DE3811370A1 - DRILL HEAD WITH ONE-PIECE FORGED STABILIZER - Google Patents

Abstract

A drill bit is assembled from a plurality of machined forgings that are welded together to form a unitary structure. Each forging comprises an upper body portion (12) and a lower leg portion (16). The lower leg portion is machined to form a shirttail section (24) and a journal section (18), which in turn is adapted to rotatively support a cone shaped cutter (20). In operation, the cutter (20) is oriented to describe a circular path, the outer diameter of which forms the gage diameter of the bit. The upper body portion (12) is machined to include a stabilizer lug (30) extending radially outward to substantially the same diameter as that formed by the cutters. The lower section of the lug (30) co-operates with a recessed portion of the leg to form a flow passage for enabling drilling fluid to more easily pass upwardly through the borehole annulus during operation. A plurality of polycrystalline diamond inserts are mounted within the surface of each stabilizer lug (30). <IMAGE>

Description

The invention relates to drilling heads for drilling through Rock and other hard formations when drilling Oil wells, and especially on rotary heads hanging legs, which have cutting edges, which on from the inside of the thighs inwards and downwards extending pins are rotatably attached.

Drill heads of this type are conventionally on one Drill pipe suspended, which is different from that on the Surface of the derrick extends downwards. Usually the string of the drill string is from Drilling rig rotated and this rotary movement on the drill head transmitted at the bottom of the hole. In some cases, the Rotation of the drill head by using an am lower end of the drill pipe just above the drill head attached fluid motor achieved. In one as in the other Fall is the drill pipe as it is a smaller one Diameter than the hole to be drilled is susceptible for side vibrations or other movements, one Cause inclination of the strand of a certain size, which to a certain extent on the drill head itself is transmitted. This leads to the tip of the drill bit what excessive pressure of the lower leg sections of the Drill head as it rotates against the formation evokes. This phenomenon is even more critical in Directional drilling, in which the drill head with exceptional angular deviations from the Is aligned vertically. Originally, drill heads due to physical limitations within the borehole  formed with relatively thin leg structures. As The rotating boring head worked with the result excessive lateral rocking or tilting movements, which greatly affects the life of the drill head reduced because the lower section of the thighs themselves quickly worn out and become a sealing and / or Defective bearing led.

Stabilizers for the drill pipe have been used so far but were in some above the drill head Distance from this arranged so that still the Possibility for moving or tilting the Drill head existed.

U.S. Patent No. 3,628,616 eliminated some of these Problems due to the fact that a stabilizing device provided directly on the drill head and thereby the Eliminates need for additional thread protection as well the tilting movement of the drill head was greatly reduced. This stabilization device consisted of hard Metal inserts that are directly attached to the upper section of the Drill head body were welded. These deposits were of sufficient thickness to extend the life of the drill head to extend to a great extent and at the same time the Diameter of the upper drill head body within the the diametrical described by the rotary cutting edges To keep cutting path or bore certain limits.

Furthermore, this type pointed welded Inlay construction necessarily has sharp edges that led to tension risers on the thigh. This is of course, undesirable, as this Fatigue life due to welding caused by weakest part of the thigh mechanical notches is greatly shortened.  

Furthermore, it was found that high Flow rates of the drilling fluid during the Operating the welded insert of the "plates" - Execution can erode immediately.

Another disadvantage of the construction according to the '616' patent was found that the lower section of the approach with its straight Surface formed a dam that the up directed flow of the drilling fluid (mud) through the Borehole annulus obstructed. This caused excessive pressures and increased erosion at the bottom Leg sections of the drill head.

The one described in U.S. Patent No. 3,628,616 Drill head design also included a plurality of Tungsten carbide inserts on the wear inserts were attached. However, these bets tend to be during the Operating to get cracks and excessive wear out.

The invention overcomes the aforementioned drawbacks Creation of a one-piece to the drill head body forged stabilization device. These Construction is realized in that the Stabilization approaches on the leg forgings be preformed. The bottom section of each Stabilization approach is towards its Rounded outside and serves with one below of the approach arranged recessed part of the To interact with one of the lowermost ends of the drill head body leading away Form flow channel.  

A major advantage of this construction is that a metallurgically solid drill head body is formed, which resists breakage. In addition, they win forged approaches since they are forged parts by improving the grain structure in the metal substantial increase in toughness and Operational safety. In this construction, the sinewy metal structure parallel to the tallest Tensions and shock loads on the thigh be forced to be aligned. By using the Metal flow during the forging process are highest mechanical properties of the critically stressed Sections achieved.

Such a construction can also be optimally adapted to provide good stabilization and at the same time that created by the flow channel construction Fluid flow and removal of cuttings too improve.

Another advantage of the invention is that the forged construction without any difficulty machinable projection that fits on everyone Diameter can be turned and less Operations as welded legs required.

The present invention also uses polycrystalline diamond compacts to achieve highest abrasion resistance in the Stabilization approaches are pressed. The Insert framing can be either flat or rounded and be flush with the neck surface or over it extend out. The advantage of the approach protruding rounded inserts consists in the Enlargement of the annular space for the  Passing the cuttings is available. These Construction continues to cut the Gauge, so that the maintenance of the Borehole diameter is supported. Moreover, due to the reduction in contact with the wall the area of the borehole is smaller Torque generated.

The invention is based on two Exemplary embodiments with reference to the drawing described in more detail. Show it

Fig. 1 is a perspective view of the drill head according to the invention,

Fig. 2 is an enlarged sectional view of one of the legs of the drill head along the lines 3 -. 3 in Figure 1,

Fig. 3 of the forging used to form the leg is a sectional view,

Fig. 4 is an enlarged side view of the leg,

Fig. 5 is an enlarged partial view of the stabilization approach according to the invention, and

Fig. 6 is an enlarged partial view of a second embodiment of the stabilization approach according to the invention.

Fig. 1 shows a drill head 10 with a body 12 and a threaded shaft portion 14 which is designed to be screwed to the lower end of the drill string. Legs 16 extend from the drill head body 12 downward. As shown in FIG. 2, each leg 16 has an inwardly and downwardly directed pin 18 , which is designed for rotatably receiving a cutting edge shown by 20 in FIG. 2 with broken lines. The cutting edges 20 are aligned so that they describe a circular path, the outer diameter of which forms the pitch diameter of the drill head.

The lower part of the pin 18 is defined by a surface of revolution 22 which lies in a plane normal to the longitudinal axis of the pin 18 . The surface of rotation 22 and the lower end of the leg 16 define a relatively thin, tapered lower leg portion, commonly known as a shirttail. The radially outermost end of the shirt lap 24 does not extend to the outer diameter of the drill head 10 , but is at a distance from the side walls of the borehole.

Stabilizing lugs 30 are formed on the upper section of each leg 16 and extend radially outward to substantially the pitch diameter of the drill head 10 . Fig. 3 shows a forging 40 of the leg 16. The forging 40 includes a head portion 41 , a pin portion 42 , a shirt lap portion 43 and a stabilizing portion 44 .

The pin portion 42 is machined to form the pin 18 and the rotating surface 22 as shown in FIG. 2. The shirt lap portion 43 is also machined to remove some base metal (shown in broken lines) from the forging ( 40 ) to form the shirt lap 24 . This is shown more clearly in FIG. 4.

The forging 40 is also turned to remove a portion of the stabilizing portion 44 , as shown in broken lines, to machine the stabilizing tab 30 . Three such leg forgings are welded together to form the stone drill.

As shown in FIG. 1, the lower portion of each stabilizing tab 30 forms a rounded portion 51 that is curved upward to unite with the sides 53 of the tab 30 . This rounded part 51 interacts with a recessed part 55 formed on the leg 16 to form a flow channel in order to improve the flow of the flushing sludge around the shirt lap 24 upwards around the stabilization attachment 30 .

The mud slurry (not shown) flows into the borehole through a plurality of openings 60 running through the drill head body 12 .

Figs. 1 and 2 also show a lubrication system with a reservoir 61, is arranged in which a pressure compensating means 62. One side of the compensation device is connected to the outside of the drill head through channels 63 , which are formed in a closure 65 . The other side of the compensation device 62 is connected to the interior of the bearing cavity via passages 66 and 67 . Lubricant (not shown) completely fills the reservoir 61 , the passages 66 and 67 and the bearing cavity.

Fig. 4 shows more clearly a plurality of bores 45 for receiving a plurality of trays 46. Each insert 46 is preferably made of polycrystalline diamond and its outer surface may be substantially planar to be flush with the outer surface of the stabilizing extension (see FIG. 5).

Alternatively, each insert 46 can also have rounded outer projections 48 which protrude beyond the outer surface of the stabilization projection 30 (see FIG. 6).

In addition, each insert 46 may be made entirely of polycrystalline diamond, or otherwise may be a plate that is brazed to a base part made of tungsten carbide.

In operation, it has been found that integral stabilization tabs 30 have overcome many of the drawbacks found in the prior art designs. In addition, the diamond inserts 46 have reduced the wear on the stabilization attachment to a great extent, thereby considerably extending the service life of the drill head.

It goes without saying that changes in the exact form, in details and proportions of the Construction without deviation from the inventive concept can be carried out.

Claims (8)

1. A drill head having a drill body having a main body portion and a plurality of legs extending downwardly therefrom, the lower end of each leg comprising a relatively thin, tapered extremity, commonly known as a shirt lap portion, and having one on each leg rotatably mounted cutting edge, which cutters define a circular cutting path when the drill head body rotates, the outer diameter of the cutting edges forming the outer diameter of the drill head, characterized in that the main body section ( 12 ) is integrally forged onto it directly above each leg ( 16 ) , from the main body portion ( 12 ) extending radially outward to substantially the same diameter as the circular cutting path stabilizing extension ( 30 ) and a flow channel device ( 51 , 55 ) recessed along the lower and lateral edges of each extension ( 30 ) fluid flow around each shirt lap portion ( 24 ) up around each stabilization tab ( 30 ). 2. Drilling head according to claim 1, characterized in that the flow channel ( 51 , 55 ) is characterized by a curved surface ( 51 ) formed on the lower section of each stabilizing attachment ( 30 ). 3. Drilling head according to claim 1 or 2, characterized in that the flow channel ( 51 , 55 ) is characterized by a radially recessed part ( 55 ) formed on the main body directly below each stabilizing attachment ( 30 ). 4. Drilling head according to at least one of claims 1 to 3, characterized by a plurality of polycrystalline diamond inserts ( 46 ) fastened in the surface of each stabilization attachment ( 30 ). 5. Drilling head according to claim 4, characterized in that each polycrystalline diamond insert ( 46 ) with the surface of the stabilizing attachment ( 30 ) has a substantially flat bearing surface ( 47 ). That each polycrystalline diamond insert (46) also comprises 6. Boring head according to claim 4, characterized in that an above the surface of the stabilizing attachment (30) extending rounded bearing surface (48). 7. A method of manufacturing a rotary drill head according to at least one of the preceding claims, characterized by the steps of forging a plurality of elements ( 40 ) having upper body portions and lower foot portions, machining each element ( 40 ) to form one at the lower foot portion arranged shirt lap portion ( 43 ), machining each element ( 40 ) to form tenons ( 18 ), providing a cutting edge ( 20 ) for rotatable attachment to each tenon ( 18 ), aligning and fastening the elements ( 40 ) to form a unitary construction such that the cutting edges ( 20 ) have an outer circumference which defines the outer diameter of the tool ( 10 ) and the stabilizing lugs ( 30 ) extend radially outward to substantially the same diameter as the cutting edge circumferences. 8. A method of making a rotary drill head according to claim 7, characterized by the steps of drilling a plurality of holes ( 45 ) into the surface of each stabilizing lug ( 30 ), and mounting a polycrystalline diamond insert ( 46 ) in each hole ( 45 ).