US1971473A - Well drilling equipment for handling drill pipe and casing in high pressure wells - Google Patents

Description

*Au .'2s, 1934.-

L. E. ZERBE ET AL WELL DRILLING EQUIPMENT FOR HANDLING DRILL PIPE AND CASING IN HIGH PRESSURE WELLS Filed Oct. 19. 1931 6- Sheets-Sheet l Inventors Allarnqyi Aug. 28, 1934. E, ZERBE ET AL 1,971,473 WELL DRILLING E UIPMENT FOR HANDLING DRILL PIPE AND CASING IN HIGH PRESSURE WELLS Filed Oct. 6 Sheets-Sheet 2 Inventor;

- Alnnnqs Aug. 28, 1934. E. ZERBE in AL 7,

WELL DRILLIN EQUIPMENT FOR HANDLING DRILL PIPE AND CASING IN HIGH PRESSURE WELLS Filed 001:. 19. 1931 6 Sheets-Sheet 3g xd 55 55 a 5 53 78 Juana-y;

' Inventor I Aug. 28, 1934'. L. EQZERBE ET A 1,971,473

WELL DRILLING EQUIPMENT FOR HANDLING D RILL PIPE AND casma IN HIGH PRESSURE WELLS Filed Oct. 19. 1931 6 Sheets-Sheet 4 11 M 5 a Il 15 1'5 15 f; ii

Inventors .{imafinaaualgdl MM: rg

W 5" Attorney Aug. 28, 1934. I

L. E. ZERBE ET AL -WELL DRILLING EQUIPMENT FOR HANDLING DRILL PIPE AND CASING IN HIGHTRESSURE WELLS Filed Oct. 19. 1931 6 Sheets-Sheet 5 5i1 1 1.1LJ O 21 11 m ors 1-1 t/orneyf,

ET AL 1,971,473 0R HANDLING DRILLSSURE WELLS 1 m1 F wmw B H m t 54m e n LNMF um EN A ml P W Aug. 28, 1934.

, 6 Sheets-Sheet 6 Inventor;

Patented Aug. 28, 1934 WELL panama EQUIPMENT FOR HAN-' DLING palm. PIPE AND CASING IN mun PRESSURE WELLS Lewis Emanuel Zerbe, Moneta, and Edward Tlmbs, Los Angeles, Calif., asslgnors, by memo assignments, to The National Superior Company, Toledo, Ohio, a corporation of Delaware Application October 19, 1931, Serial No. 569,648

.34 Claims.

This invention relates to well drilling equipment for handling drill pipe and casing in high pressure wells, and more particularly to apparatus for use in the drilling of oil, gas or like wells when using the rotary drilling process in areas where high pressure gas is found.

When drilling wells and high pressure gas is encountered, it is imperative that the high pressure gas be kept under control if the drilling operations are to be proceeded with.

In some areas gas under pressure of approximately 3,000 pounds per square inch has been encountered, and not only is drilling under this condition extremely difiicult, but is attended with many hazards.

In the usual drilling procedure, the drilling bit is rotated by the drill pipe with additional sections of drill pipe added as the well is deepened. When the bit requires redressing or replacement, the whole length of the drill pipe in the well hole is withdrawn in sections. When drilling under these high pressure conditions, the upward force on the drill stem or pipe at the top of the well tends to eject the pipe from the well and is sufliclent to overcome the weight of the submerged pipe and bit positioned within the well. Under these'conditions it is therefore necessary to actually hold the drill pipe down and to feed the drill pipe down rather thantq hold the drill pipe from falling under the force of gravity in the well.

It is therefore an object of this invention to provide an apparatus for handling and controlling the entry and withdrawal of drill pipe in the oil or gas well While the well is under relatively high gas pressure.

Another object of this invention is to provide a device for drilling oil wells wherein means are provided for automatically effecting the clamping actioii of the. drill pipe to support the weight of the same or to prevent 'the ejection of the drill pipe from the well in case the drilling crew abandons the well derrick in anticipation of some mishap.

Another object of this invention is to provide a device for clamping the drill pipe with the rotarydriving element for driving the drilling bit wherein, as the drill bit is rotated, it is fed downwardly at the same time.

' Another object of this invention is to provide a device for use in the drilling of wells which require drilling of the well under applied pressure, that is, where the hydrostatic fluid pressure of the drilling fluid or mud used is not adequate to prevent caving in of certain earth-formations, applied pressure is produced by the use of mud fluid pumps with a. return flow of the drilling fluid or mud. controlled through a valve to maintain the desired pressure on the well.

Other objects and advantages of this invention it is believed will be apparent from the following detailed description of a preferred embodiment thereofas illustrated in the accompanying draw- Figure 2 is a top plan view of the rotary ma- 7 chine table as embodied in our invention.

' Figure 3 is a sectional elevation taken substantially on the line 3-3 of Figure 2 illustrating the slips as in disengaged position.

Figure 4 is a fragmental sectional view of the operating head taken at 90 from the view thereof contained in Figure 3. I

Figure 5 is asectional view of the split table bushing taken substantiallypntheline 55 of Figure 2.

Figure 6 is a sectional top plan view illustrating the bushing locking means embodied in our invention, taken online 66 of Figure 5.

Figure '1 is an elevation partly in vertical midsection of another portion of the apparatus embodied in our invention illustrating the slips as disengaged.

Figure 8 is a top plan view partly in horizontal section of the structure illustrated in Figure '7 Figure 9 isan enlarged side elevation partly in vertical midsection of a portion of the apparatus embodied in our invention illustrated in Figure 7.

. S. Faulkner, filed May 28, 1930, Serial No. 456,395.

The hydraulic rotary machine table is so constructed that it may be elevated and lowered onhydraulic cylinders 4. Below thederrick 1 is acellar 4a within which a casing assembly is supported and in the casing 8 of which there is mounted acontrol valve 5 and blow-outpreventers 6 respectively. g

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Positioned on the top of the casing 8 is a stuflingbox assembly '7. Thecontrol valve 5 andblowout preventers 6 may be of any suitable or desir able' construction, and preferably of the type which are remotely controlled throughsprocket chain drives 9 and hand-wheels 10 which permits the actuation of the control valves and blow-out preventers from points accessible above the ground.

In the casing 8, below thecontrol valve 5, is aconduit 11 for the return circulating fluid which is pumped by means of slush pumps into thedrill stem 12 during the drilling operation.

Mounted within theconduit 11 is a valve 13, by means of which a back pressure may be imposed upon the drilling fluid or mud to enable drilling under greater pressures where required.

In drilling under pressure, it is preferable to utilize a flushjoint drill stem 12, so that thedrill stem 12 may pass through the stufling box '7 without having any obstruction, such as couplings or pipe joints, which would be required to pass through thestuifing box 7.

In carrying out the drilling process, a swivel of any suitable or desirable construction well understood in the art, but not shown, is connected to the upper end of the rotary drill stem orpipe 12 and is also connected with drilling fluid or mud circulating pumps likewise not shown in the usual manner.

Therotary machine 3 includes a customary base and rotary table which is rotatably supported upon the base and is generally indicated at 14.

A split table bushing 15, of a construction which will be hereinafter specifically pointed out, is mounted within the rotary table 14 and is provided with means which are operable either manually or automatically for holding the drill stem orpipe 12 from vertical movement relative to the table 14.

In order to force down, or to withdraw thedrill stem 12 from within the casing 8, as is required in carrying out the rotary drilling process, we provide atraveling spider 16 which is so coupled with therotary machine 3 as to enable the actual forcing of thedrill stem 12 down into the well, or the feeding of thedrill stem 12 into the well under gas pressures normally sulficient to force thedrill stem 12 out of the casing 8.

It is only necessary to employ thetraveling spider 16 when the gas pressure within the well is sufiicient to throw thedrill stem 12 out of the well. Thetraveling spider 16 is suspended within the well by a sling 1'7 which is attached to aline 18 which passes over a pulley mounted in the upper portion of thederrick 1. The opposite end of theline 18 is secured to aWeight 19 for the purpose of counterbalancing the weight of thespider 16 so that the travelingspider 16 may be easily operated within thederrick 1. Secured to theweight 19 is a handlingrope 20 which is in turn secured to thederrick 1 at a point near the floor thereof.

Secured to thearms 21 of the travelingspider 16 by means ofclevises 22, are cables 23 which are reeved underpulleys 24 mounted on the opposite sides of therotary machine 3. The cables 23 extend upward from thepulleys 24 and are secured to acommon connection 25. Secured to theconnection 25 is aline 26 which extends over pulleys mounted in the upper portion of the derrick and down to an auxiliary'hoist 2'7. The hoist 27 is power driven by any suitable or desirable means such, for example, as by means of achain 28 which passes over a, sprocket secured to the shaft of the hoist 2'7 and is driven by any suitable source of power.

The hoist 27, in addition to a spooling portion, includes brake rims 29 upon whichbrake bands 30 are mounted. Thebrake bands 30 are tightened to the brake rims 29 by any suitable or desirable means such, for example, as by means of a handle 31 secured to a rocking shaft 32.

The hoist 2'7 provides a means for actually forcing thedrill stem 12 down through the stufiing box '7 through the power applied to the hoist 2'7 operating through thepulleys 24 to the upwardly extending portion of the cable 23 to pull downwardly upon thearms 21 of thespider 16. To control the pipe ordrill stem 12 when it is withdrawn from the well under pressure it is only necessary to feed off theline 26 of the hoist 2'7 by use of thebrake bands 30.

When the pipe ordrill stem 12 is in any stationary position, slips are applied in thesplit table bushing 15 to secure thepipe 12 against movement in either direction. Thesplit table bushing 15 is secured in position within the rotary table 14 against upward displacement by means of a lockingbar 33 such, for example, as disclosed in the Letters Patent issued to Lewis E. Zerbe, No. 1,825,930 of October 6, 1931.

The split table bushing is preferably of a construction including twosymmetrical halves 34 and 35 which, when positioned within the rotary table 14 form a cylindrical bushing having a polygonal top 36, fits within a correspondingly shaped opening formed in the top of the rotary table 14. In this manner splittable bushing 15 is driven with the rotary table 14. The downwardly extending cylindrical portion of thesplit table bushing 15 is fitted within the cylindrical skirt 3'7 of the rotary table 14. Aflanged guide ring 38 is secured to the lower portion of thesplit table bushing 11 to maintain thedrill stem 12 in axial alignment with the rotary table 14 and thedrill stem bushing 15.

Means are mounted within the split table bush-I ing 15 for holding thedrill stem 12 from vertical displacement relative to therotary machine 3, which means preferably includes two sets of opposed tapered slips 39 and 40. Theslips 39 and 40 are tapered on their outer faces 41 and 42, respectively, to fit complementarytapered seats 43 and 44 formed within the central passage provided by thesplit table bushing 15. Theslips 39 and 40 are preferably, as herein illustrated, formed of two halves, but may obviously be formed of a greater number of segments if desired.

The inside diameter of theslips 39 and 40 are approximately the same as the outside diameter of thedrill pipe 12, and theslips 39 and 40 are provided withsuitable wickers 45 and 46 respectively to provide for a more efiectual gripping of thedrill stem 12 by theslips 39 and 40. Thewickers 45 of the slips 39 are formed downwardly, while thewickers 46 of theslips 40 are formed upwardly.

In order to actuate theslips 39 and 40, the slips are connected with an operatinghead 47, which is slidably mounted in a cylindrical slideway 48 formed in the upper end of .thesplit table bushing 15. The operating head 4'7 is connected bylinks 49 with the slips 39 and by means oflinks 50 with theslips 40.

In order to hold theslips 39 and 40 normally out of engagement with thedrill stem 12 as thedrill stem 12 is run into or out of the hole.whilethe operating head 47 is in a neutral position, we prefer to so connect theslips 39 and 40 through thelinks 49 and 50 with the operating head 4'7 as the normal force of gravity tends to swing the said slips to a position out-v wardly away from thedrill stem 12.

In order to accomplish this, thelinks 49 are pivotally connected to'pins 51 carried by the operatinghead 47 at a point or position offset outwardly a greater distance from the axis of thedrill stem 12, than the center of gravity of the slip 39. Likewise the point of pivotal attachment at 52 of thelinks 50 with the slip 39 is more remote from the axis of thedrill stem 12 than is the center of gravity of theslips 40. The slips 39 and40 being thus coupled with the operatinghead 47, the tendency is to swing out--v wardly from thedrill stem 12 when thehead 47 is in a neutral position.

Means are provided for actuating theslips 39 and 40 both manually or automatically, which means are preferably of the following construction:

An operating handle 53 is fulcrumed at 54 on abracket 55 secured to the stationaryrotary table guard 56. The operatinghandle 53 is forked on the inner side of thefulcrum 54 and flts over shifter lugs 57. The shifter lugs 57 are formed on ashifter ring 58 which is a split ring bolted together and fitted within anannular groove 59 formed in the upper portion of thehead 47.

By a downward forceexerted by the operator of theoperating handle 53, the slips 39 are caused to engage thedrill stem 12, securing thedrill stem 12 against being blown outward from the well. By an upward force exerted on the operatinglever 53, theslips 40 are dropped into engagement withthedrill stem 12, supporting thedrill stem 12 against downward vertical movement.

In order to operate theslips 39 and 40 automatically in accordance with the movement of thedrill stem 12 to avoid the possibility of the operator abandoning the derrick and thedrill stem 12 either being blown from, or dropping into the well, we prefer to provide the operatinghead 47 with aflanged sleeve 60. which surrounds thedrill stem 12 and which is provided with two engagingdog openings 61. Two pair of toothed dogs 63 are mounted within theopenings 61 in position to engage the periphery of thedrill stem 12. At ninety degrees from theopenings 61 twosimilar openings 62 are provided on diametrically opposite sides of the sleeve through whichsimilar dogs 64 are passed.

Thedogs 63 and 64 are pivotally supported onpins 65 and 66 respectively within recesses formed in thehead 47, and actuating pins 6'7 and 68 are provided for holding thedogs 63 and 64 into a neutral or non-operative position. The lower end of the pins 6'? and 68 engage thedogs 63 and 64 respectively, while the upper ends thereof are engaged by theflanged sleeve 60. Thedogs 63 and 64 are normally urged into an operating position by means ofsprings 69 and '70 positioned within bores formed in the head 4'1 and acting againstplungers 71 and 72 which in turn engage thedogs 63 and 64.

The dogs 63 operate on the downward movement of thedrill stem 12 to'move the operatinghead 47 downwardly to allow theslips 40 to drop into position to engage thedrill stem 12 and prevent further dropping of the drillstem 12 into the well. Thedogs 64 operatewhen thedrill stem 12 is being thrust from the well by the gas pressure to raise the operating head 4'! and thereby cause the slips 39 to engage thedrill stem 12 and thereby prevent further upward movement of thedrill stem 12.

Asafety lever 73 is pivotaliy secured to the operatinglever 53 at thepivots 74 and is forked at its inner end. The forked ends of the lever '13 carryrollers 75, which are tapered as indicated at 76 complementary to a taperedtrack 77 formed on the top of theflanged sleeve 60. The twolevers 53 and 73 are gripped together by the operator when the device is under manual control. Interposed between the levers '73 and '53 is-aspring 78 which normally operates to separate the levers when. they are released by the operator. I

Thespring 78 is provided for the purpose of relieving a downward pressure against theflanged sleeve 60 by the rollers due to the actuation of the twolevers 53 and 73 together by the operator so that the operatinghead 47 will be free to move in accordance with the friction developed by the movement of thedrill stem 12 through the device after the operator has abandoned the rig or desires the apparatus to operate automatically.

Thedogs 63 and 64 may be formed with a serrated cam face to compensate for any variation that may be found in the diameter of thedrill stem 12. I

Under ordinary drilling operations theslips 40 are forced into engagement with the drillstem 12 by means of long screws which screw into thesplit table bushing 15 at '19. The long screws are used only when the weight of thedrill pipe 12 is not sufficient to prevent rotation or slipping of thepipe 12 in theslips 40 due to the torque and pressure exerted in driving the drilling bit secured to the lower end of thedrill stem 12.

when drilling in shallow wells, particularly with rock or like bits. when the weight of the drill stem is not sufficient to produce the required pressure on the bit, or where excessive gas pressure is present within the well, then it is more desirable to utilize the upper slips 39 to drive the pipe and exert the desired downward pressure. The rate of feeding of the bit, or the progress of the hole, is controlled by the rotary machine when of the hydraulic type.

Thesplit table bushing 15 is formed of two halves which are preferably loosely coupled togetherbut which coupling is so constructed as to enable the two halves to be locked together. This locking of the two halves together enables thebushing 15 to be withdrawn from the rotary table with the last stand of drill stem.

Each half of thebushing 15 is provided with outwardly extendingeyes 15a which fit within recesses 15b formed in the adjacent edge-of the other half of the spider.Lock bolts 150, havingflat sides 15d. are passed through theeyes 15a in the recesses 15b. Thelock bolts 150 are provided withhandles 15! to enable their rotation. Lock pads 15g are formed on the body of the bushing halves immediately adjacent the recesses 15b. The lock pad 15g projects into the line of movement of thebolts 150 which pass through theeyes 15a with their flat side adjacent the fiat sidesof the lock pads 15g. Thebolts 15c normally fit loosely in theeyes 15a and when rotated to locking position, lock the two halves of the bushing together by their round surfaces riding upon theflat pads 15a.

Theguide ring 38 is secured to the two halves of the 15 in such a manner as to prevent itt accidental loss in the hole. Thering 38 is provided with a lock flange 384: which fits into theannular recess 38b formed in the end of halves of thebushing 15. Thering 38 is split so that its halves may be inserted within the halves of therecess 38b when the two portions of the bushing are separated.

In order to permit theslips 39 or 40 to seat properly against thedrill stem 12 thelinks 49 are slotted as indicated at 49a to accommodate for uneven gripping of thedrill stem 12.

The travelingspider 16 is preferably of the following construction:

The travelingspider 16 consists of acylindrical body 80 to which there is secured pipe guides 81 and 82 respectively. The pipe guides 81 and 82 are provided for the purpose of maintaining thedrill stem 12 in axial alignment with the traveling spider l6. Horizontally extendingarms 21 are formed by two bars which, at their central portionQare formed to provide a split ring which engages thebody 80 within anannular recess 83. The two bars are bolted together as indicated at 84. Formed within the axial bore of, thebody 80 is a taperedslip seat 84a. Tapered slips 85 are mounted within the bore of thebody 80 to seat upon theslip seat 84a. Theslips 85 are of any suitable or desirable construction and are herein illustrated as formed of the two complementary slip members which are connected together by means of dowel pins 86, and upon which dowel pins 86 releasingsprings 87 are mounted, which normally urge the twoslips 85 outwardly to release thedrill stem 12. Means are provided for actuating theslips 85 into pipe engaging position, which means are herein illustrated as including afulcrum lever 88 fulcrumed to thebody 80 at 89, and forked at its inner end to engage the under edge of theslips 85.

Theslips 85 are provided with alug 90 to prevent rotation of the slips within thebody 80, thelug 90 being positioned to engage theinner end of the forked portion of thefulcrum lever 88. An operatingrope 91 is secured to the end of thefulcrum lever 88 and extends downwardly in the derrick to where it may be gripped by the operator.

Theslips 85 are mounted in inverted position to prevent or hold thedrill stem 12 from being thrust out of the well, and also to enable the feeding of the drill stem. 12 out under the pressure of the well, or down into the pressure of the well when required for the purpose of changing the tool or tools connected on the end of thedrill stem 12. Theslips 85 are formed at their inner surface withwickers 92.

The operation of the apparatus embodying our invention is as follows:

Thedrill stem 12 positioned within the well, and the rotary table 14 is rotated to rotate the drill carried at the bottom of thedrill stem 12. Drilling fluid is fonced under pressure through thedrill stem 12 to lubricate the drill and to wash the cuttings out through the casing 8 through theconduit 11 to the drilling fluid or mud sumps.

When gas is encountered which is of sufilcient pressure to tend to thrust thedrill stem 12 out of the well, thedrill stem 12 is fed downwardly by means of the auxiliary hoist 27 operating the pull downwardly on the travelingspider 16 to force the drill stem down. When it is necessary to add another length of drill stem, the slips 39 are set to hold the drill stem from being withdrawn from the well under the pressure of the gas, the travelingspider 16 is removed from the end of thedrill stem 12, and another section or stand oi. drill stem'is added thereto. The traveling spider is again connected to the upper end of the new stand of drill stem and the drill stem is again forced downwardly.

To release the slips 39 after the new stand of drill stem has been added and after the travelingspider 16 is connected thereto, the rotary machine table itself may be elevated slightly in the case where a hydraulic rotary machine is used or the traveling spider is forced downwardly until the slips release. Should trouble develop during the drilling of the well so that the operators abandon the well and the operator releases the control 98 handles 53 and 73, the control handle 73 is forced away from thehandle 53 to relieve the applied pressure on theflanged sleeve 60 and permit thedogs 63 and 64 to assume their automatic operation.

If the drill stem is then falling, the dogs 63 grip the pipe and set the downwardly acting slips 40 to hold the pipe from falling further into the well. If thedrill stem 12 is being thrust from the well, thedogs 64 engage the pipe and 108 set the upwardly acting slips 39 to hold thedrill pipe 12 from further movement out of the well. When the drill pipe is thus held in position, the blow-out preventer 6 may be closed. With the blow-out preventer 6 closed, and with the passage of fluid through thedrill stem 12 being closed through the hydraulic swivel back to the mud slush sumps, fluid may only pass from the well through theconduit 11 to the slush sumps, and this passage of fluid may be controlled by the no valve 13. c

In withdrawing of thedrill pipe 12 from the well, the reverse action to that of feeding the drill stem into the well is performed so that at all times control of the movement of the drill stem is had against the pressure of the gas within the well. After withdrawing successive sections of the drill pipes or stem 12 from the well until the drilling bit comes up into the casing section above thedrilling valve 5, the valve is then closed and the stuffing box '7 detached from the casing.

Thelong screws are screwed into the split drill stem bushing at 79 to force theslips 40 to engage the'last section of thedrill stem 12 remaining in the well. The locking bars 38 are then removed and the entire assembly, including the split drill stem bushing 15, drilling bit and stuffing box "I, is removed through the rotary machine opening. The drilling bit is replaced and the apparatus is then set up again in a reverse manner and the drill'stem is again forced into the well and drilling is continued.

Having fully described our invention, it is to be understood that we donot wish to be limited to the details herein set forth, but our invention is of the full scope of the appended claims.

We claim:

1. In a well drilling apparatus, the combination of a casing. a drill stem within said casing, means for rotating the drill stem, the latter said means including a bushing, means including axially spaced slips having oppositely disposed tapers within the bushing for holding the drill stem from vertical movement' in either direction relative thereto, the effectiveness of the holding means being substantially the same in either direction and being a function of the axial load transmitted from the drill stem.

2. In a well drilling apparatus, the combination of a rotary machine having a rotary table, a split table bushing mounted in the rotary table, two pair of slips mounted within the bushing tor holding the drill stem from vertical displacement relative to the rotary machine, and means for automatically actuating the slips on movement or the drill stem.

3. In a well drilling apparatus. the combination of a rotary machine having a rotary table, a split table bushing mounted in the rotary table, two pair of slips mounted within the bushing for holding the drill stem from vertical displacement relative to the rotary machine, and means for actuating the pairs of slips to engage and hold the drill stem from vertical movement relative to the rotary machine.

4. In a rotary machine having a rotary table, the combination of a bushing adapted to be mounted in the rotary table, means carried by the bushing for guiding a drill stem axially thereof, and means carried by the bushing for holding the drill stem from vertical movement relative thereto in either direction, the effectiveness of the holding means being substantially the same in either direction and being a function of the axial load transmitted from the drill stem.

5. In a device of the class described, the combination of a rotary table, a drill stem bushing mounted within the table, separate axially spaced slips having. opposed tapered surfaces carried by the bushing for holding a drill stem from vertical movement relative to the table in either direction, and means for actuating the slips in position to engage the drill stem.

6. In a device 0! the class described-the combination of a rotary table, a drill stembushing mounted within the rotary table, slips mounted within the bushing for holding a drill stem from downward movement relative thereto, a second set oi. slips mounted within the bushing for holding the drill stem from upward vertical movement relative thereto, a control mounted on the bushing, means connecting the control and the slips, and means for actuating the control to move the slips selectively to and out of drill stem engaging position.

7. In adevice of the class described, the combination oi. a rotary table, a drill stem bushing mounted within the rotary table, slips mounted within the bushing for holding a drill stem from downward movement relative thereto, a second set or slips mounted within the bushing for holding the drill stem from upward vertical movement relative thereto, a control mounted on the bushing, means connecting the control and the slips, means for actuating the control to move the slips selectively to and out of drill stem engaging position, and automatic means operable on the movement of the drill stem for actuating the control. v a

8. In an apparatus, of the class described, the

combination of a drill stem, a rotary table, drive means mounted within the rotary table, up-anddown thrust slips mounted within the drive means, means carried by the drive means-and automatically operable upon the vertical movement of the drill stem for actuating the slips to hold the drill stem from further vertical movement relative to the rotary table.

9. In an apparatus of the class described, the combination of a drill stem, a rotary table, drive means mounted within the rotary table, up-anddown thrust slips mounted within the drive means, means carried by the drive means and automatically operable upon the vertical movement of the drill stem for actuating the slips to hold the drill stem from further vertical movement relative to the rotary table, and means for holding the driving means within the rotary table.

10. In an apparatus 0! the class described, the combination of a drill stem, a rotary table, a split table bushing mounted within the rotary table, up-and-down thrust slips mounted within the bushing, means automatically operable upon the vertical movement of the drill stem for actuating 35 tne slips selectively to hold the drill stem from iurther vertical movement relative to the rotary table.

- 11. In an apparatus of the class described, the combination of a drill stem, a rotary table, a split table bushing mounted within the rotary table, up-and-down thrust slipsmounted within the bushing, means'automatically operable upon the vertical movement 0! the drill stem for actuating the slips selectively to hold the drill stem from further vertical movement relative to the rotary table, means loosely connecting the portions of the split table bushing, and means for actuating the latter said means to firmly couple the portions of said bushings together.

12. In an apparatus of the class described, the combination of a drill stem, a rotary table, a split table bushing mounted within the rotary table, slips mounted within the bushing to grip the drill stem,'means loosely connecting the portions of 1 5 the split table bushing as a removable unit, and means for actuating the latter said means to firmly couple the portions of said bushing together.

13. In an apparatus of the class described, the combination of a drill stem, a rotary table, a table bushing mounted within the rotary table, upand-down thrust slips mounted within the bush* lngs, means automatically operable upon vertical movement of the drill stem for actuating the slips selectively to hold the drill stem from further vertical movement relative to the rotary table, and means operably connecting the up-and-down thrust slips and the automatically operable means for normally holding the slips out of drill stem engaging position.

14. In a device of the class described, the combination of a rotary table, a drill stem bushing mounted within the table, slips carried by the bushing for holding the drill .stem from vertical movement relative to the table in either direction, and means for automatically actuating the slips into operative engagement with the drill stem on movement of the drill stem in either direction.

15. In a drilling apparatus, the combination of a rotary table, a split table bushing mounted therein, gripping means mounted within the bushing to engage a drill stem, means extending longitudinally of'the bushing and selectively operable to clamp the'portions of said bushing together as a unit.

16. In.a drilling apparatus, the combination of a rotary table, a split table bushing mounted therein, gripping means mounted within the bushing to engage the drill stem, interlocking proj'ections and recesses formed on the abutting faces of the bushing portions to maintain axialalignment of the .bushing portions, and means to connectt the portions of said bushing together as a 5um 17. In a drilling apparatus, the combination of a rotary table, a split table bushing mounted therein, gripping means mounted within the bushing to engage a drill stem, rotatable means on the 15g bushing being selectively operable to clamp the portions of the bushing together as a unit.

18. In a drilling apparatus of the class described, the combination of a rotary table having a vertically extending opening, opposed split cooperating table bushing members adapted to seat within the vertical opening, a drill stem positioned axially of the opening, the bushing members having an inner tapered seat, slips positioned on the tapered seat and engaging the drill stem to support the same, the wedging action of the said slips normally forcing the table bushing members outwardly into contact with the wall of the table opening, meansfor clamping the bushings together and away from tight engagement .with the walls of the table opening in the absence of any wedging action by the slips, means to force the slips into positive engagement with the drill stem after the bushing members are clamped together as a unit so as to permit free withdrawal of the bushing unit from the opening upon the upward movement of the drill stem.

19. In an apparatus of the class described, the combination of a rotary table having a vertically extending opening therethrough, opposed split co-engaging table bushing members adapted to seat within the vertical opening, a drill stem positioned axially of the table opening, the bushing members having an inner tapered seat, slips positioned on the tapered seat and engaging the drill stem to support the same, the wedging action of the slips normally forcing the table bushing members outwardly into contact with the wall of the table bore, and means extending longitudinally of the bushing members and operable to clamp the bushing members together and away from tight engagement with the walls of the table opening in the absence of any wedging action by theslips, means to force the slips into positive engagement with the drill stem after the bushings are clamped together asa unit to permit free withdrawal of the bushing unit from the table opening upon upward movement of the drill stem.

20. In an apparatus of the class described, the combination of a rotary table having a vertically extending opening, a table bushing mounted within the table opening, an annular slip carrier slidably mounted axially within the opening formed in the upper portion of the table bushing, wedge slips positioned within the table bushing to engage a drill stem, means connecting the slips and the annular slip carrier, and manually operated means for actuating the slip carrier to move the slips in or out of engagement with the drill stem.

21. In an apparatus of the class described, the combination of a rotary table having a vertically extending opening, a table bushing mounted within the table opening, an annular slip carrier slidably mounted axially within an opening formed in the upper portion of the table bushing, wedge slips positioned within the table bushing to engage a drill stem, actuating means for the slip carrier including a pivotally mounted shifter member having a rotative connection with the slip carrier and which means are operable to actuate the slip carrier to move the slips into and out of engagement with thedrill stem.-

22. In an apparatus of the class described, the combination of a rotary machine, a split table bushing mounted within the rotary table, two sets of opposed connected slips mounted within the bushing'for holding the drill stem from vertical displacement relative to the rotary table, means engaging the drill stem for automatically actuating the slips on movement of the drill stem, an

means operable to disengage said last named means from the drill stem to render the automatic function inoperative.

23. In a well drilling) apparatus, the combination of a. rotary machine having a rotary table, a split table bushing mounted in the rotary table, slips mounted within the bushing for holding the drill stem from vertical displacement relative to the rotary table, means for automatically setting the slips on movement of the drill stem in one direction but allowing free movement in the opposite direction, and manually operable to disengage the last named means from the drill stem to render the automatic function inoperative.

24. In a device of the class described, the combination of a rotary table, a drill stem bushing mounted within the rotary table, slips mounted within the bushing for holding the drill stem from downward movement relative thereto, a second set of slips mounted within the bushing for holding the drill stem from upward vertical movement relative thereto, control means mounted on the bushing, means connecting the control means and the slips, means for actuating the control to set the slips, which means are automatically operable on movement of the drill stem for actuating the control means, and means manually operable to render the control means inoperative.

25. In an apparatus of the class described, the combination of a drill stem, a rotary table, drive means mounted within the rotary table, up-anddown thrust slips mounted within the drive means, means carried by the drive means and vertically operable upon the vertical movement of the drill stem in either direction for actuating the slips to hold the drill stem from further vertical displacement relative to the rotary table, and means manually operable for rendering the automatic slip means inoperative to set the slips.

26. In an apparatus of the class described, the combination of a drill stem, a rotary table, drive means mounted within the rotary table, up-anddown thrust slips mounted within the drive means,

means carried by the drive means and automatically operable upon the vertical movement of the drill stem for actuating the slips to hold the drill stem from further vertical displacement relative to the rotary table, means for holding the driving means within the rotary table, and means manually operable for rendering the automatic slip actuating means inoperative to seat the slips.

27. In an apparatus of the class described, the combination of a drill stem, a rotary table, a split table bushing mounted within the rotary table, upand-down thrust slips mounted within the bushing, means automatically operable upon the vertical movement of the drill stem for actuating the slips selectively to hold the drill stem from further vertical movement relative to the rotary table, and means manually operable for rendering the automatic slip seating means inoperative when it is desired to move the drill stem through the slips.

28. In a slip-handling device, the combination of a body, a split drill stem bushing mounted within the body, slips carried by the bushing for holding the drill stem from vertical movement relative to the body in either direction, means for automatically actuating the slips into operative engagement with the drill stem on movement of the drill stem in either direction, and means operable to render the automatic slip actuating means inoperative when it is desired to move the drill stem through the body.

29. In a tube gripping device, the combination of a body having a tapered opening providing a slip-engaging seat, a well tube positioned within said opening, slips mounted within the body on the'tapered seat to engage the tube, a first means to automatically actuate said slips into engagement with the well tube upon vertical movement of the tube, and a second means to manually operate the slips, said second means including means to render the first means inoperative when under control of the operator, said first means becoming automatically operable in the event the manual control of the second means is abandoned.

30. In a tube gripping device, the combination of a housing having a tapered opening providing a slip-engaging seat, a slip carrier slidably mounted axially within a bore formed in'said housing, a well tube positioned within said opening and extending through an opening in the slip carrier, depending slips on said carrier mounted within said housing on the tapered seat to engage the tube, manually controlled means operable to actuate the slip carrier and move the slips into and out of engagement with the well tube, members mounted on the slip carrier, means for yieldably urging the said members normally into contact with the tube to effect automatic actuation of the slips upon vertical movement of the well tube, and manually operable means for retracting the members when it is desired to manually actuate the slips.

31. In a traveling spider for handling well pipe, the combination of a body having a portion extending outwardly to form a yoke, an inverted tapered opening in the body, slips mounted within the opening to engage a well pipe passed through the opening, and means remotely positioned with respect to the spider for actuating the slips into engagement with the well pipe from a point remotely situated from the spider.

32. In a traveling spider for handling well pipe, the combination of a body having outwardly extending portions forming a yoke, guide bushings mounted within an opening formed in the body for positioning the spider axially with relation to the well pipe, the body having an inverted tapered opening, slips mounted within the opening to engage the well pipe passed through the opening, means to actuate the slips, and means remotely situated with reference to the spider for actuating the latter said means from a point remote from the spider.

33. In a well drilling apparatus, the combination of a casing, a drill stem within said casing, means for rotating the drill stem, the latter said means including a bushing, means including two sets of oppositely disposed slips within the bushing for holding the drill stem from vertical movement in either direction relative thereto and the effectiveness of the holding means being substantially the same in either direction and being the function of the axial load being transmitted from the drill stem.

34. In a device of the class described, the combination of a rotary machine, a drill stem bushing mounted within the table, two sets of slips having opposed tapered surfaces carried by the bushing for holding the drill stem from vertical movement relative to the table in either direction, and means for actuating the slips in position to engage the drill stem. 7

. LEWIS EMANUEL ZERBE.

EDWARD TIMES.

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