Patent Grant
9316057
The present disclosure is related to downhole tools used to form wellbores including, but not limited to, rotary drill bits and other downhole tools having cutting elements and more particularly to improving downhole performance by controlling depth of cut for each cutting element and rate of penetration for an associated drill bit.
Various types of rotary drill bits, reamers, stabilizers and other downhole tools may be used to form a borehole in the earth. Examples of such rotary drill bits include, but not limited to, fixed cutter drill bits, drag bits, PDC drill bits and matrix drill bits used in drilling oil and gas wells. Cutting action associated with such drill bits generally requires rotation of associated cutting elements into adjacent portions of a downhole formation. Typical drilling action associated with rotary drill bits includes cutting elements which penetrate or crush adjacent formation materials and remove the formation materials using a scraping action. Drilling fluid may also be provided to perform several functions including washing away formation materials and other downhole debris from the bottom of a wellbore, cleaning associated cutting structures and carrying formation cuttings radially outward and then upward to an associated well surface.
A typical design for cutting elements associated with fixed cutter drill bits includes a layer of super hard material or super abrasive material such as a polycrystalline diamond (PDC) layer disposed on a substrate such as tungsten carbide. A wide variety of super hard or super abrasive materials have been used to form such layers on substrates. Such substrates are often formed from cemented tungsten carbide but may be formed from a wide variety of other suitably hard materials. A “super hard layer” or “super abrasive layer” may provide enhanced cutting characteristics and longer downhole drilling life of associated cutting elements.
Backup cutters (sometimes referred to as “secondary cutter”) and/or impact arrestors have previously been used on rotary drill bits in combination with cutting elements having super hard or super abrasive layers. Primary cutters are often disposed on fixed cutter drill bits with respective super hard cutting surfaces oriented generally in the direction of bit rotation. Backup cutters and/or impact arrestors are often used when drilling a wellbore in hard subsurface formations or intermediate strength formations with hard stringers. Backup cutters and/or impact arrestors may extend downhole drilling life of an associated rotary drill bit by increasing both surface area and volume of super hard material or super abrasive material in contact with adjacent portions of a downhole formation. For some applications fixed cutter rotary drill bits have been provided with cutting elements having side cutting surfaces in addition to traditional end cutting surfaces.
Some rotary drill bits with primary cutters oriented to engage adjacent portions of a downhole formation along with secondary cutters trailing the primary cutters and typically oriented to act as impact arrestors often require relatively high rates of penetration before the trailing secondary cutters will contact adjacent portions of a downhole formation. For many drilling operations actual rates of penetration may be lower than this required high rate of penetration. As a result, the trailing secondary cutters or impact arrestors may not contact adjacent portions of the downhole formation. For such drilling operations, the secondary cutters may not effectively control rate of penetration and may not protect the primary cutters.
When prior impact arrestors have been placed in a leading position relative to respective cutters, such impact arrestors have often been able to initially control rate of penetration of an associated drill bit. However, when the cutters become worn, rate of penetration for the same overall set of downhole drilling conditions may increase significantly to greater than desired values.
In accordance with teachings of the present disclosure, rotary drill bits and other downhole tools used to form a wellbore may be provided with cutting elements having respective protectors operable to control depth of a cut formed by each cutting element in adjacent portions of a downhole formation and control rate of penetration of an associated rotary drill bit. For some applications, secondary cutting elements having respective protectors may be combined with primary cutting elements having respective protectors to prolong downhole drilling life of an associated rotary drill bit.
Another aspect of the present disclosure may include substantially reducing and/or eliminating damage to cutting elements while drilling a wellbore in a downhole formation having hard materials. For some applications such cutting elements may have dual cutting surfaces and associated cutting edges. Controlling depth of each cut or kerf formed in adjacent portions of a downhole formation in accordance with teachings of the present disclosure may provide enhanced axial stability and lateral stability during formation of a wellbore. Steerability and tool face controllability of an associated rotary drill bit may also be improved.
Another aspect of the present disclosure includes providing secondary cutters operable to satisfactorily form a wellbore after damage to one or more primary cutters. Separate design and drill bit performance evaluations may be conducted when forming a wellbore with primary cutters and when forming a wellbore with associated secondary cutters.
Technical benefits of the present disclosure may include, but are not limited to, controlling depth of cut of cutting elements disposed on a rotary drill bit, efficiently controlling rate of penetration of the rotary drill bit and/or providing secondary cutting elements operable to prolong downhole drilling life of an associated rotary drill bit. Forming rotary drill bits and associate cutting elements in accordance with teachings of the present disclosure may substantially reduce or eliminate damage to cutting surfaces and/or cutting edges associated with such cutting elements.
Further technical benefits of the present disclosure may include, but are not limited to, eliminating or minimizing impact damage to primary cutters or major cutters, increasing bit life by providing secondary cutters operable to function as primary cutters or major cutters when associated primary cutters experience a designed amount of wear, increased stability of an associated rotary drill bit both axially and radially relative to a bit rotation axis and improving directional drilling control by more efficiently avoiding damage to associated gage cutters.
A more complete and thorough understanding of various embodiments and advantages thereof may be acquired by referring to the following description taken in conjunction with accompanying drawings, in which like reference numbers indicate like features, and wherein:
Preferred embodiments of the present disclosure and various advantages may be understood by referring to
The terms “rotary drill bit” and “rotary drill bits” may be used in this application to include various types of fixed cutter drill bits, drag bits, matrix drill bits and PDC drill bits. Cutting elements and blades incorporating features of the present disclosure may also be used with reamers, near bit reamers, and other downhole tools associated with forming a wellbore.
Rotary drill bits incorporating teachings of the present disclosure may have many different designs and configurations. Rotary drill bits 100, 100a and 100b as shown in
The terms “cutting element” and “cutting elements” may be used in this application to include various types of compacts, cutters and/or inserts satisfactory for use with a wide variety of rotary drill bits. The term “cutter” may include, but is not limited to, face cutters, gage cutters, inner cutters, shoulder cutters, active gage cutters and passive gage cutters. Such cutting elements may be formed with respective protectors in accordance with teachings of the present disclosure.
Polycrystalline diamond compacts (PDC), PDC cutters and PDC inserts are often used as cutting elements for rotary drill bits. Polycrystalline diamond compacts may also be referred to as PCD compacts. A wide variety of other types of super hard or super abrasive materials may also be used to form portions of cutting elements disposed on a rotary drill bit in accordance with teachings of the present disclosure.
A cutting element or cutter formed in accordance with teachings of the present disclosure may include a substrate with a layer of hard cutting material disposed on one end of the substrate. Substrates associated with cutting elements for rotary drill bits often have a generally cylindrical configuration. However, substrates with noncylindrical and/or noncircular configurations may also be used to form cutting elements in accordance with teachings of the present disclosure.
A wide variety of super hard and/or super abrasive materials may be used to form the layer of hard cutting material disposed on each substrate. Such layers of hard cutting material may have a wide variety of configurations and dimensions. Some examples of these various configurations are shown in the drawings and further described in the written description.
Generally circular cutting surfaces and cutting planes may be described as having an “area” or “cutting area” based on a respective diameter of each cutting surface or cutting plane. For noncircular cutting surfaces and cutting planes an “effective diameter” corresponding with the effective cutting area of such noncircular cutting surfaces and cutting planes may be used to design cutting elements and rotary drill bits in accordance with teachings of the present disclosure.
For some applications cutting elements formed in accordance with teachings of the present invention may include one or more layers of super hard and/or super abrasive materials disposed on a substrate. Such layers may sometimes be referred to as “cutting layers” or “tables”. Cutting layers may be formed with a wide variety of configurations, shapes and dimensions in accordance with teachings of the present disclosure. Examples of such configurations and shapes may include, but are not limited to, “cutting surfaces”, “cutting edges”, “cutting faces” and “cutting sides”.
Cutting layers or layers of super hard and/or super abrasive materials may also be referred to as “penetrating layers” or “scraping layers”. Some cutting elements incorporating teachings of the present invention may be designed, located and oriented to optimize penetration of an adjacent formation. Other cutting elements incorporating teachings of the present invention may be oriented to optimize scraping adjacent portions of an associated formation. Examples of hard materials which may be satisfactorily used to form cutting layers include various metal alloys and cermets such as metal borides, metal carbides, metal oxides and/or metal nitrides.
The terms “cutting structure” and “cutting structures” may be used in this application to include various combinations and arrangements of cutting elements, cutters, face cutters, gage cutters, impact arrestors, protectors, blades and/or other portions of rotary drill bits, coring bits, reamers and other downhole tools used to form a wellbore. Some fixed cutter drill bits may include one or more blades extending from an associated bit body. Cutting elements are often arranged in rows on exterior portions of a blade or other exterior portions of a bit body associated with fixed cutter drill bits. Various configurations of blades and cutters may be used to form cutting structures for a fixed cutter drill bit in accordance with teachings of the present disclosure.
The term “rotary drill bit” may be used in this application to include, but is not limited to, various types of fixed cutter drill bits, drag bits and matrix drill bits operable to form a wellbore extending through one or more downhole formations. Rotary drill bits and associated components formed in accordance with teachings of the present disclosure may have many different designs and configurations.
The terms “downhole data” and “downhole drilling conditions” may include, but are not limited to, wellbore data and formation data such as listed on Appendix A. The terms “downhole data” and “downhole drilling conditions” may also include, but are not limited to, drilling equipment data such as listed on Appendix A.
The terms “design parameters,” “operating parameters,” “wellbore parameters” and “formation parameters” may sometimes be used to refer to respective types of data such as listed on Appendix A. The terms “parameter” and “parameters” may be used to describe a range of data or multiple ranges of data. The terms “operating” and “operational” may sometimes be used interchangeably.
Various computer programs and computer models may be used to design cutting elements and associated rotary drill bits in accordance with teachings of the present disclosure. Examples of such methods and systems which may be used to design and evaluate performance of cutting elements and rotary drill bits incorporating teachings of the present disclosure are shown in copending U.S. patent applications entitled “Methods and Systems for Designing and/or Selecting Drilling Equipment Using Predictions of Rotary Drill Bit Walk,” application Ser. No. 11/462,898, filing date Aug. 7, 2006, copending U.S. patent application entitled “Methods and Systems of Rotary Drill Bit Steerability Prediction, Rotary Drill Bit Design and Operation,” application Ser. No. 11/462,918, filed Aug. 7, 2006, and copending U.S. patent application entitled “Methods and Systems for Design and/or Selection of Drilling Equipment Based on Wellbore Simulations,” application Ser. No. 11/462,929, filing date Aug. 7, 2006. The previous copending patent applications and any resulting U.S. patents are incorporated by reference in this application.
The terms “drilling fluid” and “drilling fluids” may be used to describe various liquids and mixtures of liquids and suspended solids associated with well drilling techniques. Drilling fluids may be used for well control by maintaining desired fluid pressure equilibrium within a wellbore and providing chemical stabilization for formation materials adjacent to a wellbore. Drilling fluids may also be used to cool portions of a rotary drill bit and to prevent or minimize corrosion of a drill string, bottom hole assembly and/or attached rotary drill bit.
Various types of drilling equipment such as a rotary table, mud pumps and mud tanks (not expressly shown) may be located at well surface or well site 22. Drilling rig 20 may have various characteristics and features associated with a “land drilling rig.” However, rotary drill bits incorporating teachings of the present disclosure may be satisfactorily used with drilling equipment located on offshore platforms, drill ships, semi-submersibles and drilling barges (not expressly shown).
Rotary drill bit 100, 100a and 100b (See
Bottom hole assembly 26 may be formed from a wide variety of components. For example components 26a, 26b and 26c may be selected from the group consisting of, but not limited to, drill collars, rotary steering tools, directional drilling tools and/or downhole drilling motors. The number of components such as drill collars and different types of components included in a bottom hole assembly will depend upon anticipated downhole drilling conditions and the type of wellbore which will be formed by drill string 24 and rotary drill bit 100.
Drill string 24 and rotary drill bit 100 may be used to form a wide variety of wellbores and/or bore holes such as generally vertical wellbore 30 and/or generally horizontal wellbore 30a as shown in
Wellbore 30 may be defined in part by casing string 32 extending from well surface 22 to a selected downhole location. Portions of wellbore 30 as shown in
Formation cuttings may be formed by rotary drill bit 100 engaging formation materials proximate end 36 of wellbore 30. Drilling fluids may be used to remove formation cuttings and other downhole debris (not expressly shown) from end 36 of wellbore 30 to well surface 22. End 36 may sometimes be described as “bottom hole” 36. Formation cuttings may also be formed by rotary drill bit 100 engaging end 36a of horizontal wellbore 30a.
As shown in
In addition to rotating and applying weight to rotary drill bit 100, drill string 24 may provide a conduit for communicating drilling fluids and other fluids from well surface 22 to drill bit 100 at end 36 of wellbore 30. Such drilling fluids may be directed to flow from drill string 24 to respective nozzles 56 provided in rotary drill bit 100. See
Bit body 120 will often be substantially covered by a mixture of drilling fluid, formation cuttings and other downhole debris while drilling string 24 rotates rotary drill bit 100. Drilling fluid exiting from one or more nozzles 56 may be directed to flow generally downwardly between adjacent blades 128 and flow under and around lower portions of bit body 120.
Bit body 120 may also include upper portion or shank 42 with American Petroleum Institute (API) drill pipe threads 44 formed thereon. API threads 44 may be used to releasably engage rotary drill bit 100 with bottomhole assembly 26 whereby rotary drill bit 100 may be rotated relative to bit rotational axis 104 in response to rotation of drill string 24. Bit breaker slots 46 may also be formed on exterior portions of upper portion or shank 42 for use in engaging and disengaging rotary drill bit 100 from an associated drill string.
A longitudinal bore (not expressly shown) may extend from end 41 through upper portion 42 and into bit body 120. The longitudinal bore may be used to communicate drilling fluids from drill string 32 to one or more nozzles 56.
A plurality of respective junk slots or fluid flow paths 140 may be formed between respective pairs of blades 128. Blades 128 (see
A plurality of cutting elements 60 may be disposed on exterior portions of each blade 128. For some applications each cutting element 60 may be disposed in a respective socket or pocket formed on exterior portions of associated blade 128. Various parameters associated with rotary drill bit 100 may include, but are not limited to, location and configuration of blades 128, junk slots 140 and cutting elements 60. Such parameters may be designed in accordance with teachings of the present disclosure for optimum performance of rotary drill bit 100 in forming a wellbore.
Each blade 128 may include respective gage surface or gage portion 130. For some applications active and/or passive gage cutters may also be disposed on each blade 128. See for example,
Rotary drill bits are generally rotated to the right during formation of a wellbore. See arrow 28 in
During rotation of an associated fixed cutter rotary drill, cutting element 60 will generally cut or form kerf 39 in adjacent portions of downhole formation 38. The dimensions and configuration of kerf 39 typically depend on factors such as dimensions and configuration of primary cutting surface 71, rate of penetration of the associated rotary drill bit, radial distance of cutting element 60 from an associated bit rotational axis, type of downhole formation materials (soft, medium, hard, hard stringers, etc.) and amount of formation material removed by a leading cutting element. For cutting elements disposed on a fixed cutter rotary drill bit, rate of penetration, weight on bit, total number of cutting elements, size of each cutting element, and respective radial position of each cutting element will determine an average kerf depth or cutting depth for each cutting element.
Cutting elements such as shown in
Layer 84 of hard cutting material may be disposed on one end of protector 80 spaced from primary cutting surface 71. Layer 84 of hard cutting material may also be referred to as “cutting layer 84.” For some applications cutting layers 70 and 84 may be formed from substantially the same hard cutting materials. For other applications cutting layers 70 and 84 may be formed from different materials. Protector 80 may also include cutting surface 82 formed on an extreme end of protector 80 opposite from substrate 64.
Each cutting element 60 may be disposed on exterior portions of an associated rotary drill bit such as blades 128 of rotary drill bit 100. The orientation of each cutting element 60 may be selected to provide desired angle 66 at which primary cutting surface 71 engages adjacent portions of downhole formation 38. Angle 66 may sometimes be referred to as a “backrake angle” or the angle at which primary cutting surface 71 engages adjacent portions of formation 38. See
For embodiments such as shown in
Various geometric parameters associated with a cutting element and associated protector incorporating teachings of the present disclosure may be calculated based on the following equation.
Δ=0.5(D−d)cos(β)−L sin(β)
Where Δ=designed depth of cut or maximum depth of cut by a primary cutting surface of a cutting element during one bit revolution before an associated protector contacts adjacent portions of a downhole formation. A cutting surface may also be provided the associated protector for purpose of contacting adjacent portions of the downhole formation.
D=diameter of the cutting element
d=diameter of the protector
β=backrake angle of the cutting element
L=length of the protector extending from the primary cutting surface of the cutting element.
Rotary drill bits typically have a designed maximum rate of penetration based on parameters such as weight on bit (WOB), revolutions per minute (RPM) and associated downhole formation characteristics. See Appendix A. A corresponding maximum depth of cut (Δmax) for each cutting element during one bit revolution may be calculated using the formula:
For some applications maximum depth of cut (Δmax) may correspond with a designed depth of cut (Δ) for each cutting element. For other applications the designed depth of cut (Δ) may be calculated using a rate of penetration other than ROPmax. For example, an optimum rate of penetration may be used to calculate a designed depth of cut (Δ) based on anticipated downhole formation characteristics.
Length 86 of protector 80 may be designed to allow primary cutting surface 71 to form kerf or track 39 in adjacent portions of formation 38 with depth of cut (Δ) 40 prior to cutting surface 82 of protector 80 engaging adjacent portions of formation 38. See
For embodiments such as shown in
For some applications EDM (electric discharge machining) techniques may also be used to form a central bore extending along a central axis of a substrate. For example a hole or other opening (not expressly shown) may be formed proximate a midpoint in the side of a generally solid cylinder having overall dimensions associated with substrate 64. An EDM wire (not expressly shown) may be inserted through the hole to form central bore 74.
For some applications protector 80 may include substrate 90 having exterior dimensions and configuration compatible with the dimensions and configuration of central bore 74. Layer 84 of hard cutting material may be disposed on one end of substrate 90 using conventional cutting element manufacturing techniques. The dimensions of substrate 90 may be selected such that substantially the full length 86 cutting layer 84 will extend from primary cutting surface 71. Various techniques associated with forming polycrystalline diamond components may be used to securely engage substrate 90 within central bore 74.
Cutting layer 84a may be formed with dimensions compatible with opening 73 in layer 70a and with the extreme end of projection 65. Thickness 86a of cutting layer 84a may be selected to allow cutting surface 82 of cutting layer 84a to extend a desired length from primary cutting surface 71.
Various features of a cutting element formed in accordance with teachings of the present disclosure may be described with respect to a cutting face axis. In a cutting element coordinate system the cutting face axis may extend from a point of contact between an associated cutting surface and adjacent portions of the downhole formation through the center of the cutting surface. The cutting face axis may also extend generally normal to a central axis of an associated substrate. One example is cutting face axis 92 as shown in
The generally elliptical or oval shaped configuration of protector 80c may be defined in part by primary axis or major axis 94c. For embodiments such as shown in
Cutting element 60d as shown in
One of the benefits of the present disclosure includes the ability to orient or rotate protector 80c prior to attachment with an associated substrate to vary the angle between major axis 94 and cutting face axis 92 of an associated cutting element to control the cutting depth of the cutting element. The smallest designed cutting depth (Δ) 40c may occur when major axis 94 is aligned generally parallel with cutting face axis 92. The largest design cutting depth (Δ) 40c may occur at major axis 94 aligned generally perpendicular with cutting face axis 92.
For embodiments represented by cutting element 60k as shown in
For embodiments such as shown in
Protector 80m may extend from primary cutting surface 71m as previously described with respect to cutting element 60. Protector 80m may have a generally square cross section smaller than the cross section of primary cutting surface 71m such as shown in
Depending upon downhole drilling conditions, cutting elements may be formed in accordance with teachings of the present disclosure with substrates and/or protectors having a wide variety of noncircular configurations. The use of such noncircular configurations may depend upon characteristics of an associated downhole formation. Examples of noncircular configurations which may be used to form a cutting element in accordance with teachings of the present disclosure include cutting element 60m. Cutting element 60n having a sextagonal configuration (see
Another example of a cutting element incorporating teachings of the present disclosure is shown in
For embodiments of the present disclosure as represented by rotary drill bit 100a, pairs or sets of cutting elements 160a and 160b may be disposed on exterior portions of each blade 128f. Each blade 128f may include leading edge 131 and trailing edge 132. For embodiments of the present disclosure as represented by rotary drill bit 100a each secondary cutting element 160b may be disposed in a “leading” position relative to associated primary cutting element 160a.
Some rotary drill bits have previously been designed with a primary cutting element in a leading position and a secondary cutting element or impact arrestor in a trailing position. For such arrangements the impact arrestor or secondary cutting element often provided less than desired ability to control rate of penetration of an associated rotary drill bit. A relatively large rate of penetration (ROP) may often be required before a trailing secondary cutter or trailing impact arrestor (not expressly shown) will contact adjacent portions of a downhole formation. The required minimum rate of penetration (ROPminimum) before a trailing secondary cutter or trailing impact arrestor will contact adjacent portions of a downhole formation may be calculated using the following equation:
ROPminimum=5×RPM×360×Δ/dθ
where Δ is the designed cutting of a primary cutting before an associated secondary cutting surface contacts adjacent portions of a downhole formation. Δ may also be a difference in inches between exposure of a primary cutting surface and an associated secondary cutting surface as measured from an associated bit face profile.
dθ is the number of degrees the secondary cutting element trails the primary cutting element.
dθ also corresponds with the angular separation between the primary cutting element and the secondary cutting element measured from an associated bit rotation axis.
Typical values for some fixed cutter rotary drill bits may be Δ=0.06 inches and RPM=120. When a primary cutter and an associated secondary cutter are disposed on the same blade such as shown in
For some applications with a primary cutter and a secondary cutter disposed on respective blades the value of dθ may be approximately twenty (20°) degrees. The calculated minimum rate of penetration (ROPminimum) required before contact occurs between the secondary cutting element and adjacent portions of the downhole formation with dθ=twenty (20°) degrees may be approximately six hundred fifty (650) feet per hour indicating that such contact is not likely.
For embodiments such as shown in
For embodiments represented by the pair or set of cutting elements 160a and 160b, the configuration and dimensions of substrate 164a and associated layer 170a of hard cutting material may be larger than the corresponding configuration and dimensions of substrate 164b and layer 170b of hard cutting material. However, for other applications a pair or set of a primary cutting element and an associated secondary cutting element may have substantially the same overall dimensions and configuration.
Substrates 164a and 164b may have generally cylindrical configurations. Respective cutting layers 170a and 170b may also have generally circular configurations similar to previously described cutting layer 70. However, dimensions associated with cutting layer 170b may be less than corresponding dimensions of cutting layer 170a. For example, diameter (Db) of secondary cutting surface 171b may be smaller than diameter (Da) of primary cutting surface 171a. Substrates 164a and 164b may be formed from tungsten carbide or other materials associated with forming cutting elements on rotary drill bits.
Primary cutting element 160a may be disposed on exterior portions of an associated rotary drill bit such that primary cutting surface 171a is more exposed as compared to secondary cutting surface 171b of secondary cutting element 160b. As a result, designed cutting depth (Δ) 50 represents the difference between exposure of cutting surface 171a as compared to the exposure of cutting surface 171b relative to adjacent portions of an associated downhole formation. The exposure of cutting surface 171a and 171b may also be described as the distance each cutting surface extends from an associated bit face profile. See
Another aspect of the present disclosure includes placing secondary cutting element 160b in a leading position relative to primary cutting element 160a. The difference in exposure between secondary cutting surface 171b of secondary cutter 160b and primary cutting surface 171a of cutting element 160b may be designed to correspond with a desired amount of wear on primary cutting surface 171a. As a result of the difference in exposure or designed cutting depth (Δ) 50, secondary cutter 160b will generally not contact adjacent portions of downhole formation 38 until the wear on primary cutting surface 171a equals the designed cutting depth (Δ) 50. When actual wear depth of primary cutting surface 171a equals the designed cutting depth (Δ) 50, secondary cutter 160b will become the primary or major cutter. The primary cutter 160a may continue to slightly contact adjacent portions of downhole formation 38.
As a result of placing secondary cutting element 160b in a leading position relative to primary cutting element 160a, the angular difference between the location of primary cutting element 160a and secondary cutting element 160b relative to bit rotational axis 104b may be represented by angle (dθ) 168. However, secondary cutting element 160b trails primary cutting element 160a by 360°−dθ. The minimum rate of penetration (ROPminimum) at which secondary cutting element 160b may engage adjacent portions of downhole formation 38 can be calculated using the following formula:
ROPminimum=5×RPM×360×Δ/(360−dθ)(ft/hr)
For example, when designed depth of cut (Δ) 50 equals 0.06 inches, RPM equals 120, (revolutions per minute) and dθ equals 3 degrees, calculated minimum rate of penetration will be approximately 36.3 ft/hr when cutting surface 171b of secondary cutting element 160b contacts adjacent portions of a downhole formation. This example shows that when ROP is larger than 36.3 ft/hr, secondary cutting element 160b may contact adjacent portions of downhole formation 38 to control ROP of an associated rotary drill bit.
For some applications primary cutting element 160a and associated secondary cutting element 160b may be disposed on the same blade. See
For some applications primary cutting layer 174a may be formed from the same material as secondary cutting layer 174b. For other applications primary cutting layer 174a may be formed from material which is softer than the material used to form secondary cutting layer 174b on associated secondary cutting element 160b. For such embodiments, when actual wear depth of primary cutting surface 171a of cutter 160a equals the designed cutting depth, remaining portion of primary cutting surface 171a may continue to wear faster than the secondary cutting surface 171b of secondary cutter 160b.
For some applications computer simulations may be used to energy balance an associated rotary drill bit when primary cutting element 160a are forming adjacent portions of a wellbore. Similar computer simulations may also be used to energy balance of the associated rotary drill bit when secondary cutting element 160b are forming portions of the same wellbore.
A pair of cutting elements such as shown in
When primary cutting surface 171a experiences sufficient wear (sometimes referred to as “designed wear”) such that secondary cutting element 260b becomes the primary or major cutter, third designed depth (Δ3) 50c may become important. Third designed cutting depth (Δ3) 50c may correspond with depth of cut by cutting surface 171b prior to cutting surface 282 contacting adjacent portions of downhole formation 38. Third designed cutting depth (Δ3) 50c may be calculated based on an associated rotary drill bit exceeding a calculated maximum rate of penetration while forming a wellbore using cutting surface 171b.
A pair of cutting elements such as shown in
When primary cutting surface 171a experiences sufficient wear (sometimes referred to as “designed wear”) such that secondary cutting element 160b becomes the primary or major cutter, second designed cutting depth (Δ2) 50f may become important. Second designed cutting depth (Δ2) 50f may correspond with the total designed wear for both cutting surface 171a and cutting surface 382 after which secondary cutting element 160b may become the primary or major cutter.
Some rotary drill bits may be generally described as having three components or three portions for purposes of designing cutting elements and an associated rotary drill bit and/or simulating forming a wellbore using the cutting elements and associated rotary drill bit incorporating teachings of the present disclosure. The first component or first portion may be described as “face cutters” or “face cutting elements” which may be primarily responsible for drilling action associated with removal of formation materials to form an associated wellbore. For some types of rotary drill bits the “face cutters” may be further divided into three segments such as “inner cutters,” “shoulder cutters” and/or “gage cutters”. See, for example,
The second portion of a rotary drill bit may include an active gage or gages responsible for maintaining a relatively uniform inside diameter of an associated wellbore by removing formation materials adjacent portions of the wellbore. An active gage may contact and intermittently removing material from sidewall portions of a wellbore.
The third component of a rotary drill bit may be described as a passive gage or gages which may be responsible for maintaining uniformity of adjacent portions of the wellbore (typically the sidewall or inside diameter) by deforming formation materials in adjacent portions of the wellbore but not removing such materials.
Gage cutters may be disposed adjacent to active and/or passive gages. However, gage cutters are generally not considered as part of an active gage or passive gage for purposes of simulating forming a wellbore with an associated rotary drill bit. The present disclosure is not limited to designing cutting elements for only rotary drill bits with the previously described three components or portions of a rotary drill bit.
For embodiments such as shown in
Exterior portions of bit body 120b opposite from upper end or shank 42 as shown in
Each blade 128b may also be described as having respective shoulder 136b extending outward from respective nose 134b. A plurality of cutter elements 160s may be disposed on each shoulder 136b. Cutting elements 160s may sometimes be referred to as “shoulder cutters.” Shoulder 136b and associated shoulder cutters 160s may cooperate with each other to form portions of the bit face profile of rotary drill bit 100b extending outwardly from cone shaped section 132b. A plurality of gage cutters 160g may also be disposed on exterior portions of each blade 128b adjacent to associated gage surfaces 130.
One of the benefits of the present disclosure may include designing a rotary drill bit having an optimum number of inner cutters, shoulder cutters and gage cutters with respective protectors providing desired steerability and/or controllability characteristics. Another benefit of the present disclosure may include providing pairs or sets of cutting elements on exterior portions of an associated rotary drill bit to increase the downhole drilling life of the associated drill bit. Cutting elements 160i, 160s and 160g as shown in
Rotary drill bit 100b as shown in
At step 404 a maximum allowed rate of penetration for the drill bit corresponding with the drill bit data input into the software application at step 402 may be inputted into the software program or algorithm. At step 406 the total number of cutters on the drill bit may be inputted into the software program or algorithm.
At step 408 various geometric parameters for each cutting element or cutter such as cutter diameter, protector diameter and cutter backrake angle may be selected. Additional cutter geometric parameters and/or design characteristics as previously discussed in this application may also be inputted. At step 410 the maximum depth of cut of each cutter during one bit revolution may be calculated based on the previously input maximum allowed rate of penetration for the rotary drill bit. At step 412 the length of protector may be calculated for the associated cutting element using the formula L=0.5×(D−d)×cos(β)−Δmax/sin β.
At step 414 the calculated length of the respective protector may be compared with an allowable range of protector lengths. If the calculated protector length is satisfactory, the software application or algorithm will proceed to step 416. If the calculated step is not satisfactory, the software application or algorithm will return to step 408 to select alternative cutter geometric parameters. Steps 408, 410 and 412 may be repeated until the calculated length of the respective protector is in the allowable range. At this time the software application or algorithm will proceed to step 416. If the cutter being considered is the last cutter or the K cutter, the software application or algorithm will then end by proceeding to step 418. If the cutter being considered is not the last cutter, the software application or algorithm will return to step 406.
At step 502 a wide variety of downhole drilling parameters such as revolutions per minute and weight on bit may be input into a computer program or algorithm incorporating teachings of the present disclosure. Additional examples of such downhole drilling parameters or downhole drilling conditions are shown in Appendix A. Drilling equipment data, wellbore data and formation data may be included in step 502.
At step 504 the total number of cutters for the drill bit design selected in step 502 may be input into the software program or algorithm. At step 506 the maximum designed wear or expected wear for the primary cutter in each pair of cutters may be input into the software program or algorithm. At step 508 various geometric parameters for both the primary and secondary cutters such as cutter diameter, protector diameter (if applicable) and cutter backrake angle may be inputted into the software application or algorithm. Additional cutter geometric parameters and/or design characteristics as previously discussed in this application may be inputted into the software application or algorithm.
At step 510 (if applicable) the length of each protector associated with the primary cutter and/or the secondary cutter may be calculated using the same formula as previously discussed with respect to step 412 in
At step 514 the angular degrees between the primary cutter and the secondary cutter may be calculated and input into the software application. At step 516 the rate of penetration at which the secondary cutter will contact adjacent formation materials may be calculated based on the designed wear or maximum wear depth of the primary cutter. At step 518 the calculated rate of penetration for contact by the secondary cutter is evaluated. If the rate of penetration of contact by the secondary cutter with the adjacent formation material is not satisfactory, the software application or algorithm will return to step 504. If the rate of penetration of contact by the secondary cutter is satisfactory, the software application or algorithm will proceed to step 520. At step 520 the software application or algorithm will determine if the cutter being evaluated is the last cutter. If the answer is YES, the software application or algorithm will proceed to step 522 and end. If the answer is NO, the software application or algorithm will return to step 504 and repeat steps 504 through 520 until all cutters have been evaluated.
Although the present disclosure and its advantages have been described in detail, it should be understood that various changes, substitutions and alternations can be made herein without departing from the spirit and scope of the disclosure as defined by the following claims.
This application is a Divisional of U.S. patent application Ser. No. 12/525,249 filed Jul. 30, 2009 now U.S. Pat. No. 8,210,288, which is a U.S. National Stage Application of International Application No. PCT/US2008/052468 filed Jan. 30, 2008, which designates the United States of America, and claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application No. 60/887,459, filed Jan. 31, 2007, the contents of which are hereby incorporated by reference in their entirety.
| Number | Name | Date | Kind |
|---|---|---|---|
| 4397361 | Langford, Jr. | Aug 1983 | A |
| 5028177 | Meskin et al. | Jul 1991 | A |
| 5533582 | Tibbitts | Jul 1996 | A |
| 5595252 | O'Hanlon | Jan 1997 | A |
| 5815413 | Hively et al. | Sep 1998 | A |
| 5868213 | Cisneros et al. | Feb 1999 | A |
| 5947216 | Truax et al. | Sep 1999 | A |
| 6003623 | Miess | Dec 1999 | A |
| 6045440 | Johnson et al. | Apr 2000 | A |
| 6109368 | Goldman et al. | Aug 2000 | A |
| 6202770 | Jurewicz et al. | Mar 2001 | B1 |
| 6234261 | Evans et al. | May 2001 | B1 |
| 6374926 | Goldman et al. | Apr 2002 | B1 |
| 6408953 | Goldman et al. | Jun 2002 | B1 |
| 6581699 | Chen et al. | Jun 2003 | B1 |
| 6672406 | Beuershausen | Jan 2004 | B2 |
| 6845828 | Boyce | Jan 2005 | B2 |
| 6879947 | Glass | Apr 2005 | B1 |
| 6904984 | Estes et al. | Jun 2005 | B1 |
| 7083010 | Eppink et al. | Aug 2006 | B2 |
| 7703559 | Shen et al. | Apr 2010 | B2 |
| 20030015351 | Goldman et al. | Jan 2003 | A1 |
| 20040069531 | McCormick et al. | Apr 2004 | A1 |
| 20040134687 | Radford et al. | Jul 2004 | A1 |
| 20080091290 | Kubota et al. | Apr 2008 | A1 |
| Entry |
|---|
| International Search Report & Written Opinion; PCT/US2008/052468; pp. 12, Jun. 25, 2008. |
| Number | Date | Country | |
|---|---|---|---|
| 20130013267 A1 | Jan 2013 | US |
| Number | Date | Country | |
|---|---|---|---|
| 60887459 | Jan 2007 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 12525249 | US | |
| Child | 13540451 | US |
