The present invention relates generally to earth boring drill bits for drilling a wellbore, and more particularly to a roller cone rock bit with a cuttings evacuator.
Roller cone or rotary cone bits are well known in the art of earth boring drilling operations. The most common design of a roller cone bit consists of three roller cones, each rotatably mounted on a downwardly and radially inwardly extending bearing pin. Each roller cone supports a plurality of cutting elements, which are referred to as cutters. Each of the bearing pins is spaced approximately 120 degrees apart with the three pins formed as a part of a bit body. The entire structure is rotated at the end of a drill string. Boring is accomplished by applying weight to the drill bit and rotating the drill string, thereby causing the roller cones to roll and crush the rock formation beneath the bit. As the bit is rotated and moves through a formation, the cutter elements contact and disintegrate portions of the formation in order to form the desired bore hole. The earth separated from the formation become cuttings that are removed from the bottom and sides of the bore hole and washed away by a drilling fluid, such as air or drill mud, that is supplied to the drill bit from the surface through the hollow rotating drill string. The cuttings are suspended in the drilling fluid and carried to the surface in the space between the bore hole and the drill string.
The cuttings produced by the drilling operation are abrasive and with continued use will erode the cutters and other portions of the bit. The grinding and re-grinding of the cuttings produced by the drilling operation slows the formation penetration rate of the bit and shortens the life of the bit. The re-ground cuttings tend to dull the cutters and the finely ground particles may enter the bearing surfaces formed between the roller cones and the journals supported by the bit, restricting cutter cone rotation and further limiting bit life.
Reference is made to U.S. Pat. No. 6,082,473 to Dickey, which is incorporated herein by reference and discloses a self-cleaning polycrystalline diamond compact (PDC) bit.
Reference is also made to U.S. Pat. No. 5,462,128 to Gray, which is incorporated herein by reference and discloses a cutter bit having a passageway for cuttings to escape to the surface of the hole.
Further reference is made to U.S. Pat. Nos. 2,692,117 and 3,099,324 each to Kucera which disclose drill bits having passageways through the bit for the evacuation of cuttings.
An earth boring drill bit having an alternate path to allow cuttings to be ejected or evacuated from the drill bit and up the bore hole is disclosed. The evacuation hole of the present disclosure allows larger sized cuttings to evacuate from the bit without having to be continually ground by rolling cone cutters until the cuttings are small enough to follow a path around the edge of the shirttail of the bit and up the borehole. A cuttings restrictor is disposed at the inlet of the evacuation hole. The cuttings restrictor ensures that only cuttings that are sized to move completely through the evacuation hole and exit the drill bit are allowed into the evacuation hole.
In certain embodiments, the drill bit may include a drilling fluid hole that extends from an inner plenum of the bit and intersects the evacuation hole. Drilling fluid may flow from the inner plenum, through the drilling fluid hole, and into the evacuation hole. This fluid flow may enhance the evacuation and ejection of cuttings from the evacuation hole.
Other embodiments of the drill bit of the present disclosure may include an excluder disposed at the outlet of the evacuation hole. The excluder may include features that partially block an opening leading to the outlet, and thus prevent debris and flushed cuttings from reentering the evacuation hole through the outlet.
Technical advantages of the disclosed drill bit include features that allow larger sized cuttings to be evacuated from the drill bit, as opposed to being reground by the cutter cones. By reducing the amount of regrinding that occurs in the drilling operation, penetration efficiency may be improved, fewer cutters may be lost, and bits may last longer.
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Drilling fluid is directed through the drill string and reaches the plenum of the bit, which is defined by an interior plenum surface 18. From the plenum the fluid is received by one or more discharge ports 34. Drill bits usually have one discharge port 34 per roller cone. Fluid flows through the discharge ports 34 and exits to the bit cavity 36 located in a central region of the bit among the cones and between the cones and a surface of a throat area 39.
The drilling fluid serves to keep the bit cool. For example, roller cone bits often have non-sealed rolling element bearings that support the roller cones 16 as they rotate. Some of the drilling fluid may be directed to flow through channels internal to the bit body 10 to these bearings in order to keep them cool during down hole operation.
The drilling fluid also functions to flush earth cuttings out of the bit cavity 36, around the shirttail 32, and up the borehole. For cuttings to be flushed out through this path, they must be sufficiently small to fit between the shirttail 32 and the wall of the borehole. Larger cuttings may not be immediately flushed from the bit cavity 36. Rather, they may be reground by the cutters until the cuttings are small enough to flow with the drilling fluid between the shirttail 32 and the borehole wall. This regrinding reduces bit efficiency and accelerates bit and cutter wear. Also, the drilling fluid is susceptible to recirculation in the cavity 36 near the discharge nozzles 20, which can cause erosion and coring problems with the bit near the nozzles 20. In addition, continuous grinding of larger cuttings may lead to loss of cutter inserts, may reduce bit life, and may reduce bit penetration.
According to an embodiment of the present disclosure, drilling fluid may flush earth cuttings away from the roller cone cutters 16 and the bit through a passageway defined by an evacuation hole 38. The evacuation hole 38 may be formed through the leg 14 and may be at any suitable angle. An evacuation hole 38 may be formed through a single leg 14, all the legs 14, or less than all the legs 14. In certain embodiments, the evacuation hole 38 may be a constant diameter straight hole as shown in
In certain embodiments, an interior surface of the evacuation hole 38 may support a sleeve. The sleeve may run the length of the evacuation hole 38 and may extend into the cavity 36 as further detailed below with respect to the description of the cuttings restrictor 42. The sleeve may be employed to provide an abrasion/erosion resistant inner surface for the evacuation hole 38, which may resist wear caused by cuttings being evacuated through the bit. The sleeve may comprise any suitable abrasion/erosion resistant material, such as tungsten carbide, a glass filled polymer, or a ceramic. The sleeve may have a tapered inner surface to assist in the prevention of clogging. The tapered surface may be an interior surface of the sleeve, while the exterior surface of the sleeve corresponds to the geometry of the evacuation hole 38.
The outlet of the evacuation hole 38 may be formed in any portion of the backside surface of the leg 14 that is up hole of the bottom edge 33 of the shirttail 32. For example, the outlet may be formed in a surface adjacent an upper shoulder surface 35 and may be on the leading or trailing side of the leg 14. In other embodiments, it may be formed partially in the shoulder surface and partially in the outer (gage or shirttail surface) of the leg 14. Still further, the outlet may be formed in the outer surface of the leg 14.
The cuttings follow path 37 and enter the evacuation hole 38 from the bit cavity 36 and exit from the outlet into the space 41 between the bit body 10 and the borehole wall 15.
The entry portion of the evacuation hole 38 may be through a surface of the bit generally in the throat area 39. In certain embodiments, the evacuation hole 38 may include features at its inlet that prevent cuttings from becoming lodged in the evacuation hole 38, and may include features at its outlet that prevent re-entry of flushed cuttings or other debris in the evacuation hole 38.
According to one embodiment, the evacuation hole 38 may be in fluid communication with a drilling fluid hole 40, which is connected to the plenum. The drilling fluid hole 40 may be smaller in diameter than the evacuation hole 38. The drilling fluid hole 40 may be defined by the plenum at one end and an intersection with the evacuation hole 38 at the other end. Similar to the evacuation hole 38, the drilling fluid hole 40 may be formed by drilling, plunge electro-discharge machining, or milling.
In certain embodiments, the drilling fluid hole 40 may intersect an up-hole portion of the evacuation hole 38. Drilling fluid flowing through the plenum may also flow through the drilling fluid hole 40 and into the evacuation hole 38. This flow will help draw cuttings into and completely through the evacuation hole 38. In this manner, cuttings may be drawn through the evacuation hole 38 to be ejected away from the bit. Some embodiments of the present disclosure may effectively evacuate and remove cuttings from the cavity 36 without a drilling fluid hole 40.
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A beveled surface 46 may be interior to the annular portion 43. The beveled surface 46 transitions to a tapered inner surface 48. The inner perimeter where this transition occurs may be a minimum diameter 50 of the restrictor 42. This minimum diameter 50 ensures that if a cutting particle passes the minimum diameter 50, then it will continue to move or flow through the portion of the restrictor 42 defined by the tapered inner surface 48 and on through the larger diameter evacuation hole 38. In this manner, only cuttings that are sized to completely exit the bit through the evacuation hole 38 may enter through the restrictor 42.
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The flushed cuttings excluder 44 including the ring 52 and the prong 54 also may be positioned at the inlet of the evacuation hole in lieu of the restrictor 42.
Thus, according to the teachings of the present disclosure, an alternate path for cuttings to be ejected or evacuated from a drill bit and up the bore hole is disclosed. The evacuation hole 38 of the present disclosure allows larger sized cuttings to evacuate from the bit without having to be continually ground by the rolling cone cutters 16 until the cuttings are small enough to follow the path around the edge of the shirttail of the bit and up the borehole. In this manner, cutter or bit failure may be prevented and drilling efficiency may be improved.
Embodiments of the invention have been described and illustrated above. The invention is not limited to the disclosed embodiments.