US2823901A - Expansible rotary drilling tools - Google Patents

Expansible rotary drilling tools Download PDF

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US2823901A
US2823901A US545413A US54541355A US2823901A US 2823901 A US2823901 A US 2823901A US 545413 A US545413 A US 545413A US 54541355 A US54541355 A US 54541355A US 2823901 A US2823901 A US 2823901A
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cutter
teeth
casing
well bore
structures
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US545413A
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Archer W Kammerer
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    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B29/00Cutting or destroying pipes, packers, plugs, or wire lines, located in boreholes or wells, e.g. cutting of damaged pipes, of windows; Deforming of pipes in boreholes or wells; Reconditioning of well casings while in the ground
    • E21B29/002Cutting, e.g. milling, a pipe with a cutter rotating along the circumference of the pipe
    • E21B29/005Cutting, e.g. milling, a pipe with a cutter rotating along the circumference of the pipe with a radially-expansible cutter rotating inside the pipe, e.g. for cutting an annular window
    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B10/00Drill bits
    • E21B10/26Drill bits with leading portion, i.e. drill bits with a pilot cutter; Drill bits for enlarging the borehole, e.g. reamers
    • E21B10/32Drill bits with leading portion, i.e. drill bits with a pilot cutter; Drill bits for enlarging the borehole, e.g. reamers with expansible cutting tools
    • E21B10/322Drill bits with leading portion, i.e. drill bits with a pilot cutter; Drill bits for enlarging the borehole, e.g. reamers with expansible cutting tools cutter shifted by fluid pressure

Definitions

  • the present invention relates to drillingtools,and more particularly to tools usable in a Well bole to perform diverse operations therein, such as enlarging the diameter of the well bore or milling outatportion of the casing in the well bore.
  • any desirable drilling weight can be imposed thereon through the [agency of the-drill string to which 'the tool is secured. floweverpthe force available for expanding the cutters from their initially retractedposition to enlarge the Well here or to-severthe -casing"is liliiite'd.
  • Fig. 2 is ar longjitudinal section similar to Fig. 1, d'isclosing the critters -loclced in their fully expanded position;
  • Fig. 3 is an enlarged fragmentaryvi'eW- of a butter in c: performing 1 its s'evering action 611 casing;
  • Fig. 4' is an inside elevationai View of one ef the cutter to the lower erid ofithe string'of clrill 'pipe' B.
  • Thismandrel includes an upper kelly or drill stem rne'rnber -flslida'bly splined to the m ain body 13 of the drill 'bit.
  • the exterior of the loWer-portion LMof the kelly is non circular in 'shape, hei'ng telescopically received in 'a companion no'n-cir cular socket 15 fornied inthe'in-ainbit bo'dy13.
  • the mandrel 10 has a 'Iirnited range of longitudinal "movement Within the' bodyf its"downwa'rd movementbeing "cleterrnined by ng ageinent of the :loWer "end”"16 "of the kelly w'ith a "inwardly directed"body :shohldefIT, and its I upward movement being limitedibyengagement of an externalshoulder or'piston portion "1801? thekel'ly *With a cylinderheadliVsecured"tothebody.
  • the Upper end of thehead has a fiange 'Ztlengaging; abody shoulder pivotally mounted in'bodyslotsiil on hinge pins 28 and suitably “secured to 'the' body, to prevent their loss therefrom.
  • Each cutter-supporting meiiibef26 dependslfrom the "hinge piizs and carries a drag or milling cutter structure 29 at its lower end, which structure is specifically described hereinbelow.
  • each cutter supporting member 26 has an inclined expander surface 30 on its inner portion below the hinge pin 28 which tapers in a downward and inward direction.
  • Each expander surface terminates in a lock surface 31 formed on a lock portion 32 of the cutter supporting member.
  • This tubular member includes a lower portion 34 slidable within a guide bushing 35 mounted in a bridge 36 secured to the body and extending across the body slots 27. This guide bushing 35 is disposed below the lock portions 32 of the cutter supporting members 26.
  • a mandrel lock and expander 38 which has outer surfaces 39 adapted to engage the expander surfaces 30 and the lock surfaces 31.
  • the lock and expander 38 may be formed integral with the tubular member 33, the upper end of the latter being piloted within a socket 40 formed in the lower portion 14 of the kelly 12.
  • An enlarged boss 41 on the tubular member 33 engages a downwardly facing shoulder 42 of the kelly, the tubular member being held against this shoulder by a suitable split retainer or lock ring 43 snapped into an internal groove 44 encompassing the Kelly socket and engaging the lower end of the tubular member boss 41.
  • Drilling mud or other fluid can pass down through the central passage 45 in the kelly or drill stem 12 and into the central passage 46 extending completely through the tubular member 33. Leakage of fluid around the exterior of the tubular member 33 is prevented by a suitable side seal ring 47, such as a rubber O ring, in
  • the inclined expander surfaces 30 of the cutter supporting members 26 will be shifted upwardly along the lock and expander eoengaging lock surfaces 39, 31 be inclined slightly in a downward direction toward the axis of the tool, to insure release of the lock and the expander portion 38 from the cutter supporting members 26 when the latter and the cutter structures 29 are to be shifted to retracted position.
  • the relative longitudinal movement between the tubular mandrel 10 and the body 13 of the tool is accomplished hydraulically in the specific form of apparatus disclosed in the drawings.
  • the piston or enlarged portion 1.3 on the drill stem 12 is received within a counterbore 51 formed on the upper portion of the body of the tool.
  • This upper portion actually constitutes a cylinder 52 having a cylindrical wall 53 extending from a lower shoulder 54, defining the bottom of the counterbore 51, to the cylinder head 19.
  • a confined cylinder space 55 is formed between the piston portion 18 of the kelly, the periphery of the kelly above the piston, and the cylinder 52.
  • a suitable packing or side seal ring 56 may be disposed in a suitable piston ring groove 57 formed in the piston 18, which is adapted to slidably seal against the cylindrical wall 53 of the cylinder 52. Fluid is thereby prevented from passing in a downward direction between the piston and the cylinder.
  • fluid is prevented from passing in an upward direction out of the annular cylinder space 55 by an inner side seal ring 58 carried in an internal groove 59 in the cylinder head 19 and slidably and sealingly engaging the periphery of the kelly 12 above the piston 18, and also by an outer side seal ring 60 disposed in an external groove 61 in the head 19 and sealing engaging the cylinder wall 53.
  • Fluid under pressure in the string of drill pipe B and in the tubular mandrel passage 45 can be fed into the cylinder space 55 through one or more side ports 62 establishing communication between the central passage drel 10 is of arestricted diameter as compared to the portion 38 of the tubular member 33.
  • the cutter supporting members 26, and the cutter structures 29 carried thereby will be pivoted about the hinge pins 28 and urged in an outward direction.
  • the upward movement of the body 13 with respect to the tubular mandrel 10 can continue until the cutter structures 29 have been shifted outwardly to their fullest extent, as determined by engagement of stop shoulders 49 on the cutter supporting members 26 with companion shoulders 50 formed in the body on opposite sides of the body slots 27.
  • the lower end 16 of the kelly portion 12 of the tubular mandrel will engage the body shoulder 17, and the lock and expander 38 on the tubular member 33 will be disposed behind and in engagement with the lock portions 32 on the cutter supporting members 26.
  • the surfaces 31 of the lock portions 32 of the cutter supporting members 26 and the companion surfaces 39 on the lock and expander portion 38 of the tubular member are substantially parallel to the axis of the drill bit, to prevent the reactive forces
  • a set of diametrically opposed supporting members 26 and cutter structures 29 are employed, displaced substantially 180 degrees apart from each other. Actually, it is preferred to employ three sets of supporting members and supporting structures displaced substantially degrees from each other, to secure a smoothly running rotary expansible bit. The two sets of supporting member structures are shown in the interests of simplicity of the drawings.
  • Each cutter structure 29 is secured to the lower portion of a cutter supporting member 26 by use of welding material 79, which functionally integrates the cutter structure to the depending supporting member or leg 26.
  • the lower portion of the cutter structure has a plurality of depending legs '71, '72, 73 separated from one another by substantial spaces 74, the depending legs, in effect, constituting cutter teeth, which depend to substantially the same extent from the upper body portion 75 of the cutter structure.
  • the lower ends of the teeth 71, 72, 73 are preferably provided with hardfacing material 76, whereas the leading faces of the depending teeth are also provided with hardfacing material 77.
  • Such hardfacing material may be of any suitable type. However, it is found that the brazing of sintered tungsten carbide particles on the leading faces of the teeth, as well as on their bottom faces or surfaces, is very ifecti'vein milling away casing sections and in acting upon very hard formations.
  • each.cutter structure 29 has 'thre'edepe'nding legs or teeth 71, 72, 73. It is preferred to use aplurality "of teeth, in order to have a large cutting surface in contact the casing section or formation, after the cutter supporting members 26 and cutter structures 29 have been expanded ou'twardly to their maximum extent.
  • the necessary drilling weight can be imposed on the string of drill pipe B and on the rotary drill bit A itself, to secure aproper cutting away of the casing material "or of the formation.
  • the plurality of teeth may be, they offer a disadvantage in securing the initial severing cut in the casing D in view of the large surface that will contact the inner wall of thecasin'g and the relatively limited expanding force available for urging the cutters 29 from their retracted to their fully expanded posidons,
  • each cutter tooth 71, 72, 73 extends radially outward beyond the upper body portion 75 of the cutter structure 29, but that only some of the cutter teeth, such as the end teeth 71, 73, are capable of engaging the casing in efiecting its severing.
  • the end teeth 71, 73 are each provided with a layer of hardfiacing material 78 running lengthwise therealong from the lower end of the tooth to the region where the tooth emerges into the body portion 75 of the cutter structure, andthat such hardfacing material 73 extends radially outward of the cutter structure to a much greater extent than the intermediate tooth 72.
  • the intermediate tooth 72 isnot caused to perform any severihg action on the casing D, it is not even supplied with hardfacing material on its outer surface 72a Its outer surface is disposed inwardly of the outer surfaces 781; of the end teeth 71, 73 to a substantial extent, so that the outer fiace of the intermediate tooth cannot even engage the casing until the end teeth 71, 73 have completed the severing action on the casing.
  • the lower ends of the teeth will all lie substantially in the same plane when the cutter supporting members 26 and cutter structures 29 have been expanded outwardly 'to their maximum extent, whereas the outer surfaces 78a of the end teeth 71, 73 he on an arc of a circle that has a substantially greater nadius than the arc of the circle on which the outer surface 72a of the intermediate tooth lies.
  • the apparatus A In the operation of the apparatus A, it is run in the Well easing with the cutter supporting members 26 and the cutter structures 29 in their initial retracted position, such as shown in Fig. 1.
  • the lower portion of the body 13 of the apparatus may have a pilot structure 80 secured thereto, such pilot structure being constituted by circumferentially spaced, longitudinally extending blades 81 which are capable of riding along the wall of the easing D, to center the apparatus therewithin.
  • the pumps at the top of the well bore are started to pump fluid at a sufiicie'nt rate through the drill pipe B and into the mandrel passages 45, 46 building up a back pressure in the Kelly passage 45 and in the fluid in the ports 62 and cylinder space 55, which pressure will act upon the cylinder head 19 to urge the body 13, the cutter supporting members 26, and the cutter structures 29 in an upward direction with respect tothe mandrel 10.
  • each cutter structure extends along a substantial arc of easing, as is evident from an inspection of Fig. 5, the grooves 90 formed in the teeth being arcuately spaced from one another, so as to insure the stable positioning of each cutter structure 29 on top of the casing.
  • the fact that it is preferred to use three sets of cutter structures spaced 120 degrees apart means that there are nine cutter tooth grooves 91 receiving the upper end of the casing after the tool has been operated to some extent, which cause the teeth to embrace the casing at a large number of points around the latter.
  • the plurality of arcuately separated cutter teeth 71, 72, 73 in each cutter structure also provides a much greater cutting surface capable of simultaneous operation upon the well casing.
  • hardfacing material on the leading face 77 of each tooth capable of a cutting operation on the upwardly facing casing end E. Such hardfacing material is available and is effective until the casing has formed grooves 90 in the cutter teeth to their uppermost ends, where they are joined to the main steel body 75 of the cutter structure 29.
  • the cutter structure disclosed in Fig. 7 possesses more cutter teeth than that disclosed in Figs. 4 and 5.
  • the cutter structures disclosed in Fig. 7 have four cutter teeth 92, 93, 94, 95 arcuately separated from each other, with their leading faces 77 and bottom faces 76 provided with hardfacing material.
  • only alternate cutter teeth 92, 94 have their casing severing or reaming edges 78 provided with hardfacing material, these edges exi tending outwardly to a substantially greater extent than the outer edges 72a of the other cutter teeth 93, 95..
  • the hardface'd reamer edges 78 extend outwardly beyond the other outer tooth edges 72:: to an extent insuring severing of the casing before the un- .hardfaced outer edges 72a could engage the casing wall.
  • the unit force acting onthe reamer edges 78 to sever the casing is much higher than would be available if all four outer edges 78, 72a of the teeth 92 to 95 were permitted to engage the well casing in making the severing cut.
  • there are only two cutter teeth 9.2, 94 available to accomplish the severing action four spaced cutter teeth 92 to 95 are available for action upon the severed end B of the casing, which will permit a greater total drilling weight to be supplied on the tool, effective over a large number of cutting teeth, to cause the casing to be milled away at a comparatively rapid rate;
  • the outer surfaces 26 of the cutter supporting members will engage the casing above and adjacent the location where the severing cut was made, when the apparatus is elevated in the well bore, which will force the cutter supporting members 26 and cutters 29 inwardly, enabling the apparatus to be withdrawn through the'well casing D to the top of the well bore.
  • an expansible rotary drill bit has been provided in which a large tooth surface is available for action upon the severed end of a well or for action upon hard formation, when drilling weight can be imposed thereon.
  • a large tooth surface is available for action upon the severed end of a well or for action upon hard formation, when drilling weight can be imposed thereon.
  • only a portion of the cutter teeth are utilized to enhance the penetration of the cutter teeth into the casing, and effect its severing in a more expeditious manner.
  • the cutter teeth are widely separated from each other, to insure their being maintained free from cuttings by the fluid being circulated down through the drill pipe 3 and apparatus A, as well as in a cool state.
  • a main body mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and having lower cutting faces lying in the same plane so that all teeth and lower faces are adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth.
  • a main body comprising: a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth; the lower and leading faces of all teeth being hardfaced, said reaming surface being hardfaced and said corresponding outer surface of said another of said teeth being devoid of hardfacing.
  • a rotary drill bit to be lowered in a Well bore a main body; a supporting member pivotally mounted on said body; a drag cutter structure secured to the lower portion of said member; means for expanding said member and cutter structure laterally outward of said body; said drag cutter structure having a plurality of depending teeth arcuately spaced from each other and having their lower cutter faces lying in the same plane so that all teeth and lower faces are adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer longitudinal reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth.
  • a main body a supporting member pivotally mounted on said body; a drag cutter structure secured to the lower portion of said member; means for expanding said memher and cutter structure laterally outward of said body; said drag cutter structure having a plurality of depend ing teeth arcuately spaced from each other and having their lower faces adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer longitudinal reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth; the lower and leading faces of all teeth being hardfaced, said reaming surface being h-ardfaced and said corresponding outer surface of said another of said teeth being devoid of hardfacing.
  • a main body to be lowered in a well bore: a main body; supporting members pivotally mounted on said body in equiangular circumferentially spaced relation; a drag cutter structure secured to the lower portion of each of said members; means for expanding said members and cutter structures laterally outward of said body; each of said drag cutter structures having a plurality of depending teeth arcuately spaced from each other and having their lower faces adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth of each cutter structure having an outer longitudinal reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth; the lower and leading faces of all teeth of all cutter structures being hardfaced, said reaming surface of all cutter structures being hardfaced and said corresponding outer surface of said another of said teeth of each cutter structure being devoid of hardfacing.
  • a main body comprising: a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and having lower cutting faces lying in the same plane so that all teeth and lower faces are adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; the outer reaming surfaces of alternate teeth extending radially outward to a substantially greater extent than the corresponding outer surface of each intervening tooth.
  • a main body a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward. of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the ad- Vance of said teeth; the outer reaming surfaces of alternate teeth extending radially outward to a substantially greater extent than the corresponding outer surface of each intervening tooth; the lower and leading faces of all teeth being hardfaced, said reaming surfaces being hardfaced, and said corresponding outer surface being devoid of hardfacing.
  • a main body to be lowered in a Well bore: a main body; supporting members pivotally mounted on said body in equiangular circumferentially spaced relation; a drag cutter structure secured to the lower portion of each of said members; means for expanding said members and cutter structures laterally outward of said body; each of said drag cutter structures having a plurality of depending teeth arcuately spaced from each other and having their lower faces adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; the outer reaming surfaces of alternate teeth of each cutter structure extending radially outward to a substantially greater extent than the corresponding outer surface of each intervening tooth; the lower and leading faces of all teeth of each cutter structure being hardfaced, said reaming surfaces of each cutter structure being hardfaced, and said corresponding outer surface of each cutter structure being devoid of hardfacing.

Description

Feb. 18, 1958 w, KAMMERER 2,823,901
EXPANSIBLE ROTARY DRILLING TOOLS v Filed Nov. 7, 1955 2 Sheets-Sheet 1 E0. 11 la r 3,
24 f B 25 D 6' D 25 59 35 V i Z 2/ INVENTOR.
BY a0 W 1477-0 new,
Feb. 18, 1958 A. w. KAMMERER 3 3 EXPANSIBLE ROTARY DRILLING TOOLS Filed Nov. 7, 1955 2 Sheets-Sheet 2 7 iv INVEN TOR. flea/5e mfia/w meze,
United States Patent The present invention relates to drillingtools,and more particularly to tools usable in a Well bole to perform diverse operations therein, such as enlarging the diameter of the well bore or milling outatportion of the casing in the well bore. h Rotary drill bitsof theexpansible type-are usedtoenlarge the diameter of the Well bore and to sever "and mill away a desired extent or length of casi'ng'therein. Such bits include cutters disposed initially in 're'tracted position, vvhere =are expanded outwardly to initially enlarge the well bore at-a particular-location,orto sever thecasing at a predetermined point, after which the expanded cutters are Reflective to-drill al1ead as the bit is rotated and gradually lowered in the Well bore. After the-cutters have been expandedfi any desirable drilling weight can be imposed thereon through the [agency of the-drill string to which 'the tool is secured. floweverpthe force available for expanding the cutters from their initially retractedposition to enlarge the Well here or to-severthe -casing"is liliiite'd. Such limited f'orce mightbe insufficient to securep-iproper penetration of t'he cut-tersin the material being operated mien and could require considerahlenime for'the cutters to make a "s'evering cuti'n easing," or to be"expanded to *their maximum extent in very "hard formations. This; "is' p'artic'tilarl-y true of themse of cutters havinglkirge tooth for *engagetnent with the formation or severed en'cl o'f the casing after the cutters linve been eipandedn'o their maximurnextent. For "eX zimpleQit is tlesirablet'o have a'large' toothsiirfaee in contact with the severed endof "e: casing s'ince greater d'rilling weights-canheimposed ion "the" cutters to mill the ca'sing away more rapidly, While the critters still "gitis'se-s's a lo'n'g useful life. Suclflar'ge "tooth surfacesvvould also erigagethe casing Wall when "makiri'ga severing cut in the casingyan'd since 'the cutter *bXp'anding 'fo'ree is'limited, such-force, spread ov'era large 'surfac'e, wo'u'ld'r e'sult in slow progress being made 111"SV- *erin'g the easing.
-Accordingly;-it is an'object of the present invention to pro'vide'nn*eiipandiblerotary drill bit'having a relatively large totaldown-surface available for enlarging thewell here "-or milling awa casing in a Well bore after the "cutter-shave beenexpanded, in which the effectiveness "of a limited cutter expansion force in penetratingthe cutters into the w alhofe formationor of a casing isgreatly -An'o'th'erobject of the invention is to 'provide anexpandible 'rotary "drill bit embodying cutters capable of effectivedperationupon casing and very hard'for'mations, the eutterspossessing great strength and longlife, and
capable of easy rna'intenance, free'from cuttings and "in 'ice 2 of casing, the bit=cutters ceacting with the casing to center the bit in the latter and insure its stable operation.
This invention i possesses many other advantages, and has other objects which may lie-made more clearlyapparent froma considerationof several formsin which it may be embodied. These forms are-showninthe drewings accompanyingand-forming,part of the present specification. --'lhe '--will-n0W be described'in detaih' fo'c the purposeofi illustrating the'general' principles of the'inven- -ticn; but it is- -to beluntlerstoodthat s'uchidetailed description is not to-be taken ina limiting sense, since th'e scope of the invention 'is 'bestdefined by the =appended i claims.
Refe'rring to the drawings :Figure 1 1 -isa' longitudinal section through ian "embodiment-of the l invention disposed in 21 Well casing; with :the cutter-s 'arid=other ;parts occupying their =initial retracted ;'positions;
Fig. 2 is ar longjitudinal section similar to Fig. 1, d'isclosing the critters -loclced in their fully expanded position;
Fig. 3 is an enlarged fragmentaryvi'eW- of a butter in c: performing 1 its s'evering action 611 casing;
Fig. 4'is an inside elevationai View of one ef the cutter to the lower erid ofithe string'of clrill 'pipe' B. Thismandrel includes an upper kelly or drill stem rne'rnber -flslida'bly splined to the m ain body 13 of the drill 'bit. The exterior of the loWer-portion LMof the kelly is non circular in 'shape, hei'ng telescopically received in 'a companion no'n-cir cular socket 15 fornied inthe'in-ainbit bo'dy13. spe'eificall'y, the Kellyexterior and the-socket "15 may be of liexagonalshape, to =enz'ible the kelly 12 "to be' moved longitudinally vvith res ect to 'the body "13, while's'till being capable of transmitting rotary motion to i the bddy. The mandrel 10" has a 'Iirnited range of longitudinal "movement Within the' bodyf its"downwa'rd movementbeing "cleterrnined by ng ageinent of the :loWer "end""16 "of the kelly w'ith a "inwardly directed"body :shohldefIT, and its I upward movement being limitedibyengagement of an externalshoulder or'piston portion "1801? thekel'ly *With a cylinderheadliVsecured"tothebody. "The Upper end of thehead has a fiange 'Ztlengaging; abody shoulder pivotally mounted in'bodyslotsiil on hinge pins 28 and suitably "secured to 'the' body, to prevent their loss therefrom. Each cutter-supporting meiiibef26 dependslfrom the "hinge piizs and carries a drag or milling cutter structure 29 at its lower end, which structure is specifically described hereinbelow.
The cutter supporting members 26 and the cutter structures 29 themselves tend to occupy a retracted position substantially entirely within the confines of the main body 13 of the bit. These cutter supporting members and the cutter structures are expandible outwardly, to sever the casing and mill it away by operating upon the upper end E of the casing therebelow. To accomplish the expansion, each cutter supporting member 26 has an inclined expander surface 30 on its inner portion below the hinge pin 28 which tapers in a downward and inward direction. Each expander surface terminates in a lock surface 31 formed on a lock portion 32 of the cutter supporting member. The outward expansion is accomplished by producing relative longitudinal movement between the mandrel 10 and the bit body 13, which will produce relative longitudinal movement between the cutter supporting members 26 and the tubular member 33 of the mandrel it}. This tubular member includes a lower portion 34 slidable within a guide bushing 35 mounted in a bridge 36 secured to the body and extending across the body slots 27. This guide bushing 35 is disposed below the lock portions 32 of the cutter supporting members 26.
Located initially substantially above the guide bushing 35 and below the hinge pins 28, and in cutter member recesses 37, is a mandrel lock and expander 38 which has outer surfaces 39 adapted to engage the expander surfaces 30 and the lock surfaces 31. The lock and expander 38 may be formed integral with the tubular member 33, the upper end of the latter being piloted within a socket 40 formed in the lower portion 14 of the kelly 12. An enlarged boss 41 on the tubular member 33 engages a downwardly facing shoulder 42 of the kelly, the tubular member being held against this shoulder by a suitable split retainer or lock ring 43 snapped into an internal groove 44 encompassing the Kelly socket and engaging the lower end of the tubular member boss 41.
Drilling mud or other fluid can pass down through the central passage 45 in the kelly or drill stem 12 and into the central passage 46 extending completely through the tubular member 33. Leakage of fluid around the exterior of the tubular member 33 is prevented by a suitable side seal ring 47, such as a rubber O ring, in
. a peripheral groove 48 in the kelly, which engages the interior of the boss 41.
Assuming that the body 13 of the tool is elevated relatively along the tubular mandrel 10, the inclined expander surfaces 30 of the cutter supporting members 26 will be shifted upwardly along the lock and expander eoengaging lock surfaces 39, 31 be inclined slightly in a downward direction toward the axis of the tool, to insure release of the lock and the expander portion 38 from the cutter supporting members 26 when the latter and the cutter structures 29 are to be shifted to retracted position.
The relative longitudinal movement between the tubular mandrel 10 and the body 13 of the tool is accomplished hydraulically in the specific form of apparatus disclosed in the drawings. Thus, the piston or enlarged portion 1.3 on the drill stem 12 is received within a counterbore 51 formed on the upper portion of the body of the tool. This upper portion actually constitutes a cylinder 52 having a cylindrical wall 53 extending from a lower shoulder 54, defining the bottom of the counterbore 51, to the cylinder head 19.
A confined cylinder space 55 is formed between the piston portion 18 of the kelly, the periphery of the kelly above the piston, and the cylinder 52. A suitable packing or side seal ring 56 may be disposed in a suitable piston ring groove 57 formed in the piston 18, which is adapted to slidably seal against the cylindrical wall 53 of the cylinder 52. Fluid is thereby prevented from passing in a downward direction between the piston and the cylinder. Similarly, fluid is prevented from passing in an upward direction out of the annular cylinder space 55 by an inner side seal ring 58 carried in an internal groove 59 in the cylinder head 19 and slidably and sealingly engaging the periphery of the kelly 12 above the piston 18, and also by an outer side seal ring 60 disposed in an external groove 61 in the head 19 and sealing engaging the cylinder wall 53.
Fluid under pressure in the string of drill pipe B and in the tubular mandrel passage 45 can be fed into the cylinder space 55 through one or more side ports 62 establishing communication between the central passage drel 10 is of arestricted diameter as compared to the portion 38 of the tubular member 33. During such upward shifting, the cutter supporting members 26, and the cutter structures 29 carried thereby, will be pivoted about the hinge pins 28 and urged in an outward direction. The upward movement of the body 13 with respect to the tubular mandrel 10 can continue until the cutter structures 29 have been shifted outwardly to their fullest extent, as determined by engagement of stop shoulders 49 on the cutter supporting members 26 with companion shoulders 50 formed in the body on opposite sides of the body slots 27. When such engagement occurs, the lower end 16 of the kelly portion 12 of the tubular mandrel will engage the body shoulder 17, and the lock and expander 38 on the tubular member 33 will be disposed behind and in engagement with the lock portions 32 on the cutter supporting members 26.
It is to be noted that the surfaces 31 of the lock portions 32 of the cutter supporting members 26 and the companion surfaces 39 on the lock and expander portion 38 of the tubular member are substantially parallel to the axis of the drill bit, to prevent the reactive forces As a practical matter, it is preferred that the passage 45 through the kelly portion of the mandrel. As a result, the pumping of drilling mud, or other fluid, at an adequate rate through the apparatus will build up a back pressure of fluid in the passage 45, which pressure will be imposed on the fluid in the cylinder space 55, acting upon the cylinder head 19 to urge the body 13 of the tool in an upward direction with respect to the tubular mandrel 10, to secure the outward expansion of the cutter supporting member 26 and cutter structures 29 to their fullest extent, as above described.
As apparently disclosed in the drawings, a set of diametrically opposed supporting members 26 and cutter structures 29 are employed, displaced substantially 180 degrees apart from each other. Actually, it is preferred to employ three sets of supporting members and supporting structures displaced substantially degrees from each other, to secure a smoothly running rotary expansible bit. The two sets of supporting member structures are shown in the interests of simplicity of the drawings. Each cutter structure 29 is secured to the lower portion of a cutter supporting member 26 by use of welding material 79, which functionally integrates the cutter structure to the depending supporting member or leg 26. The lower portion of the cutter structure has a plurality of depending legs '71, '72, 73 separated from one another by substantial spaces 74, the depending legs, in effect, constituting cutter teeth, which depend to substantially the same extent from the upper body portion 75 of the cutter structure. The lower ends of the teeth 71, 72, 73 are preferably provided with hardfacing material 76, whereas the leading faces of the depending teeth are also provided with hardfacing material 77. Such hardfacing material may be of any suitable type. However, it is found that the brazing of sintered tungsten carbide particles on the leading faces of the teeth, as well as on their bottom faces or surfaces, is very ifecti'vein milling away casing sections and in acting upon very hard formations.
As specifically disclosed in Figs.'4 and 5,feach.cutter structure 29 has 'thre'edepe'nding legs or teeth 71, 72, 73. it is preferred to use aplurality "of teeth, in order to have a large cutting surface in contact the casing section or formation, after the cutter supporting members 26 and cutter structures 29 have been expanded ou'twardly to their maximum extent. The necessary drilling weight can be imposed on the string of drill pipe B and on the rotary drill bit A itself, to secure aproper cutting away of the casing material "or of the formation. However desirable the plurality of teeth may be, they offer a disadvantage in securing the initial severing cut in the casing D in view of the large surface that will contact the inner wall of thecasin'g and the relatively limited expanding force available for urging the cutters 29 from their retracted to their fully expanded posidons,
The present invention overcomes the aforeuoted disadvantage by causing a lesser number of teeth to engage the casing D and make the severing cut than are available to engage the casing at E after it has been severed, and when drilling weight can be imposed in a downward direction on the cutters 29. Thus, it will be noted that each cutter tooth 71, 72, 73 extends radially outward beyond the upper body portion 75 of the cutter structure 29, but that only some of the cutter teeth, such as the end teeth 71, 73, are capable of engaging the casing in efiecting its severing. As specifically disclosed, the end teeth 71, 73 are each provided with a layer of hardfiacing material 78 running lengthwise therealong from the lower end of the tooth to the region where the tooth emerges into the body portion 75 of the cutter structure, andthat such hardfacing material 73 extends radially outward of the cutter structure to a much greater extent than the intermediate tooth 72. As a matter of fact, since the intermediate tooth 72 isnot caused to perform any severihg action on the casing D, it is not even supplied with hardfacing material on its outer surface 72a Its outer surface is disposed inwardly of the outer surfaces 781; of the end teeth 71, 73 to a substantial extent, so that the outer fiace of the intermediate tooth cannot even engage the casing until the end teeth 71, 73 have completed the severing action on the casing. V
The lower ends of the teeth will all lie substantially in the same plane when the cutter supporting members 26 and cutter structures 29 have been expanded outwardly 'to their maximum extent, whereas the outer surfaces 78a of the end teeth 71, 73 he on an arc of a circle that has a substantially greater nadius than the arc of the circle on which the outer surface 72a of the intermediate tooth lies.
In the operation of the apparatus A, it is run in the Well easing with the cutter supporting members 26 and the cutter structures 29 in their initial retracted position, such as shown in Fig. 1. The lower portion of the body 13 of the apparatus may have a pilot structure 80 secured thereto, such pilot structure being constituted by circumferentially spaced, longitudinally extending blades 81 which are capable of riding along the wall of the easing D, to center the apparatus therewithin. When the apparatus has been lowered to the desired point in the well casing D at which the latter is to be severed, the pumps at the top of the well bore are started to pump fluid at a sufiicie'nt rate through the drill pipe B and into the mandrel passages 45, 46 building up a back pressure in the Kelly passage 45 and in the fluid in the ports 62 and cylinder space 55, which pressure will act upon the cylinder head 19 to urge the body 13, the cutter supporting members 26, and the cutter structures 29 in an upward direction with respect tothe mandrel 10.
During such upward movement, the expander surfaces Cit 30 on thecutter supportihgme'mb'e'rs 29 are brought to bear against the lock and expander 'p'ortiojn38 of the mandrel, the cutter structures being urged in an putward direction against the wall of the well casing. The drill pipe B and therotary drill bit A e erged at proper speeds while fluid is being pumped through the apparatus, the outer casing severing "or reaming edges 78 ofthe cutter teeth 71, 73 acting upon'the wall of the casing and gradually milling it away. *During this operation, the apparatus is retained in the same-longitudinal osh tion in the well casing. As the casing is cut away, the hydraulic force acting upon the body raises it and the cutter supporting members 26 and cutter structures 29 to a further extent, until the retainer edges 78of the cutter teeth 71, 73 have completely severed the casing. Such severing action will occur before the outer face 72a of the intermediate cutter teeth 72 can engag theinner wall of the'casing D. Thereafter, rotation of the drill pipe B and therotary drill bit A continues, so that the reamer edges 78 continue to cut away the casing and dig into the formation, until the cutters 29 have been-fully expanded outwardly to the maximum extent, as determined by engagement 'of the stop shoulders mend the lower end 16 of the Kelly portion of the mandrel with the body shoulder 17. With the parts in this position, the lock portion 32 of'the cutter supporting member 26 will bear against the lock and expander portion 38 of the tubular member 33 to preelude inadvertent partial retraction of the cutter structures 29 from their fully expanded position;
Dow'nweight ofthe proper amount is new imposed on the string of drill pipe B, this downweig'ht being transmitted through the kelly 12to thebod'y shoulder 17, and from the body through the stop'shoulder-s 50, 45 directly to the supporting members 26 and the cutter structures 29, urging the three blades 71, 72, 73 of each cutter 29 against the upwardly facing severed end E of the Well casing D. It is evident that a greater number of teeth and surfaces are not available for 'a milling action upon the upper end B of the casing than was used in severing the casing. Assuming that three sets of supporting members 26 and cutter structures 29 are used, each cutter structure 29 having the configuration disclosed in Figs. 4 and 5, a total of nine cutter teeth will be available for action upon the severed end E of the casing. With such large number of cutter teeth, and in view of the extent of their bottom faces 76, a relatively large drilling weight can be imposed upon the cutterteeth to cause a relative rapid milling away of the casing .D. The drilling weight can be varied within wide ranges. However, since the expanding force in making the severing cut on the casing is limited to the hydraulic pressure that can be,
ing force over a lesser number of teeth 71, 73 than are used in milling away the casing after it has been severed, means that a greater unit penetrating pressure is being; supplied on the reamer edges 78 of the teeth 71, '73 than would be present if the intermediate tooth 72 were alsomade eifective in performing the casing severing action. With such latter tooth 72 active, inadequate penetration into the casing wall might result.
It is to be noted that there are relatively wide spaces 74 between the depending teeth 71, 72, 73. Accordingly, the cuttings that the teeth produce can readily be flushed from between them by the drilling fluid circulated down:
fluid will maintain the teeth in a cool condition, to enhance their life. 7 V p As'the bottomends 76 of the teeth operate upon the casing section, the latter will be gradually milled away in a downward direction. During the milling action, the casing itself may wear grooves 90 in the casing teeth (Fig. 6), the grooves extending upwardly from their lower ends 76 with the side walls 91 of the grooves of the teeth closely sliding along the inner and outer surfaces of the casing D. Such grooves are of advantage in connection with the stabiblity in the operation of the apparatus, since it assists the pilot portion 80 in centering the bit in the well casing, to insure its smooth oepration. The multiple cutter teeth 71, 72, 73 of each cutter structure extend along a substantial arc of easing, as is evident from an inspection of Fig. 5, the grooves 90 formed in the teeth being arcuately spaced from one another, so as to insure the stable positioning of each cutter structure 29 on top of the casing. In addition, the fact that it is preferred to use three sets of cutter structures spaced 120 degrees apart means that there are nine cutter tooth grooves 91 receiving the upper end of the casing after the tool has been operated to some extent, which cause the teeth to embrace the casing at a large number of points around the latter. The use of a plurality of arcuately spaced cutter teeth in each cutter structure, and of a plurality of structures, all assist in the stability in the operation of the apparatus in milling away casing sections in a well bore, and increases the efficiency of the tool. In actual practice, the apparatus disclosed has been capable of milling away hard casings in a well bore in a comparatively rapid manner.
The plurality of arcuately separated cutter teeth 71, 72, 73 in each cutter structure also provides a much greater cutting surface capable of simultaneous operation upon the well casing. As the cutter teeth wear away, there is effective hardfacing material on the leading face 77 of each tooth capable of a cutting operation on the upwardly facing casing end E. Such hardfacing material is available and is effective until the casing has formed grooves 90 in the cutter teeth to their uppermost ends, where they are joined to the main steel body 75 of the cutter structure 29.
The cutter structure disclosed in Fig. 7 possesses more cutter teeth than that disclosed in Figs. 4 and 5. Actually, the cutter structures disclosed in Fig. 7 have four cutter teeth 92, 93, 94, 95 arcuately separated from each other, with their leading faces 77 and bottom faces 76 provided with hardfacing material. However, only alternate cutter teeth 92, 94 have their casing severing or reaming edges 78 provided with hardfacing material, these edges exi tending outwardly to a substantially greater extent than the outer edges 72a of the other cutter teeth 93, 95.. As was described in connection with the cutter structure shown in Fig. 5, the hardface'd reamer edges 78 extend outwardly beyond the other outer tooth edges 72:: to an extent insuring severing of the casing before the un- .hardfaced outer edges 72a could engage the casing wall.
Accordingly, in Fig. 7, the unit force acting onthe reamer edges 78 to sever the casing is much higher than would be available if all four outer edges 78, 72a of the teeth 92 to 95 were permitted to engage the well casing in making the severing cut. Despite the fact that there are only two cutter teeth 9.2, 94 available to accomplish the severing action, four spaced cutter teeth 92 to 95 are available for action upon the severed end B of the casing, which will permit a greater total drilling weight to be supplied on the tool, effective over a large number of cutting teeth, to cause the casing to be milled away at a comparatively rapid rate;
When it is desired to retrieve the apparatus A from the well bore afterthe hole enlarging operation has been completed, or as a result of the cutter teeth becoming worn, it is only necessary to discontinue the pumping of the drilling fluid through the drill pipe Bend the apparatus A, to relieve the pressure on the cylinder 52, and elevate the drill pipe B. Such elevating movement will elevate the tubular mandrel with respect to the body 13 and the cutter supporting members 26 to raise the lock and expander portion 38 above the expander surfaces 30, whereupon the cutter structures 29 can drop back to their retracted position, such as disclosed in Fig. 1. In the event the cutters 29 are reluctant to move to such position, the outer surfaces 26 of the cutter supporting members will engage the casing above and adjacent the location where the severing cut was made, when the apparatus is elevated in the well bore, which will force the cutter supporting members 26 and cutters 29 inwardly, enabling the apparatus to be withdrawn through the'well casing D to the top of the well bore.
It is, accordingly, apparent that an expansible rotary drill bit has been provided in which a large tooth surface is available for action upon the severed end of a well or for action upon hard formation, when drilling weight can be imposed thereon. However, during the initial expansion of its cutters, as in making a severing cut of the casing, only a portion of the cutter teeth are utilized to enhance the penetration of the cutter teeth into the casing, and effect its severing in a more expeditious manner. The cutter teeth are widely separated from each other, to insure their being maintained free from cuttings by the fluid being circulated down through the drill pipe 3 and apparatus A, as well as in a cool state. The use of a plurality of cutter teeth on each cutter structure, arcuately separated from each other, causes the severed end B of the casing to form grooves along arcuately spaced portions of the teeth of the cutter structure, which insures the centering of the apparatus in the well casing and stability in its operation therewithin.
T he inventor claims:
1. In a rotary drill bit to be lowered in a Well bore: a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and having lower cutting faces lying in the same plane so that all teeth and lower faces are adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth.
2. In a rotary drill bit to be lowered in a well bore: a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth; the lower and leading faces of all teeth being hardfaced, said reaming surface being hardfaced and said corresponding outer surface of said another of said teeth being devoid of hardfacing.
3. In a rotary drill bit to be lowered in a Well bore; a main body; a supporting member pivotally mounted on said body; a drag cutter structure secured to the lower portion of said member; means for expanding said member and cutter structure laterally outward of said body; said drag cutter structure having a plurality of depending teeth arcuately spaced from each other and having their lower cutter faces lying in the same plane so that all teeth and lower faces are adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer longitudinal reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth.
4. In a rotary drill bit as defined in claim 3; wherein said reaming surface is hardfaced and said corresponding outer surface of said another of said teeth is devoid of hardfacing material.
5. In a rotary drill bit to be lowered in a well bore: a main body; a supporting member pivotally mounted on said body; a drag cutter structure secured to the lower portion of said member; means for expanding said memher and cutter structure laterally outward of said body; said drag cutter structure having a plurality of depend ing teeth arcuately spaced from each other and having their lower faces adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth having an outer longitudinal reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth; the lower and leading faces of all teeth being hardfaced, said reaming surface being h-ardfaced and said corresponding outer surface of said another of said teeth being devoid of hardfacing.
6. In a rotary drill bit to be lowered in a well bore: a main body; supporting members pivotally mounted on said body in equiangular circumferentially spaced relation; a drag cutter structure secured to the lower portion of each of said members; means for expanding said members and cutter structures laterally outward of said body; each of said drag cutter structures having a plurality of depending teeth arcuately spaced from each other and having their lower faces adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; at least one of said teeth of each cutter structure having an outer longitudinal reaming surface extending radially outward to a substantially greater extent than the corresponding outer surface of another of said teeth; the lower and leading faces of all teeth of all cutter structures being hardfaced, said reaming surface of all cutter structures being hardfaced and said corresponding outer surface of said another of said teeth of each cutter structure being devoid of hardfacing.
7. In a rotary drill bit to be lowered in a well bore: a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and having lower cutting faces lying in the same plane so that all teeth and lower faces are adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; the outer reaming surfaces of alternate teeth extending radially outward to a substantially greater extent than the corresponding outer surface of each intervening tooth.
8. In a rotary dril bit to be lowered in a Well bore: a main body; cutter means mounted on said body for expansion laterally outward of said body; means for expanding said cutter means laterally outward. of said body; said cutter means including a drag cutter structure having a plurality of depending teeth arcuately spaced from each other and adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the ad- Vance of said teeth; the outer reaming surfaces of alternate teeth extending radially outward to a substantially greater extent than the corresponding outer surface of each intervening tooth; the lower and leading faces of all teeth being hardfaced, said reaming surfaces being hardfaced, and said corresponding outer surface being devoid of hardfacing.
9. In a rotary drill bit to be lowered in a Well bore: a main body; supporting members pivotally mounted on said body in equiangular circumferentially spaced relation; a drag cutter structure secured to the lower portion of each of said members; means for expanding said members and cutter structures laterally outward of said body; each of said drag cutter structures having a plurality of depending teeth arcuately spaced from each other and having their lower faces adapted for simultaneous operation upon a shoulder formed in the well bore which opposes the advance of said teeth; the outer reaming surfaces of alternate teeth of each cutter structure extending radially outward to a substantially greater extent than the corresponding outer surface of each intervening tooth; the lower and leading faces of all teeth of each cutter structure being hardfaced, said reaming surfaces of each cutter structure being hardfaced, and said corresponding outer surface of each cutter structure being devoid of hardfacing.
References Cited in the file of this patent UNITED STATES PATENTS 710,935 Avery Oct. 14, 1902 1,485,642 Stone Mar. 4, 1924 2,644,673 Baker July 7, 1953
US545413A 1955-11-07 1955-11-07 Expansible rotary drilling tools Expired - Lifetime US2823901A (en)

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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2976927A (en) * 1958-05-08 1961-03-28 Rotary Oil Tool Company Rotary drill bits and cutters
DE1152979B (en) * 1961-04-08 1963-08-22 Archer William Kammerer Device for reworking boreholes
US3196960A (en) * 1963-03-19 1965-07-27 Lamphere Jean K Fluid pressure expansible drill bits
EP0298663A2 (en) * 1987-07-08 1989-01-11 Tri-State Oil Tool (UK), a division of Baker Hughes Limited Downhole cutting tool
EP0298537A2 (en) * 1987-06-25 1989-01-11 Shell Internationale Researchmaatschappij B.V. Device and method for underreaming a borehole
US5456312A (en) * 1986-01-06 1995-10-10 Baker Hughes Incorporated Downhole milling tool
US20030029644A1 (en) * 2001-08-08 2003-02-13 Hoffmaster Carl M. Advanced expandable reaming tool
US20130146361A1 (en) * 2011-12-13 2013-06-13 Smith International, Inc. Apparatuses and methods for stabilizing downhole tools

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US710935A (en) * 1901-03-05 1902-10-14 Addison Avery Rock-drill.
US1485642A (en) * 1922-04-11 1924-03-04 Diamond Drill Contracting Comp Expanding rotary reamer
US2644673A (en) * 1949-09-26 1953-07-07 Baker Oil Tools Inc Expansible rotary drill bit and cutter

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US710935A (en) * 1901-03-05 1902-10-14 Addison Avery Rock-drill.
US1485642A (en) * 1922-04-11 1924-03-04 Diamond Drill Contracting Comp Expanding rotary reamer
US2644673A (en) * 1949-09-26 1953-07-07 Baker Oil Tools Inc Expansible rotary drill bit and cutter

Cited By (19)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2976927A (en) * 1958-05-08 1961-03-28 Rotary Oil Tool Company Rotary drill bits and cutters
DE1152979B (en) * 1961-04-08 1963-08-22 Archer William Kammerer Device for reworking boreholes
US3196960A (en) * 1963-03-19 1965-07-27 Lamphere Jean K Fluid pressure expansible drill bits
US5456312A (en) * 1986-01-06 1995-10-10 Baker Hughes Incorporated Downhole milling tool
US5899268A (en) * 1986-01-06 1999-05-04 Baker Hughes Incorporated Downhole milling tool
US5810079A (en) * 1986-01-06 1998-09-22 Baker Hughes Incorporated Downhole milling tool
EP0298537A2 (en) * 1987-06-25 1989-01-11 Shell Internationale Researchmaatschappij B.V. Device and method for underreaming a borehole
EP0298537A3 (en) * 1987-06-25 1989-04-12 Shell Internationale Research Maatschappij B.V. Device and method for underreaming a borehole
EP0298663A3 (en) * 1987-07-08 1990-01-03 Tri-State Oil Tool (UK), a division of Baker Hughes Limited Downhole cutting tool
EP0298663A2 (en) * 1987-07-08 1989-01-11 Tri-State Oil Tool (UK), a division of Baker Hughes Limited Downhole cutting tool
US20030029644A1 (en) * 2001-08-08 2003-02-13 Hoffmaster Carl M. Advanced expandable reaming tool
US20040154836A1 (en) * 2001-08-08 2004-08-12 Hoffmaster Carl M. Advanced expandable reaming tool
US7451836B2 (en) 2001-08-08 2008-11-18 Smith International, Inc. Advanced expandable reaming tool
US7451837B2 (en) 2001-08-08 2008-11-18 Smith International, Inc. Advanced expandable reaming tool
US20130146361A1 (en) * 2011-12-13 2013-06-13 Smith International, Inc. Apparatuses and methods for stabilizing downhole tools
US9051793B2 (en) * 2011-12-13 2015-06-09 Smith International, Inc. Apparatuses and methods for stabilizing downhole tools
US9488009B2 (en) * 2011-12-13 2016-11-08 Smith International, Inc. Apparatuses and methods for stabilizing downhole tools
GB2513029B (en) * 2011-12-13 2019-03-13 Smith International Apparatuses and methods for stabilizing downhole tools
NO347136B1 (en) * 2011-12-13 2023-05-30 Smith International Apparatus and methods for stabilizing tools down the borehole

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