CROSS REFERENCE TO RELATED APPLICATIONS This application claims the benefit of U.S. Provisional Patent Application No. 60/525,577, filed on Nov. 26, 2003, and entitled “Flat and Bevel Chipbreaker Insert.”
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT Not Applicable
BACKGROUND OF THE INVENTION 1. Field of the Invention
This invention is in the field of tools used downhole, in oil or gas wells, to mill or otherwise cut metal objects in the borehole.
2. Background Art
In the drilling, completion, or re-work of an oil or gas well, it often becomes necessary to cut into or through a metal object which is located downhole in the well bore. This can be required, for instance, in cutting through the wall of a well casing, removing a packer, or milling away some other metal obstruction which may be present in the borehole. This type of cutting or milling operation is very different from the type of metal cutting operations typically found in a machine shop environment. The downhole metal cutting operation involves the rotation of a very large tool by a very heavy workstring, by comparison with the typical machine shop operation. The downhole cutting operation itself involves a great deal of vibration and even severe impact, between the cutting tool and the metal object being cut. In fact, much of the force of any such impact or vibration is typically brought to bear directly on the cutting insert or inserts which are mounted on the cutting face of the downhole cutting tool. These cutting inserts are essentially the “teeth” of the cutting tool. They are typically made of a very hard material, such as tungsten carbide.
The operator can not closely observe the downhole cutting operation and monitor the condition of the cutting insert or inserts. By contrast, the machine shop operator can closely observe the cutting operation as it progresses, and he can change the cutting insert regularly as its cutting surfaces degrade. Stopping the operation in the machine shop is typically significantly cheaper than pulling a downhole tool from the well bore and checking or changing the tool out. This means that the typical machine shop operation is always done with a basically fresh cutting insert in good condition.
The downhole operator, on the other hand, must simply rotate the workstring and rely upon fairly remote indicators of the performance of the tool, such as vibration and rate of penetration, to judge the progress of the cutting operation. As a result, as the cutting operation continues, the cutting insert on the face of the cutting tool usually wears away and disintegrates. It is common, in fact, to have multiple cutting inserts on a downhole cutting tool, with the inserts being arranged progressively across the cutting face of the tool. This is done so that, as each cutting insert wears away and disintegrates or falls off the tool, another adjacent cutting insert establishes contact with the work piece, thereby continuing the cutting action. This alleviates the need to pull the work string and replace the tool, or at least delays the necessity of replacing the tool.
An unfortunate aspect of this situation is that each cutting insert must remain effective in spite of having its original cutting geometry drastically changed as the cutting operation progresses; that is, the insert will not retain its original cutting edge for very long. If the cutting insert wears to such an extent that the cutting edge is gone, the portion of the insert contacting the work piece can act as a bearing surface. If the cutting insert can not cut effectively after having its original cutting edge worn away, the insert will not be an effective part of the tool, and it can even impede the action of nearby cutting inserts, by acting as a bearing surface, rather than as a cutting surface.
It is also known to provide a chip breaking feature on the forward face of a cutting insert for use in the downhole environment, which causes the insert to break off metal chips from the work piece at short lengths, allowing the chips to be more easily removed from the well bore by the flow of drilling fluid. So, as wear progresses across the insert face, through the chip breaking feature, the insert might cease to break off short chips and begin to produce long, thin metal turnings. The long thin turnings are not easily removed from the well bore by the flow of fluid, so this type of insert wear can lead to the clogging of the area around the cutting tool, preventing further penetration of the work piece. Further, if the chip breaking feature contributes in any way to the fragility of the insert body, it can cause the insert to disintegrate prematurely and fall off the cutting tool, resulting in a complete loss of the ability to cut, until the tool body wears sufficiently to allow the adjacent cutting insert to come into play.
It is desirable to have, therefore, a cutting insert which is sufficiently robust to withstand the impacts experienced in the downhole environment, and which is designed to break off short metal chips from the work piece, and to continue to present an effective cutting geometry to the work piece, even as the original cutting geometry of the insert gradually wears away.
BRIEF SUMMARY OF THE INVENTION The present invention, in summary, is a downhole cutting insert which has one or more lands on its cutting face, interspersed with one or more beveled surfaces, creating a robust cutting face on the insert. The juxtaposition of bevels with lands causes the insert to break off metal chips from the work piece at short lengths, allowing the chips to be more easily removed from the well bore by the flow of drilling fluid. Use of alternating multiple bevels and lands allows the insert to continue to effectively form short metal chips, even as the forward face and the edge of the insert gradually degrade.
The novel features of this invention, as well as the invention itself, will be best understood from the attached drawings, taken along with the following description, in which similar reference characters refer to similar parts, and in which:
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGSFIG. 1 is an elevation view of a downhole cutting tool which can incorporate a cutting insert according to the present invention;
FIG. 2 is a top or front elevation view of a first embodiment of a cutting insert according to the present invention;
FIG. 3 is a top or front elevation view of a second embodiment of a cutting insert according to the present invention;
FIG. 4 is a partial axial section view of a third embodiment of a cutting insert according to the present invention;
FIG. 5 is a partial axial section view of a fourth embodiment of a cutting insert according to the present invention;
FIG. 6 is a partial axial section view of the cutting insert shown inFIG. 2 orFIG. 3; and
FIG. 7 is a partial axial section view of a fifth embodiment of a cutting insert according to the present invention.
DETAILED DESCRIPTION OF THE INVENTION As illustrated inFIG. 1, a cutting insert according to the present invention can be mounted on acutting tool10 designed for use in cutting metal objects downhole, in an oil or gas well. Thecutting tool10 can be a pilot mill, junk mill, casing cutter, window mill, or any other type of downhole cutting tool. Thecutting tool10 has atool body12, which is adapted to mount to a work string WS. Thetool body12 has at least one cutting feature, such as theblades14, attached thereto or formed thereon. Each cutting feature orblade14 has at least one cutting insert20 mounted on acutting face16 thereof, and oriented to face in thedirection18 in which theblades14 and thecutting inserts20 will advance when thecutting tool10 is rotated. Advancement in thedirection18 will cause thecutting inserts20 to advance toward and into the downhole metal object or work piece (not shown).
Thecutting inserts20 can take various shapes, some of which will be designated as20,20A and20B in the Figures discussed below. Other shapes can also be used without departing from the spirit of the present invention, as long as they exhibit the features described below.FIG. 2 shows the forward or front elevation of a round or cylindrical cutting insert20A, oriented in the drawing the same as the orientation of thecutting inserts20 on theright hand blade14 inFIG. 1. Where a round or cylindrical insert is discussed herein, it should be understood that a half-round or otherwise partially round insert can also be intended, where the context allows. The cutting insert20A has at least oneland22A and at least one bevel orbeveled surface24A, with afirst land22A being located immediately next to the original leadingedge28A of the cutting insert20A. Where present,successive lands22A andbevels24A are alternatingly arranged from the leadingedge28A toward the axis A of the cutting insert20A. The cutting insert20A is shown with threelands22A and threebevels24A, but it can have any number of each. The cutting insert20A can also have asurface26A substantially orthogonal to the axis A, on the front face of the insert20A.
As illustrated inFIG. 3, thecutting insert20 can also have a rectilinear shaped body, such as the insert20B. The cutting insert20B is shown oriented in the drawing the same as the orientation of thecutting inserts20 on theright hand blade14 inFIG. 1. Where a rectilinear insert is discussed herein, it should be understood that a square or otherwise rectangular insert can be intended. The cutting insert20B has at least oneland22B and at least one bevel or beveled surface24B, with afirst land22B being located immediately next to the original leading edge28B of the cutting insert20B. Where present,successive lands22B and bevels24B are alternatingly arranged from the leading edge28B toward the axis of the cutting insert20B. The cutting insert20B is shown with threelands22B and three bevels24B, but it can have any number of each. The cutting insert20B can also have a surface26B substantially orthogonal to the axis, on the front face of the insert20B.
FIG. 4 shows the most basic illustration of the features of thelands22 and bevels24 on theinserts20 shown inFIGS. 2 and 3, or on anyinsert20 according to the present invention. Theinsert20 has a solid body. Eachland22 is a substantially flat surface which is substantially orthogonal to the axis of the cuttinginsert20. Each land can be, more specifically, angled between approximately 75 degrees and approximately 90 degrees relative to the insert axis. It can be seen that, on the round insert20A shown inFIG. 2, theland22A would be a substantially planar, annular, surface, substantially or nearly orthogonal to the axis of the cutting insert20A. It can further be seen that, on the rectilinear insert20B shown inFIG. 3, theland22B would be a substantially planar, rectangular or otherwise rectilinear, surface, substantially or nearly orthogonal to the axis of the cutting insert20B.
Eachbevel24 is angled forward, or in thedirection18 of rotation, above or forward of the outwardlyadjacent land22 by adistance32, at anangle34 from a plane orthogonal to the axis of the cuttinginsert20. Theangle34 can be between approximately 20 degrees and approximately 70 degrees, with a preferred angle of approximately 45 degrees. Put another way, thebevel24 is also angled relative to the axis of the cuttinginsert20, by an angle between approximately 20 degrees and approximately 70 degrees, with a preferred angle of approximately 45 degrees. A representative raiseddistance32 could be on the order of approximately 0.015 inch. It can be seen that, on the round insert20A shown inFIG. 2, thebevel24A would be a substantially frusto-conical surface, angled relative to the axis of the cutting insert20A. It can further be seen that, on the rectilinear insert20B shown inFIG. 3, the bevel24B would be a substantially planar, rectangular or otherwise rectilinear, surface, angled relative to the axis of the cutting insert20B. The cuttinginsert20 can also have arelief angle36 between approximately 3 degrees and approximately 9 degrees, which promotes the cutting action of theedge28 into the work piece. Arear face40 is provided for mounting the cuttinginsert20 on the cutting feature orblade14 of thecutting tool10.
Thedistance32 by which each bevel24 rises above its outwardlyadjacent land22 terminates thebevel24 either in thesurface26 or in an inwardlyadjacent land22, as shown inFIG. 5, in which the cuttinginsert20 has twolands22 and twobevels24. This embodiment has been found to be somewhat more robust in resisting impact than the single land, single bevel embodiment shown inFIG. 4. As shown inFIG. 6, the cuttinginsert20 can have three sets oflands22 and bevels24, or even more. Each land can be relatively narrow, for example, in the range of approximately 0.004 inch to approximately 0.060 inch. As shown inFIG. 7, the cuttinginsert20 can also have other features on its leadingface26, such as adepression38.
While the particular invention as herein shown and disclosed in detail is fully capable of obtaining the objects and providing the advantages hereinbefore stated, it is to be understood that this disclosure is merely illustrative of the presently preferred embodiments of the invention and that no limitations are intended other than as described in the appended claims.