1772”), 360mm (13 5/8”) and 245mm (9 5/8”) intermediate sections. ”) narrowing to the bottom hole diameter of 216mm (87”) in the reservoir section.
[0019] Oil and gas shortages are leading oil and gas companies to explore and develop reserves in more basins, such as those in water at depths greater than 1,830m (6,000 feet) or sections below the salt mass. These wells have highly complex directional trajectories and highly sophisticated formation assessment requirements. Known in the prior art as “3D designer” wells, these wells have highly complex trajectories, due to the need to access multiple reservoirs with a single wellbore, as well as the configuration of hydrocarbon reservoirs. The 3D wells and horizontal wells created a need for “geo-orientation” of the well to avoid bypassing the production reservoir zones and orienting the well to the ideal production zone. On average 65% of hydrocarbons are left underground, this equates to a 35% recovery rate. A front sensing profiling tool potentially helps to increase recovery rates.
[0020] Therefore, the background compositions that are required for drilling these wells routinely include acoustic, sonic profiling or other sound-based devices to characterize the formations. As such, logging is an integral part of well construction and there is now greater reliance on logging for well placement and formation assessment.
[0021] Previously, the ultrasonic and electromagnetic tool had been restricted in its placement above the drill bit and limited to only taking lateral measurements. Typically, the distance would be about 30 meters (100 feet) behind the drill bit, meaning that formation data would only be provided after the formation has been penetrated or traversed. Therefore, the drill bit may have moved out of the zone of interest and the well could have been diverted back to the ideal location. If critical knowledge of the formation, i.e. reservoir structures, fractures, beds or depressions and fluids contained therein can be acquired in advance before being drilled, this would lead to higher recovery rates due to more effective well placement, increasing footage perforated real in the area of interest.
[0022] In other applications, such as gas zone, kick detection, pore pressure analysis or fracture identification, tolerances between programmed parameters and actual parameters of wells can be very close and variations of 0, 02 kg/l (0.2 ppg) can lead to well failure or loss. By being able to detect a kick or establish a fracture before it is actually drilled, corrective drilling measures can be taken in advance saving time, money and providing a significant margin of safety.
[0023] As far as the prior art is concerned, there are three generic approaches that have been unsuccessfully attempted to overcome the limitations of acoustic profiling. First, it is routine to move sensors closer to the well to achieve greater lateral proximity or even to create contact with the well wall. Second, to increase the number of consecutive source and receiver arrays. Lastly to deflect signals for training. The prior art has not dealt with the fundamental problem of directing the acoustic source or the electromagnetic signal to look ahead of the drill bit or reduce the distance to the drill bit.
[0024] The technique is limited as it relies on measurements perpendicular to the tool axis orientations, or lateral or orthogonal that cannot see beyond the tool itself, regardless of longitudinal or angular depth. Furthermore, signal transmission and signal propagation is limited to small investigation depths, usually no more than a few meters. Lastly, prior art positioning at significant distances behind the drill bit creates additional constraints as the depth of investigation is severely limited to an area that has already been drilled. Therefore, drilling has been carried out and the trajectory of the drilling well has already been achieved. These data acquired at this time are after the event data and the drilling assumption is always that the current trend of the formation or bed should continue. There are no actual measurements either direct or inferred until after the drill bit has penetrated a formation and the logging tools have traversed said formation.
[0025] It is unsatisfactory to depend on the placement of source or source, the placement of receiver that is lateral, orthogonal or perpendicular to the tool axis. These placements do not provide formation measurements beyond close to the well, nor do they provide forward sensing data; they simply give information about geology or formations that have already been drilled, and when it is too late to achieve a desired ideal trajectory. In this way, there is the constant cycle of steering tools to maintain the well slope or azimuth.
[0026] For those skilled in the art it is known that the industry relies on delayed drill bit data, which may be 30 meters (100 feet) or more behind the bit.
[0027] Therefore, the state of the art itself does not provide reliable or certain means of investigating the frontal sensing of formations during or immediately before their drilling.
[0028] In addition, the state of the art generates lengthy cycles of correction of changes in azimuth and inclination in an attempt to retrospectively maintain a better path of the well.
[0029] In addition, the state of the art contributes to an average and unsatisfactory recovery rate of 35% of hydrocarbons as the reserves are not ideally located.
[0030] Furthermore, the prior art does not detect variations in formations ahead of the drill in real time.
[0031] In addition, the prior art does not detect variations in formation characteristics such as porosity or fluid content ahead of the drill in real time.
[0032] In addition, the state of the art does not detect gas zones, fractures or water flow in front of the drill or wellbore in real time.
[0033] In addition, the state of the art does not detect temperature or pressure variations ahead of the drill or wellbore in real time.
[0034] In addition, the state of the art does not automatically allow a closed connection or automatic location of defects in the placement of the well path. SUMMARY OF THE INVENTION
[0035] The main object of the present invention is to provide an improvement over the state of the art in which the formation or formation characteristic is investigated in advance, that is to say simultaneously with, or immediately after, or immediately before the drilling starts, but at all times, in front of the drill bit, before the formation or formation feature of interest has been penetrated or traversed.
[0036] The present invention optimally orients sources and receivers or transducers which, in addition, can be placed much closer to the drill or within the drill itself and propagate signals ahead of the drill to formations that have not yet been penetrated or traversed. Data communication can be achieved via a pulsed signal in mud or other wireless or wired transmission to ensure it is received at the surface in real time and the well path can be optimized.
[0037] The invention aims to meet the need for a closed-loop real-time front sensing formation evaluation tool, which provides real-time formation data in addition to the drill bit. This has not been the case in the prior art behind the drill bit due to design limitations inherent in sensor placement, orientation or the localized distance from the bit.
[0038] The present invention seeks to directly investigate formations ahead of the drill and offer the best placement of the well using a new angular/longitudinal source, receiver or transducer orientation that also allows optimized signal propagation and return signal, according to a axial plane and vertical depth.
[0039] The present invention eliminates the uncertainty of post-drilling investigation and eliminates the need for correction of directional passes and consequent tortuosity of the well by providing real-time data, which allows the driller to respond much earlier to formation characteristics, increasing, thus, the recovery factors, saving time and money.
[0040] It is therefore an objective of the present invention to provide acoustic formation assessment tools with front sensing means allowing the device to obtain immediate assessment of a formation to be drilled or the characteristics of a formation yet to be drilled and, if the tool detects a parameter of interest or a change in a parameter of interest, such as porosity, failure or gas zone, automatically calculates and corrects for a better well path, and repeats the assessment until such resulting best well path is reached in real time.
[0041] Although sonic investigation is a main way to characterize certain formations and their characteristics, the invention is not limited to acoustic means and provides another modality with additional resistivity investigation means similarly integrated with the frontal sensing capability of the tool . These additional means can include electromagnetic waves suitably combined with acoustic measurements for optimal drillhole placement. This combination will allow acoustic or porosity measurements to be correlated with resistance or conductivity measurements for oil, gas and water identification zone.
[0042] It is another objective of the present invention to provide a tool capable of simultaneously observing ahead of the drill bit taking sonic investigation measurements, preferably by an acoustic source and a receiver or a transducer, and verifying such measurements through an arrangement processor that uses such sonic measurements to detect the formation parameters of interest and conduct the diagnosis, according to a logic circuit, in order to ensure that the well path is optimized, taking into account the investigated measurement data. If a parameter of interest is detected, the processor will automatically detect if corrective measures are needed to guide/maintain the well in the optimal zone. If the tool encounters a significant azimuthal or tilt deviation, a signal can be sent to the surface equipment or to the operational engineer's location so that further measurements can be taken, such as coordinate revisions. A memory mode can store sensor information that can be downloaded to the surface when the tool is retrieved or sent to the surface by telemetry. The tool may also have an internal link to a pulse mud telemetry system to allow real-time monitoring of the formation yet to be penetrated.
[0043] One or more sources and receivers or transducers may be optimally spaced in a forward angular or longitudinal orientation in order to emit at least one sound wave in front of the drill bit or in front of a directional control system or in front of a pipe over a given period of time, part of which is reflected back by the formation.
[0044] A keyway can provide a channel for wiring the sensors to the processor and transponder. Wiring can be used to transmit acoustic data retrieved by the acoustic sensors, as well as positional and structural data of formation features and their relative distance from the tool and drill bit. The keyway can be sealed and filled with a means to absorb vibration such as silicone gel or grease and to hold the wires in place. Likewise, keyways can be left redundant and as a support for a wireless mode of operation.
[0045] The transponder converts the formation data so that it can be transmitted and is connected to the mud pulse generator, which transmits the data to the surface using a series of binary codes at a given frequency using drilling fluid as a means of pulsation of mud. Other data transfer means can be used, such as short wireless transmission using radio frequency or electromagnetic pulses or wired drill pipe. This allows upper and lower tool linkage in order to receive and transmit data and commands in order to optimize wellbore placement before formations are traversed.
[0046] On the surface, a transducer can be incorporated within a decoder housing, which decodes the binary code and can connect to the drilling terminal or can be further transmitted by satellite or other means to a remote operations center.
[0047] These and other objectives will emerge from the following description and the attached Claims.
[0048] In one aspect, the front sensing apparatus (50) comprises at least one tool body with means for securing the tool body (63) directly or indirectly to a drill bit or holder, whereby it can be rotated and moved axially along a passage (20) and is characterized by at least one profiled element (58) that houses at least one receiver source, or a transducer that is outwardly disposed and projects forward to a angle of at least 0.25° or as much as 89.75° 5 (Figure 5) with respect to the horizontal axis of the tool, and (57) is adapted to transmit sound and recognize acoustic velocity signatures of a formation (70 ) or a feature of a formation (110, 120, 130, 140) and thus increase hydrocarbon recovery rates by optimizing the well path based on formation data acquired by the receiver or transducer before, during or after a drilling operation, but occurs at all times before a formation or formation feature has been penetrated by the drill bit (70).
[0049] The support may typically be a drill string (30) or an extended length of coiled tubing connected through the tool to a drill bit, such as used in oil and gas field well operations.
[0050] In preferred embodiments of the invention, the investigation operation is based on the acoustic source, receivers or transducer elements comprising a set of at least one source, combination of receiver or transducer optimally configured and oriented to send sound waves to in addition to a drill bit and receive acoustic velocity signatures. The tool can be directly or indirectly linked to a drill bit depending on requirements. The source, receiver or a transducer housed may comprise a protective cover, which may be of similar construction to the source of receiver, or a transducer but having outer surfaces that are protected by a hardened material. The shield can simply withstand pressure, temperature or flow acting against them from within a wellbore. In an alternative embodiment, the zone around the housing can be treated to actively receive echo pulses that make it a detection zone that allows for formation evaluation method, which uses the treated zone to actively send or receive echo pulses.
[0051] Sources, receivers or transducers can be provided with a lens surface that can be convex (52a), concave (52b), or planar (52c), as per the requirement. Sources, receivers and transducers can be optimally tuned and frequency-closed so that the emitted frequencies do not vanish in contact with the return waves and so reference measurements are taken to establish the background noise that would be properly excluded from operational time-of-flight calculations. Alternatively, the same sources, receivers and transducers may be received within an additional section of the tool or a separate steel body or behind or in front of such section suitably prepared to provide a means of stabilization or centering and protection for drilling applications . Other sources, receivers or transducers may be equipped with a means to reduce “buzz” or “dampening” of sound waves to ensure that the tool is always fit for purpose.
[0052] It should be noted that the description here of the structure and functioning of sources, receivers and transducers and tool model is generally applicable regardless of function, except to the extent that acoustic sources, receivers or transducers may be specifically provided for formation of evaluation purposes and replaced by other sensors, such as resistivity sensors, as required by the drilling operation.
[0053] The tool body is typically a cylindrical housing of high grade steel adapted to form part of the bottom composition (BHA). Thus, the means for securing the tool body to the holder, whether it is a drill string or spiral pipe, may comprise a screw thread provided on the tool body, which is engageable with a drill collar. The fixture for the drill string does not need to be direct but can be indirect as there will typically be several functional elements to be included in the long and narrow BHA, and the arrangement of successive elements may vary. The lower end of the BHA can be the drill bit which can be attached directly to the tool and between them there may or may not be a means for directional control, such as a steerable rotary system or directional motor. The tool body may be provided with a passage through the flow of drilling fluid from the drill string.
[0054] Sources, receivers and transducers can be shielded and housed in a plurality of angular depth orientations directed outwardly of a profiled tool body and at all times before the drill bit. Sources, receivers and transducers may be received within the tool body profile in a recess in the source, receiver and transducer suitably protected from abrasion wear, and damage by means of at least one protective coating or cover. Steel protective coating can be with HVOF, tungsten carbide, nickel boron or other protection as per requirements. The source, receiver and transducer can be provided with a damping material or mechanism such as silicone gel or a spring.
[0055] The source and the receiver or the transducer can then be provided with means for conducting the sound pulses and receiving the echoes from the formation far away, close to the formation or well. The microprocessor control means can be adapted to receive training data from the source of the receiver, or a transducer, and to control the frequency in response thereto. A switching procedure can be conveniently incorporated to rule out a range of noise frequencies either by establishing a maximum reference measurement and engaged with such a maximum or by establishing a measurement and engaged with such a measurement.
[0056] Pressure compensation can be provided to handle pressure variations within the well compared to atmospheric conditions of surfaces where activation is opposed by external pressure. This may comprise a port from a source of drilling fluid to a chamber suitably connected to the area inside the tool requiring pressure compensation (not shown).
[0057] The system may comprise microprocessor means for monitoring formation evaluation data and the relative positions of formation structures wherein the microprocessor means may include a means of automatically anticipating any formation or detection of a characteristic of a formation or detecting a change in the characteristic of a formation, thereby guiding the directional control system to ensure optimal drillhole trajectory and placement.
[0058] The tool typically comprises a plurality of sources and receivers arranged symmetrically around the tool and arranged outwardly in angular orientations. The source and receiver can be configured as an integral transducer or separate as a source to the receiver. Two transducers would be on opposite sides of the tool, three transducers would be 120 degrees apart, four by 90 degrees and six by 60 degrees. Multiple tool bodies with sources and receivers can be combined along longitudinal BHA BHA or wellbore spacings to ensure that the pulsed investigation zone and echo capture zone are optimised. In operation, the front sensing apparatus or tool is typically rotated in the drill string as well as being moved axially along the drillhole.
[0059] In accordance with a particularly preferred aspect of the invention, the transducer or source and receiver array is provided with an internal keyway for directing energy from a source within the tool and providing communications to and from the sensor receiver. The power source may be a battery within the tool or within another tool holder suitably adapted for the purpose. The communications may be a processor within the tool, or on the surface or other support for the tool suitably adapted for the purpose. Alternatively or additionally, the source, receiver and transducer or tool body may be provided with a wireless communication means to an internal or external processor. In each case, bidirectional communications provide data transmission, operational refinement, and data capture.
[0060] In order to keep the source, receiver, or transducer clean and prevent the accumulation of clogging debris, the drilling operation, the source, receiver or transducer housed may be provided with a specialized coating to minimize residence or remove such materials entirely from the source, receiver or transducer.
[0061] In an embodiment of the present invention incorporates an optimally oriented and spaced sound means based on training assessment means that is practically applicable and may be ultrasound.
[0062] In another modality of front acoustic sensing tool housing for other types of sensors, such as electromagnetic, is provided within the profile that offers a robust and ideal location. This has not been possible with prior tools due to their inherent design limitations which rely on orientations that are lateral, orthogonal or perpendicular to the tool axis.
[0063] The tool may further comprise telemetry data communication means within the well and control signals between the tool and a surface interface, which may, among other functions, control the drill string during the formation evaluation operation .
[0064] In another aspect, the invention provides a method of operating a recording apparatus or tool for investigating a formation or parameter of interest ahead of a directional tool or drill bit or the like to guide and optimally place a drillhole , which comprises locating a tool according to the invention inside the well on a support behind a drill bit, activating the source, receivers or transducers to receive sonic reflections from the formation and establishing data on formations and characteristics thereof , its relative distance, azimuth and tool size in a preferred embodiment of a profiled steel tool housing, rotating the tool and moving axially along the inside of the well in the drill string or other support, investigating the formation by means of sonic probe, and continuing the sonic investigation until an optimal well placement is achieved.
[0065] In accordance with the method of the invention, the tool can be provided with microprocessor means responsive to training data received from the acoustic source, receivers or transducers. In this way, a closed-loop tool that is capable of detecting formation changes and correcting the well direction can be realized. The acoustic source, receivers or transducers can investigate the formation or investigate a feature of a formation, take reference measurements to establish background noise and can provide data to a surface monitor to signal an opportunity for operator intervention to correct the well trajectory, if not able to do automatically.
[0066] Thus, in the case of the front sensing tool with acoustic investigation means, acoustic reflections of the formation are detected by a receiver or transducer. Sonic waves can be transmitted from the source and detected by the receiver (or transmitted and received by the transducer), calculated as return times based on different signature speeds of the formation ahead of the drill. The processor correlates formation data from maximum return, as well as particular signatures such as dips, formations allowing for drill fluid or formation variations. The processor uses this data to correlate whether the pre-programmed well path is actually being drilled to an optimal drillhole path based ahead of the drill formation assessment. When the processor detects a formation or feature of interest, such as a fault or change in porosity or gas zone, it automatically correlates the two measurements and recalculates an ideal trajectory.
[0067] In the case of background noise, the driller can pull the drill bit out of the bottom and respond to a reference survey without drilling, which will allow the subsequent drilling noise to be measured. The difference between the two minimum measurements is automatically used by the processor as background noise or redundant data.
[0068] For example, the processor can be programmed with a logic circuit that can be configured in any number of ways, such as optimizing performance. An example configuration might involve the circuit to first cross-check the bottom acoustic data and then take piercing measurements. In this way it can be seen whether there are any changes 5 in the formation or its characteristics. If the maximum bounce signals show that the formation ahead of the drill bit is a continuation of the present formation, there is a trend that can be followed. If the data ahead of the drill shows, for example, a change in the dip angle or an intersection of the formation or gas zone, then the tool can alert the user via mud pulse telemetry to verify the trajectory and action this azimuthal or tilt control as required or present it through a closed loop directional drilling system. A skilled technician will readily understand that other procedures can be implemented by the logic circuitry inside the processor, which can be programmed to cover other scenarios.
[0069] In another aspect, the invention provides a forward observation apparatus comprising at least one tool body with at least one set of source and receivers, optionally but not limited to a housing carrying a plurality of acoustic sources and receivers or transducers directed away from the tool body, wherein the acoustic source or receiver or transducer is received within the tool body, in a purpose-built housing having an open mouth and means to allow acoustic waves from origin to propagate to and from the housing and to the wellbore and from it, as well as formation from near and far.
[0070] In yet another aspect, the invention provides a front sensing apparatus comprising at least a tool body with said source receiver, or said transducer and a drill body with an acoustic source or a receiver or a transducer housing a plurality of sources, receivers or transducers directed away from the drill body, wherein the source or receiver or transducer or a combination thereof is received within the drill body in a chamber having an open mouth and means for housing retaining and propagating the transmission of the acoustic signal from the chamber through the acoustic or shielding source of the receiver or transducer during drilling or the bottom and where the acoustic source or receiver or transducer is provided with an internal keyway open to a source of energy and communications.
[0071] In addition, the acoustic source and arrays of the receiver or transducer can be configured perfectly, providing longitudinal spacing between the acoustic sources, receivers and transducers.
[0072] Additionally or alternatively, other types of sensors can replace the acoustic sensor receiving matrix.
[0073] Other aspects of the invention are disclosed in the following specific description of exemplary embodiments of the invention. BRIEF DESCRIPTION OF THE DRAWINGS
[0074] The embodiments of the invention are illustrated by means of non-limiting examples in the attached drawings, in which:
[0075] FIG. 1 is a schematic overview of an oil or gas well showing surface structures of the rig (10) and the underground well (20), with a tool (50) according to the invention as part of a bottom composition (40 ) drilling the well (30) and indicating formations and formation features (70) located ahead of the drill bit (60) and a drill well (80);
[0076] FIG. 2 is a side view of the bottom of the well illustrating the limitations of the prior art based on their distances behind the drill bit (100) limiting formation evaluation to formations behind the drill bit and in a lateral orientation, only (90) and formations (70) and characteristics of formations not investigated (110, 120, 130, 140);
[0077] FIG. 3 is a BHA from inside the well showing detailed components and distances corresponding to Figure 2
[0078] FIG. 4 is a 3-D terrestrial model from a side view of the downhole, portion cut away to show the invention's ability to look ahead of the drill bit (180) under a conical angular condition and detect formations (110 , 120, 130) in front of the drill bit. Figure 4 also shows several tool bodies with sources and receivers (50) that can be combined together along longitudinal BHA or well spacings, with the aim of ensuring that the pulsed investigation zone and the echo capture zone are optimised;
[0079] FIG. 5 is a schematic side view of the part of the tool cut away to show the source (51) and the receiver (52), elements housed (53) and oriented in a new angular profile (58), according to an angle (57), of the tool of Figure 1;
[0080] FIG. 6 is a diagrammatic cross-section through a forward observation tool in accordance with the invention similar to that shown in Figure 5, but having a rotatable swivel (62) or other wall contact element (69) at the leakage end above the hole. ;
[0081] FIG. 7 is a diagrammatic cross-section through a front sensing tool in accordance with the invention similar to that shown in Figure 5, but having an additional stabilizer or guard section (61) at the bottom end of the main well;
[0082] FIG. 8 is an enlargement of part of Figure 5 showing a source (51), a receiver (52) and its housing (53), the power means (54), the processor (55), the hard-wired (56) and angular orientation (57) within a profile (58) and the internal flow hole (59) and the lens surfaces on the sources or transducers (52a, 52b, 52c) with transponder (64) and the mud pulsator ( 64a); Figure 8a corresponds to Figure 8, in which a plurality of sources and receivers or transducers are housed in the body of said tool. Figure 8b corresponds to Figure 8, as an alternative embodiment, in which the zone around the housing can be treated to actively receive echo pulses that make it a detection zone enabling formation evaluation method using the treated zone to actively send or receive echo pulses;
[0083] FIG. 9 is an exemplary diagnostic and troubleshooting procedure in accordance with the invention showing background noise exclusions and signal switching;
[0084] FIG. 10 shows an alternative embodiment, with at least one tool body with sources and receivers (Figure 4, 50) used in conjunction with a drill bit having a receiver source, or a transducer for sending acoustic waves through the formation. the front the drill bit;
[0085] FIG. 11 corresponds to Figure 10 and shows a secondary tool body with sources and receivers (Figure 4, 50) used in conjunction with a drill bit having a receiver source, or a transducer to send acoustic waves through the formation ahead to drill bit. This secondary tool body was placed further back from the drill bit allowing extensive investigation to and from formations ahead of the drill bit. DETAILED DESCRIPTION OF THE INVENTION
[0086] As shown in Figure 1, an exemplary exploration or production rig comprises a surface structure (10) at the wellhead, a well (20), and a drill string (30) in the well with a borehole assembly of well (40) at its lower end. The wellbore assembly includes a front sensing drilling tool (50) in accordance with the invention and a drill bit (60) and formations yet to be penetrated (70) and the object of the invention.
[0087] The front sensing tool (50) is illustrated by means of exemplary embodiments in Figures 4, 5, 6, 7 and 8, comprising at least one tubular steel body (62) provided with a collar pin connection of drilling (63) at its downhole end to allow its direct or indirect connection to the drill bit (60) and a link to a communication means for the surface (64) at its other end, which is adapted to be engaged by an additional drill collar connection (not shown) to connect it to other elements of the wellbore assembly (40), and then the drill string (35).
[0088] The tool body has a profile (58) carrying at least one housing for at least one acoustic source (51) and a mounting receiver (52) capable of frontal sensing of the drill bit (60) . The original receiver module, or a transducer (51, 52 and 53) comprises a number of sources, receivers or transducers arranged symmetrically, radially and at determined angles around the profile of the tool body (50) and, in accordance with an angular orientation (57) with respect to the horizontal axis of the tool, to allow an investigation depth condition shown in Figure 4. Said angular receivers and transducers take the sound measurements extending behind the drill bit (60) and also in formations nearby (70) and in front of the well (110, 120 and 130).
[0089] An exemplary configuration of the invention in accordance with its specified object is shown in Figure 5.
[0090] Figure 6 is a diagrammatic cross-section through a front sensing tool in accordance with the invention, similar to that shown in Figure 5, but having an orientable rotation (62) or other wall contact element (69) on the end to the right. Also, such a well inside wall comes into contact with perhaps a roller reamer, an expanding reamer, a pressure containment device;
[0091] Figure 7 schematically illustrates the aforementioned elements of the tool (50), together with a section of the stabilizer (61) in a cross-sectional view through a front sensing tool in accordance with the invention similar to that shown in Figure 5, but having an additional stabilizer or guard section (61) at the bottom end of the main well;
[0092] As the acoustic source, receiver or a transducer is housed in a profiled element (58), an optimal angle is defined which can be either 89.5° degrees or as low as 0.5° degrees (57 ), as indicated in Figures 5, 6, 7 and 8, the tool incorporates an acoustic source (51) and an acoustic receiver (52). Tool performance is verified using a microprocessor, shown at location (55), which compares the receiver source data or a transducer (51,52,53) with a pre-programmed well trajectory, thus detecting formations and training characteristics. The tool is also programmed and automated to conduct diagnostics, in accordance with a logic circuit or diagnostic program stored in the processor (55), to ensure that the well is optimally placed. Once corrective measures have been taken, and if the tool indicates that the planned trajectory is not ideal in light of the frontal data sensing, an alert signal is sent via transponder (64) and mud pulser (64 ) to the surface platform (10) or to a remote operator so that azimuthal or tilt control action BHA (40) can be taken. A memory module (not shown) associated with the processor (55) can store acoustic information that can be downloaded to the surface when the tool is retrieved, or sent to the surface by telemetry via a transponder (64) and mud pulser ( 64a) or by other means of communication. A means of powering the source and the receivers or transducers is shown by (54).
[0093] The tool is provided with an internal link to a communication system which may be a mud pulse telemetry system (64) which also serves to monitor real-time formation data and features. One or more sources, receivers or transducers (51, 52, 53) are spaced within the profile of the tool body (58) in order to emit a series of sound waves over a given period of time which are reflected back by the well. near (40) or by the distant formation (110, 120, 130) in the case of a cavernous formation and caught by the acoustic reflection receivers or transducers (52,53). The microprocessor (55) establishes the formations (110, 120, 130) and formation characteristics (160) through a series of calculations derived from the acoustic velocity signatures and compares this to the trajectory of the pre-programmed or desired well. If the two measurements match certain user-defined tolerances, the tool continues to totalize the depth of the well section. If the training data does not match, the logic circuit determines a series of diagnostic steps, which are discussed in relation to Figure 9 below.
[0094] As further shown in Figure 5, a keyway (56) provides a channel for wiring (56) from the sounders or transducers (51,52,53) to the processor (55), and also the a transponder (64), which can be connected to a mud pulse generator (64a). The wiring is used to transmit formation evaluation data retrieved by the sounders or transducers (51, 52, 53) as well formation characteristics (110, 120, 130, 160) from the receivers or transducers (52,53) for processor (55) and transponder (64) and mud pulser (64a). The keyway can be sealed and filled with a means to absorb vibration and hold the wires in place, such as silicone gel or grease (not shown).
[0095] The transponder (64) converts the data from the microprocessor (55) so that it can be transmitted to the surface (10) and can be connected to the mud pulser (64a), which transmits the data to the surface using a series of binary codes at a given frequency using drilling fluid as a means of pulsating mud. Other means of data transfer can be used such as wireless transmission, small radio frequency jumps to additional mud pulsator or electromagnetic pulses.
[0096] Figure 7 shows an alternative configuration with a stabilizing or shielding profile (61) and shows a central axial axis through the passage (59) for drilling fluid flow (not shown) through the bottom assembly of well (40).
[0097] Receiver acoustic source means, or a transducer (51, 52) or integrated transducer (53), are typically housed within the housing (53a) in the tool body (50) in a profiled element (58) at an outwardly angled arrangement of 9 (57).
[0098] The transducer housing (53) can also be conveniently adapted and treated for the use of other types of sensors, especially electromagnetic sensors to establish fluid resistivity in formation ahead of the drill bit (60). In such a case, power, communication and data processing can be optimized to suit resistivity applications.
[0099] The tool body (50) is a cylindrical tube of high grade steel adapted to form part of bottom composition (BHA) 40. Figures 5, 6 and 7 show a schematic side view of the tool body (50 ) in modes with an independent tool (Figure 5, 50), the front sensing tool configured with a rotary orientable (Figure 6, 50, 62) and an additional tool (Figure 7 50, 61) configured with a stabilization element or of protection. In Figure 5, at the reading end from inside the well there is a pin connection (63) for a drill bit, in the center is a profiled section (58) of housing sources, receivers or transducers (51, 52, 53) and the control functions (55). In Figure 6, a back section (62) at the end to the well, with slope and steering control members (69), is attached to the tool or the BHA (40). In Figure 7, at both ends of the tool (50) a stabilizer (61) can be placed to stabilize the tool during drilling. Sources, receivers and transducers can be constructed and housed integrally and generally designated as (51, 52,53), except that additional numbers of receivers can additionally be placed around the source to form a detection zone (Figure 4, 50) . In the modality of an additional electromagnetic capacity, sources and receivers or transducers generally designated as acoustic can be constructed and are housed integrally to send and receive electromagnetic data. In all embodiments there is at least one surface that is difficult to face or coated with a rigid abrasion resistant material. The means for securing the tool body to a drill bit comprises a pin thread (not shown) provided in the tool body, which is engageable with a drill bit box (not shown).
[00100] In this alternative configuration, the tool is configured, in addition to investigative capability, with the body of the stabilization tool incorporating rigid turned cutter blocks to act as a stabilizer. The hard facing acts to avoid cutting abrasion while drilling. This eliminates some of the problems associated with loss of directional control due to a bespoke stabilizer close to the drill bit directly behind the drill bit.
[00101] The stabilizer can be directly or indirectly above or below the central sensing section and can be wired or wireless accordingly so as to ensure the mud-pusher (64a) can transmit data to the surface (10). The tool can be supplied with a mud pulsator as a stand alone tool or the mud pulse generator itself can be supplied by a third party as would be the case when a measurement suite during drilling or profiling during the proper drilling of tools is located in the BHA below the invention. Tool wiring configuration can be changed to accommodate such request.
[00102] Figure 8a corresponds to Figure 8, in which a plurality of sources, receivers or transducers are housed in said tool body. Figure 8b corresponds to Figure 8, as an alternative embodiment, in which the zone around the housing can be treated to actively receive echo pulses that make it a detection zone, which allows for a method of formation evaluation, which uses the treated zone to actively send or receive echo pulses.
[00103] As shown in Figures 4, 5, 6, 7, 8 and 9, the illustrated example of a tool according to the invention is a tool for evaluating the frontal sensing of the formation that uses a microprocessor (55) and electronic means to determine a 5 best trajectory of the piece. Sources, receivers and transduction means determine the actual formation characteristics (110, 120, 130, 160) and send corresponding signals back to the processor (55).
[00104] As required, sources, receivers and transducers (51, 52, 53) may be shielded and housed (53) in a plurality of forward angular orientations (57) directed outward from a shaped tool body ( 58) and at all times prior to drill bit (60) and determined as an optimal orientation based on formation and BHA component considerations. The sources, receivers or transducers may be received within the tool body housing profile in a recessed box of the source receiver, or a transducer (53) which is also adequately protected from abrasion wear and damage by at least , a protective coating or covering. The steel protective coating can be with a coating of HVOF, tungsten carbide, nickel boron, titanium, epoxy, Kevlar or other suitable protection for the requirements. The sensor can also be provided with a damping material or mechanism such as silicone gel or a spring (not shown).
[00105] The source and the receiver or transducer can then be provided with means (54) for conducting the sound pulses and receiving the echoes from the distant formation (110, 120, 130, 160), near the formation or well (80). The microprocessor control means (55) can be conveniently adapted to receive the training data from the sensors (51, 52) and to control the frequency in response thereto. A switching procedure can be conveniently incorporated to rule out a range of background noise frequencies either by setting a maximum and envelope reference measurement with such a maximum or by setting any other acoustic velocity signature.
[00106] Figure 10 shows an alternative embodiment in which the apparatus comprises at least three of the two bodies and at least one tool body is configured with sources and receivers (51, 52) that are used in association with a drillstring (60) having a source, receiver or transducer for sending or receiving acoustic waves through the formation ahead of the drillstring itself to be also received by one of said tool bodies. This allows for greater placement flexibility and smaller investigation angles to and from formations ahead of the drill can be probed and this data can be processed by the microprocessor and communications within said tool body.
[00107] Figure 11 corresponds to Figure 10 and shows said apparatus, in which a secondary tool body with sources and receivers (Figure 4, 50) is used in association with a drill bit having a source, receiver or a transducer to send acoustic waves through the formation ahead of the drill bit itself. This secondary tool body was placed further back from the drill bit allowing for extensive investigation. It can be seen from these modalities that many configurations are possible and remain within the purpose and scope of the invention, which is at all times a frontal sensing of the drill bit and obtaining data on formations or formation characteristics before the drill bit has penetrated to said formations.
[00108] Pressure compensation can be provided to handle pressure variations within the well compared to surface atmospheric conditions where activation is opposed by an external pressure source. This may comprise a port from a source of drilling fluid to a chamber suitably connected to the area inside the tool requiring pressure compensation (not shown).
[00109] The system may comprise a microprocessor means for evaluating formation control data and the relative positions of formation structures wherein the microprocessor means may include a means of automatically anticipating any formation or detection of a characteristic of a formation or detection of a change in the characteristic of a formation, thereby guiding the directional control system to ensure optimal trajectory and placement of the well.
[00110] The tool normally comprises a plurality of sources and receivers arranged symmetrically around the tool and arranged outwardly in angular orientations. The source and receiver can be configured as an integral transducer or separate as a source and multiple receivers known as a “sensing zone”. Two transducers could be on opposite sides of the tool, three transducers could be 120 degrees apart, four by 90 degrees, and six by 60 degrees. A number of tool bodies housing said source and receivers can be configured in a plurality of combinations with the aim of ensuring the pulsed investigation zone and the echo collection zone are optimised. In operation, the front sensing tool is typically rotated in the drill string, as well as being moved axially along the well.
[00111] In accordance with a particularly preferred aspect of the invention, the transducer or source and receiver array is provided with an internal keyway to direct energy from a source within the tool and provide communications to and from the sensor receiver. The power source may be a battery within the tool or within another tool holder suitably adapted for the purpose. Communications can be a processor inside the tool, or on the surface or other support for the tool suitably adapted for the purpose. Alternatively or additionally, the source and receiver body or transducer or tool may be provided with a wireless communication means to an internal or external processor. In each case, bidirectional communications provide data transmission, operational refinement, and data capture.
[00112] In order to keep the receiver source or a transducer clean and prevent the accumulation of clogging debris from the drilling operation, the sensor housing can be provided with a specialized coating to minimize residence or remove material completely.
[00113] In a preferred aspect the present invention incorporates an optimally oriented and spaced sound medium on the basis of formation evaluation, which is practically applicable and can be ultrasonic.
[00114] In another aspect of the present invention, housings for other types of sensors are provided within the profile that offers a robust and ideal location. This has not been possible with prior tools due to their inherent design limitations which rely on orientations that are lateral, orthogonal or perpendicular to the tool axis.
[00115] The tool can further comprise telemetry data communication means within the well and control signals between the tool and a surface interface, which can, among other functions, control the drill string during the formation evaluation operation .
[00116] In another aspect, the invention provides a method of operating a logging tool to investigate a formation or parameter of interest ahead of a drill bit or directional tool or the like, to guide and optimally place a drillhole, which comprises locating a tool according to the invention in a well on a support behind a drill bit, activating the source or receivers or transducers to emit and receive sound waves accordingly from the formation and establish the data on formations and characteristics thereof, their relative distance, azimuth and tool size in a preferred embodiment of a profiled steel tool housing, rotating the rotary tool and moving axially along the well in the column of or other support, investigating the formation by the acoustic sensor or receiver or transducer, and continuing the investigation at acoustic velocity until an ideal placement of the well.
[00117] For those skilled in the art, it is known that the wellhead surface structure (10) includes a control and communications system having an interface for communication with the well telemetry instrumentation including a transponder and a decoder that decodes the data and can be connected directly to the user or punch terminal. The decoded data can also be further transmitted by satellite or other means, to a remote user or a remote operations center via a telecommunication link. This surface control system allows complete communication to and from the bottom link and the top link with the invention.
[00118] As noted above, the invention provides a method of operating an automatically directional tool, according to a processor, which detects the differences between the programmed and actual measurements, using the data acquired from the front of the drill bit.
[00119] It is recognized that the tool can be programmed by the skilled person to cover many other scenarios.
[00120] Those skilled in the art will take into account that the examples of the invention given by the specific modalities illustrated and described show a new frontal sensing tool and system and method for formation evaluation before the drill, with numerous variations being possible. These embodiments are not intended to be limiting with respect to the scope of the invention. Substitutions, alterations and modifications not limited to the variations suggested herein may be made in the disclosed embodiments while remaining within the scope of the invention.

权利要求:
Claims (17)
[0001]
1. Front Sensing Apparatus (50), with means for attaching a tool body directly or indirectly to a drill bit (10) or support, whereby it can be rotated and moved axially along a passage ( 20) comprising at least one tool body, characterized in that it comprises: i. at least one profiled element (58), housing at least one source and an integrated acoustic receiver or transducer (51, 52, 53) disposed outwardly towards the end inside the well of said tool body and projecting forward in an angle (cp) of at least 0.25° or as much as 89.75° with respect to the longitudinal axis of the tool adapted to transmit sound and receive acoustic signature velocities of a formation or feature of a formation; ii. at least one microprocessor to process said acoustic signature speeds using said source, said receiver and said transducer being for increasing hydrocarbon recovery by optimizing the wellbore trajectory based on formation data acquired by said source acoustic and said receiver or said transducer before, during or after a drilling operation occurs, but at all times before a formation or formation feature has been penetrated by the drill bit.
[0002]
2. Front Sensing Apparatus (50) according to Claim 1, characterized in that said acoustic source and said receiver or said integrated transducer are received within said profiled element in said tool body at a housing (53) having an open mouth and suitably secured therein.
[0003]
3. Front Sensing Apparatus (50) according to any one of the preceding Claims, characterized in that said source, said receiver or said transducer may be provided with a surface that is concave (52a) or convex (52b) or planar (52c).
[0004]
4. Front Sensing Apparatus (50) according to Claim 1, characterized in that an electromagnetic source and integrated receiver or transducer are provided with means to send and receive electromagnetic data to and from the formation ahead of a drill bit and processed by said microprocessor.
[0005]
5. Front Sensing Apparatus (50) according to any one of the preceding Claims, characterized in that said tool body is configured with an orientable rotary system (Figure 5, 62) with a wall contact element (69) in the displacement hole above or leading to the end within the well or a roller reamer, an expandable reamer, a pressure containment device or a measuring device.
[0006]
6. Front Sensing Apparatus, (50), according to any one of Claims 1 to 5, characterized in that it comprises at least one of said profiled elements housing said source and said receiver or said transducer, at longitudinally spaced apart positions along said tool body, a first said tool body adapted to probe a formation ahead of the drill bit and a second said tool body adapted to stabilize the tool during drilling.
[0007]
7. Front Sensing Apparatus, (50), according to any one of Claims 1 to 6, characterized in that it comprises at least one of said profiled elements housing said source and said receiver or said transducer, at longitudinally spaced apart positions along said tool body, a first said tool body being adapted to stabilize the tool during drilling and a second said tool body adapted to probe a formation ahead of the drill bit.
[0008]
8. Front Sensing Apparatus (50) according to any one of the preceding Claims, characterized in that it comprises microprocessor control means (55) adapted to receive data on formation or formation characteristics based on speeds of acoustic signature recognized by said receivers (52) or said transducers, detecting a formation or formation feature, and controlling a directional tool in response to acquired acoustic data in order to maximize borehole footage drilled in productive reservoir zones.
[0009]
9. Front Sensing Apparatus (50) according to any one of the preceding Claims, characterized in that said tool body is provided with an internal keyway (56) leading to a source of power or communications inside or outside the tool and is capable of sending a warning signal to a user or where said profiled element is disposed in the drill pipe and used to look ahead of a formation or observe a feature of a formation.
[0010]
10. Front Sensing Apparatus (50) according to Claim 1, characterized in that it is arranged with a plurality of said sources, said receivers or said transducers being directed away from said tool body or separately housed and placed along the drill string in separate tool bodies with longitudinal BHA or wellbore spacings to form a detection zone to capture acoustic signature velocities or where either an acoustic source or receiver or transducer means (52) are housed on a surface drill bit or used in combination with a drill bit to look ahead and assess a formation that has not yet been drilled.
[0011]
11. Front Sensing Apparatus, (50), according to any one of the preceding Claims, characterized in that it further comprises communication means to communicate said acoustic data or electromagnetic and control signals between said tool and said apparatus and a surface decoder and real-time user interface to optimize performance.
[0012]
12. Front Sensing Apparatus (50) according to Claims 1 and 11, characterized in that the means for securing the tool body to a holder comprises a screw thread provided on the tool body which is adapted to engaging with a drill bit, the directional control system, the drill collar (30) or the extended length of coiled tubing (15) or the tool body is included in bottom composition comprising a drill bit (60) or used in the transportation or optimal placement of a drilling, completion, or production system (not shown).
[0013]
13. Automated Method of Operation of Front Sensing Tool, to optimally place a wellbore or a tubular or sand screen or similar drilling, completion or production system or device based on acquired formation data, characterized by the fact that comprises locating a tool or apparatus, as defined in any of the preceding Claims, in a well, in a drill bit or support in a wellbore, activating the acoustic source or the receiver or transducer to send and receive data of formation, rotation of the tool or apparatus and moving them axially along the well in the drill bit or support, receiving data through the receiver and continuing formation evaluation until an ideal wellbore placement is achieved using logic programming to diagnose and correct common errors or failures.
[0014]
14. Formation Assessment Method, using apparatus as defined in any of the preceding Claims, characterized in that it is provided with a closed-loop microprocessor means to detect a formation, detecting a characteristic of the formation by comparing it to a trajectory of the pre-programmed wellbore and automatically alerting an operator or changing the condition of a directional control system in response to it (62) and where the tool or apparatus is supported on a drill bit and drill string (40 ) and a surface interface controls and exchanges data with the drill string and any of its components during the formation assessment operation in accordance with a program to release a desired wellbore placement; and/or by the fact that said sources and said receivers or said transducers are optimally tuned and controlled by the means of the microprocessor so that undesirable noise does not interfere with the training evaluation.
[0015]
15. Front Sensing Formation Assessment Method, which uses said apparatus as defined in any one of Claims 1 to 14, characterized in that said tool or said apparatus provides immediate evaluation of a formation to be drilled or the characteristics of a formation yet to be drilled and, if said tool or said apparatus detects a characteristic of a formation or a change in a characteristic of interest, it automatically calculates and corrects for an ideal well trajectory and repeats the evaluation until such time ideal well path result is achieved in real time by the fact that said sources and said receivers or transducers are optimally tuned and controlled by microprocessor means so that unwanted noise no longer interferes with the formation evaluation.
[0016]
16. Front Sensing Formation Assessment Method according to Claim 15, characterized in that formations such as rock types, earth formations or lithologies with a characteristic of interest are detected, intended to include, but not be limited to, , detection of porosity or a change in porosity, detection of permeability or a change in permeability, an oil zone, a gas zone, a water zone, a fracture, a fault, a dip, a bed, a formation vugular, an anticline, a syncline and a trap.
[0017]
17. Optimized Well Control Method, which uses said tool or said apparatus as defined in any one of Claims 1 to 14, characterized in that it is to detect a highly pressurized zone and anticipate a kick or flow before of him entering the wellbore.

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WO2011080640A3|2012-06-21|

GB0922667D0|2010-02-10|

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US20120273270A1|2012-11-01|

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US3190388A|1961-05-16|1965-06-22|Schlumberger Well Surv Corp|Acoustic logging tools with acoustic attenuating structure|

US3161256A|1961-05-16|1964-12-15|Schiumberger Well Surveying Co|Acoustic logging tools|

US3974476A|1975-04-25|1976-08-10|Shell Oil Company|Highly-directional acoustic source for use in borehole surveys|

US4964085A|1986-02-25|1990-10-16|Baroid Technology, Inc.|Non-contact borehole caliber measurement|

US4802145A|1986-08-01|1989-01-31|Amoco Corporation|Method and apparatus for determining cement conditions|

US4800537A|1986-08-01|1989-01-24|Amoco Corporation|Method and apparatus for determining cement conditions|

US4867264A|1986-09-17|1989-09-19|Atlantic Richfield Company|Apparatus and method for investigating wellbores and the like|

US4757873A|1986-11-25|1988-07-19|Nl Industries, Inc.|Articulated transducer pad assembly for acoustic logging tool|

US4916400A|1989-03-03|1990-04-10|Schlumberger Technology Corporation|Method for determining characteristics of the interior geometry of a wellbore|

GB2261308B|1991-11-06|1996-02-28|Marconi Gec Ltd|Data transmission|

US5475309A|1994-01-21|1995-12-12|Atlantic Richfield Company|Sensor in bit for measuring formation properties while drilling including a drilling fluid ejection nozzle for ejecting a uniform layer of fluid over the sensor|

AU4700496A|1995-01-12|1996-07-31|Baker Hughes Incorporated|A measurement-while-drilling acoustic system employing multiple, segmented transmitters and receivers|

US6206108B1|1995-01-12|2001-03-27|Baker Hughes Incorporated|Drilling system with integrated bottom hole assembly|

US6088294A|1995-01-12|2000-07-11|Baker Hughes Incorporated|Drilling system with an acoustic measurement-while-driving system for determining parameters of interest and controlling the drilling direction|

US5678643A|1995-10-18|1997-10-21|Halliburton Energy Services, Inc.|Acoustic logging while drilling tool to determine bed boundaries|

US6564899B1|1998-09-24|2003-05-20|Dresser Industries, Inc.|Method and apparatus for absorbing acoustic energy|

US6308787B1|1999-09-24|2001-10-30|Vermeer Manufacturing Company|Real-time control system and method for controlling an underground boring machine|

US6480118B1|2000-03-27|2002-11-12|Halliburton Energy Services, Inc.|Method of drilling in response to looking ahead of drill bit|

US6510104B1|2000-06-07|2003-01-21|Schlumberger Technology Corporation|Acoustic frequency selection in acoustic logging tools|

US7099810B2|2001-06-20|2006-08-29|Halliburton Energy Services, Inc.|Acoustic logging tool having quadrupole source|

US6661737B2|2002-01-02|2003-12-09|Halliburton Energy Services, Inc.|Acoustic logging tool having programmable source waveforms|

US6907348B2|2003-02-12|2005-06-14|Baker Hughes Incorporated|Synthetic acoustic array acquisition and processing|

US7301852B2|2003-08-13|2007-11-27|Baker Hughes Incorporated|Methods of generating directional low frequency acoustic signals and reflected signal detection enhancements for seismic while drilling applications|

US20050034917A1|2003-08-14|2005-02-17|Baker Hughes Incorporated|Apparatus and method for acoustic position logging ahead-of-the-bit|

US7999695B2|2004-03-03|2011-08-16|Halliburton Energy Services, Inc.|Surface real-time processing of downhole data|

CN1601304A|2004-10-26|2005-03-30|大庆油田有限责任公司|Ground stress multifrequency reverse demonstration method of dipole trans verse wave well logging|

US8125848B2|2005-02-22|2012-02-28|Halliburton Energy Services, Inc.|Acoustic logging-while-drilling tools having a hexapole source configuration and associated logging methods|

US8055448B2|2007-06-15|2011-11-08|Baker Hughes Incorporated|Imaging of formation structure ahead of the drill-bit|

MX2010002076A|2007-08-27|2010-03-24|Schlumberger Technology Bv|Look ahead logging system.|

CN101392646A|2008-10-21|2009-03-25|中国海洋石油总公司|Acoustic logging instrument of novel acoustic array structure|

GB2476653A|2009-12-30|2011-07-06|Wajid Rasheed|Tool and Method for Look-Ahead Formation Evaluation in advance of the drill-bit|

US8542553B2|2010-02-04|2013-09-24|Schlumberger Technology Corporation|Downhole sonic logging tool including irregularly spaced receivers|

US8755248B2|2010-05-17|2014-06-17|Schlumberger Technology Corporation|Unipole and bipole acoustic logging while drilling tools|

US8559272B2|2010-05-20|2013-10-15|Schlumberger Technology Corporation|Acoustic logging while drilling tool having raised transducers|

US8861307B2|2011-09-14|2014-10-14|Schlumberger Technology Corporation|Acoustic logging while drilling tool with active control of source orientation|US7036611B2|2002-07-30|2006-05-02|Baker Hughes Incorporated|Expandable reamer apparatus for enlarging boreholes while drilling and methods of use|

US8875810B2|2006-03-02|2014-11-04|Baker Hughes Incorporated|Hole enlargement drilling device and methods for using same|

EP2483510A2|2009-09-30|2012-08-08|Baker Hughes Incorporated|Remotely controlled apparatus for downhole applications and methods of operation|

GB2476653A|2009-12-30|2011-07-06|Wajid Rasheed|Tool and Method for Look-Ahead Formation Evaluation in advance of the drill-bit|

CA2803831C|2010-06-24|2015-08-04|Baker Hughes Incorporated|Cutting elements for earth-boring tools, earth-boring tools including such cutting elements, and methods of forming cutting elements for earth-boring tools|

WO2012047847A1|2010-10-04|2012-04-12|Baker Hughes Incorporated|Status indicators for use in earth-boring tools having expandable members and methods of making and using such status indicators and earth-boring tools|

AU2010363968B2|2010-11-17|2016-08-04|Halliburton Energy Services, Inc.|Apparatus and method for drilling a well|

US8844635B2|2011-05-26|2014-09-30|Baker Hughes Incorporated|Corrodible triggering elements for use with subterranean borehole tools having expandable members and related methods|

US9074467B2|2011-09-26|2015-07-07|Saudi Arabian Oil Company|Methods for evaluating rock properties while drilling using drilling rig-mounted acoustic sensors|

US9447681B2|2011-09-26|2016-09-20|Saudi Arabian Oil Company|Apparatus, program product, and methods of evaluating rock properties while drilling using downhole acoustic sensors and a downhole broadband transmitting system|

US9903974B2|2011-09-26|2018-02-27|Saudi Arabian Oil Company|Apparatus, computer readable medium, and program code for evaluating rock properties while drilling using downhole acoustic sensors and telemetry system|

US10180061B2|2011-09-26|2019-01-15|Saudi Arabian Oil Company|Methods of evaluating rock properties while drilling using downhole acoustic sensors and a downhole broadband transmitting system|

US9624768B2|2011-09-26|2017-04-18|Saudi Arabian Oil Company|Methods of evaluating rock properties while drilling using downhole acoustic sensors and telemetry system|

US10551516B2|2011-09-26|2020-02-04|Saudi Arabian Oil Company|Apparatus and methods of evaluating rock properties while drilling using acoustic sensors installed in the drilling fluid circulation system of a drilling rig|

EP2587227A1|2011-10-31|2013-05-01|Welltec A/S|Downhole tool for determining flow velocity|

US8862405B2|2011-12-06|2014-10-14|Schlumberger Technology Corporation|System and method for producing look-ahead profile measurements in a drilling operation|

US8960333B2|2011-12-15|2015-02-24|Baker Hughes Incorporated|Selectively actuating expandable reamers and related methods|

US9267331B2|2011-12-15|2016-02-23|Baker Hughes Incorporated|Expandable reamers and methods of using expandable reamers|

US9493991B2|2012-04-02|2016-11-15|Baker Hughes Incorporated|Cutting structures, tools for use in subterranean boreholes including cutting structures and related methods|

CN102777165A|2012-07-23|2012-11-14|太仓市旭达机械设备有限公司|Detection and control device for underreaming bits|

EP3008497B1|2013-06-12|2021-03-17|Well Resolutions Technology|Apparatus and methods for making azimuthal resistivity measurements|

NO20130951A1|2013-07-09|2013-07-09|Modi Vivendi As|Systems for optimized, intelligent and autonomous drilling operations|

US9091155B2|2013-07-10|2015-07-28|Halliburton Energy Services, Inc.|Reducing disturbance during fiber optic sensing|

AU2013394366B2|2013-07-15|2017-03-30|Halliburton Energy Services, Inc.|Communicating acoustically|

MX367342B|2013-11-14|2019-08-15|Halliburton Energy Services Inc|Downhole systems for communicating data.|

CN103867197B|2014-04-04|2016-07-20|中国石油集团川庆钻探工程有限公司|Complex lithology natural gas reservoir interval transit time diagnostic method|

EP2952674A1|2014-06-04|2015-12-09|Services Petroliers Schlumberger|Rotating downhole logging tool with reduced torque|

AU2014415587B2|2014-12-31|2018-10-18|Halliburton Energy Services, Inc.|Visualization of look-ahead sensor data for wellbore drilling tools|

CA2965989C|2014-12-31|2019-07-02|Halliburton Energy Services, Inc.|Improving geosteering inversion using look-ahead look-around electromagnetic tool|

US10202846B2|2015-02-10|2019-02-12|Halliburton Energy Services, Inc.|Stoneley wave based pipe telemetry|

US20170350235A1|2015-03-30|2017-12-07|Halliburton Energy Services, Inc.|Acoustic source identification apparatus, systems, and methods|

US20170314389A1|2016-04-29|2017-11-02|Baker Hughes Incorporated|Method for packaging components, assemblies and modules in downhole tools|

WO2017189000A1|2016-04-29|2017-11-02|Halliburton Energy Services, Inc.|Water front sensing for electronic inflow control device|

CN107420085B|2016-05-23|2020-05-05|中国石油化工股份有限公司|Monitoring hole arrangement method and device|

US10612360B2|2017-12-01|2020-04-07|Saudi Arabian Oil Company|Ring assembly for measurement while drilling, logging while drilling and well intervention|

US10947811B2|2017-12-01|2021-03-16|Saudi Arabian Oil Company|Systems and methods for pipe concentricity, zonal isolation, and stuck pipe prevention|

US10557317B2|2017-12-01|2020-02-11|Saudi Arabian Oil Company|Systems and methods for pipe concentricity, zonal isolation, and stuck pipe prevention|

US10557326B2|2017-12-01|2020-02-11|Saudi Arabian Oil Company|Systems and methods for stuck pipe mitigation|

IT201900009873A1|2019-06-24|2020-12-24|Eni Spa|DETECTION SYSTEM TO DETECT DISCONTINUITY INTERFACES AND / OR ANOMALIES IN THE PRESSURE OF THE PORES IN GEOLOGICAL FORMATIONS.|

CN113503153A|2021-09-13|2021-10-15|四川交达预应力工程检测科技有限公司|Self-adaptive drilling hole-forming method and system|

法律状态:
2019-08-20| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

2019-12-10| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

2020-09-08| B06A| Notification to applicant to reply to the report for non-patentability or inadequacy of the application [chapter 6.1 patent gazette]|

2021-01-12| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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:

申请号 | 申请日 | 专利标题

GB0922667A|GB2476653A|2009-12-30|2009-12-30|Tool and Method for Look-Ahead Formation Evaluation in advance of the drill-bit|

GB0922667.1|2009-12-30|

PCT/IB2010/055752|WO2011080640A2|2009-12-30|2010-12-10|Look ahead advance formation evaluation tool|

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