MILLING OF CEMENTED TUBULARS

Abstract

A method and apparatus for milling an item in a wellbore. The method and apparatus including providing a milling tool having one or more blades which are geometrically configured to resist deflection by distributing cutting forces in multiple directions.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.

FIG. 1 illustrates a schematic of a wellbore with a milling tool according to one embodiment of the present invention.

FIG. 2 is a perspective view of a milling tool according to one embodiment of the present invention.

FIG. 3 is a cross sectional view of a milling tool according to one embodiment of the present invention.

FIG. 4 is a perspective view of a milling end of the milling tool according to one embodiment of the present invention.

FIGS. 5A-5E are views of cutting structures of the milling tool according to one embodiment of the present invention.

FIGS. 6A-6C illustrate a schematic of the cutting structure of the milling tool according to one embodiment of the present invention.

FIG. 7 is an end view of the milling tool according to one embodiment of the present invention.

FIG. 8 is an end view of the milling tool according to one embodiment of the present invention.

FIG. 9 is an end view of the milling tool according to one embodiment of the present invention.

FIG. 10 is an end view of the milling tool according to one embodiment of the present invention.

FIG. 11 is an end view of the milling tool according to one embodiment of the present invention.

FIG. 12 is an end view of the milling tool according to one embodiment of the present invention.

DETAILED DESCRIPTION

Embodiments of apparatus and methods for milling an item in a wellbore are provided. In one embodiment, a milling tool is configured to have blades that are geometrically designed to increase the life and penetration of the mill. The milling tool is coupled to a conveyance, such as a drill pipe or coiled tubing, and lowered into a wellbore. The milling tool is lowered until it reaches an item that is stuck in the wellbore, such as a drill pipe. The item in the wellbore may prevent use of the wellbore below the item. The milling tool then engages the item while the milling tool is rotated. The geometric configuration of the milling tool has an increased resistance to deflection and torsion. The increased resistance to deflection and torsion allows the blades to be longer than those of conventional milling tools. The increased length increases the life and penetration achieved by the milling tool. The milling tool continues to mill through the item until access to the wellbore has been regained. The milling tool is then removed from the wellbore, and drilling and/or production operations may proceed in the wellbore.

FIG. 1 shows a wellbore 100 with a casing 102 cemented in place, a drill rig 104, a conveyance 108, a milling tool 110, and an item 112 stuck in the wellbore 100. The conveyance 108 may be a drill string which may be rotated and axially translated from the drill rig 104; however, it should be appreciated that the conveyance could be any conveyance such as a co-rod, a wire line, a slick line, coiled tubing, casing. The milling tool 110 may be coupled to a drilling motor (not shown) in order to rotate the milling tool in a manner independent from the conveyance. The conveyance 108 is connected to the milling tool 110 at its lower end. The milling tool 110, as will be described in more detail below, is lowered into the wellbore 100 until it engages the item 112 that is stuck in the wellbore. The item 112, as shown, is a drill pipe which has been cemented into place; however, the item 112 could be any suitable item stuck in the wellbore 100 including, but not limited to: casing, production tubing, liner, centralizers, whipstocks, packers, valves, drill bits, drill shoes. Optionally, the item 112 may be cemented in place in the wellbore 100. Preferably, the milling tool 110 engages the item 112 while the milling tool 110 rotates. A milling end 114 of the milling tool 110 then mills away the item 112 and any cement attached to the item 112. The milling tool 110 may have one or more blades which may be geometrically configured to resist deflection. The milling tool 110 is lowered while rotating and milling until the item 112 is no longer obstructing the wellbore 100.

FIG. 2 is a perspective view of the milling tool 110. The milling tool 110 has a body 200 with a connector end 202 and a milling end 204. The connector 202, as shown, is simply a threaded connection member to coupling the milling tool to the conveyance 108. The body 200, as shown, is a cylindrical member adapted for transferring rotation from the conveyance 108 to the milling end 204. The body 200 may be of any suitable length or shape so long as it is capable of transferring rotation and axial force to the milling end 204 of the body 200. The body 200 may optionally include one or more stabilizers 206 for centering and stabilizing the milling tool 100 during milling.

The milling end 204, as shown, has a face 208, one or more blades 210, one or more cutting structures which may include any combination of one or more inserts 212, an amorphous structure 214, and a reinforcing member 216. The face 208 may be a substantially flat end of the body 200 adapted to couple one or more blades 210, the amorphous structure 214, and other members, (not shown), to the body 200. The one or more blades 210 have a height H which extends beyond the face 208 of the milling tool 110. The one or more blades 210 may be geometrically configured to resist deflection, as will be described in more detail below. The amorphous structure 214 may be arranged to increase the one or more blades' 210 resistance to deflection and torsion, while increasing the rate of penetration of the milling tool 100, as will be described in more detail below.

FIG. 3 shows a cross sectional view of the milling tool 110. The body 200 is shown having a flow path 300 for conveying fluid from the conveyance 108 to the face 208. As shown, the flow path 300 splits into two paths near the face 208; however, it should be appreciated that there could be any suitable number of paths at the face 208. The flow path 300 may convey fluids, such as drilling mud, to the milling end 204 of the milling tool 110 in order to lubricate and cool the milling tool 110 and wash away any cuttings that are created during milling. The flow path 300 delivers the fluid to the side of the one or more blades 210 having the inserts 212.

The one or more blades 210 may be embedded into the face 208. This may be accomplished by creating a groove (not shown) in the face 208 to correspond with the geometry of a coupling end 302 of the corresponding blade 210. The coupling end 302 of the blade 210 may be located in the groove and secured to the face 208 by welding or other suitable connection methods. The coupling end 302 of the blade may also be welded directly to the face and not embedded.

In an alternative embodiment, the one or more blades 210 may be integral with the milling end 204 of the milling tool 110. In this embodiment, one or more of the blades 210 may be constructed from the milling tool 110. For example, the blade 210 may be milled from a piece of metal when forming the milling tool 110, or cast with the milling tool 110. In this embodiment, the one or more blades 210 are all form one piece of the milling tool 110.

FIG. 4 shows a perspective view of milling end 204 of the milling tool. The one or more blades 210 are embedded in the face 208 as described above. The one or more blades 210 may extend radially beyond the face 208, as shown. When the one or more blades 210 extend beyond the face 208, the reinforcing member 216 may be included to structurally reinforce one or more outer edges 400 on the blades 210. The reinforcing members 216 may extend beyond the outer diameter of the body 200 and may be coupled to the coupling end 302 of the blades 210. As shown, the coupling end 302 of the blades 210 are flush with the reinforcing members 216; however, it should be appreciated that the coupling end 302 may be embedded into the reinforcing members 216.

The amorphous cutting structure 214 may be used to enhance mill life. The amorphous cutting structure 214 may comprise a crushed carbide with a support structure, such as brass, silver, nickel, plastic, fiber glass, etc, which is brazed onto the milling end 204 of the milling tool 110, in addition or alternatively the amorphous structure 214 may comprise inserts, PDC, a diamond impregnated matrix, or any suitable cutting structure or combination thereof. The amorphous structure 214 is shown attached to the face 208 and filling a space between created by the one or more blades 210. The amorphous structure 214, as shown, is filled to a height that is greater than the height of the blades 210; however, it should be appreciated that it could have any height. The amorphous structure 214 may also be placed on the cutting edge of the blades 210 in addition, or as an alternative, to the inserts 212. The amorphous structure 214 and the inserts 212 may mill the item 112.

The inserts 212, as shown in FIG. 4, include one or more shaped structures 402 for containing the cutting structure coupled to the one or more blades 210. The shaped structures 402 may be in any configuration depending on the operation. FIGS. 5A-5E show embodiments of insert 212 configurations. The shaped structures 402 may have a variety of widths and shapes that may be placed in a staggered configuration. Further, the shaped structures 402 may include a variety of cutting structures in order to increase the life of the mill. In one embodiment, the cutting structure of the inserts 212 includes a layered carbide impregnated insert. The layered carbide impregnated insert includes one layer of a relatively harder tungsten carbide ball fill in a tungsten carbide matrix. For example the hard tungsten carbide ball fill may include a relatively low cobalt content (13% or less) and the tungsten carbide matrix may include a relatively high cobalt content (13%-20%). The second layer is a wear grade tungsten carbide. The carbide may be microwave sintered or applied using any known technique. FIG. 6A depicts the layered carbide impregnated insert 600. The layered carbide impregnated insert 200 may comprise an impregnated carbide layer 602 and a wear grade carbide layer 604. In an alternative embodiment, the insert 212 may be a layered diamond impregnated insert 606, as shown in FIG. 6B. The diamond impregnated insert 606 includes at least two layers. One of the layers is a diamond fill in a tungsten carbide matrix 608. The second layer is a wear grade tungsten carbide 610. The carbide may be microwave sintered or applied using any known technique. In yet another alternative embodiment, the insert 212 may be a full diamond impregnated insert 612, shown in FIG. 6C. This insert includes diamonds impregnated in tungsten. The carbide may be microwave sintered or applied using any known technique. Further, any suitable insert may be used. Any of these inserts may be used in combination.

In general, a minimum number of blades, typically 4 or more, are needed to provide smooth milling. By structurally joining two blades at an apex or bend, the blades provide for smooth milling and have an added stiffness. The increase in stiffness allows for the blades to increase in height thereby increasing the life of the milling tool 110. FIG. 7 shows an end view of the milling end 204. The one or more blades 210 are bent in a manner that gives the blades 210 a self supporting rigidity. The one or more blades 210 have a length L and a width W. The one or more blades 210 have a bend 700 formed in the blades 210. The bend 700 creates two blade legs 702A and 702B which extend from the bend at an angle θ. In one example the optimal angle is 50-60 degrees. The angle θ may be any suitable angle that gives the blades 210 self supporting rigidity. The length of each of the legs 702A and 702B may be equal or not equal depending on the milling operation. Deflection may be calculated using the following:

$y_A:=\frac{-W}{6·E·I}·\left(2·L^3-3·L^2·a+a^3\right)$

Area moment of inertia=I (in̂4)

Length of beam=L (ft)

Distance from left edge to load=a (ft)

Modulus of elasticity=E (lbf/in̂2)

Load=W (lbf)

Increasing area moment of inertia [I] decreases deflection [y(a)]

                                 Radius:Angle: R ≡ 6 · inα ≡ 60 · deg
I                      2                                        :=                                                                                            R                          4                                                12                                            ·                                                                                                                                  [                                                                                                (                                                                                                            3                                      ·                                      α                                                                        -                                                                          3                                      ·                                                                              sin                                                                                                                          (                                          α                                          )                                                                                                                    ·                                                                              cos                                                                                                                          (                                          α                                          )                                                                                                                                                                                      )                                                                -                                                                                                                                                                                                                                                                                          2                                  ·                                  sin                                                                                                                                                                                                            (                                      α                                      )                                                                        3                                                                    ·                                                                      cos                                                                                                              (                                      α                                      )                                                                                                                                                                  ] I2 = 128.848 in4
Rectangle:
I                      2                                        :=                                                                  1                        12                                            ·                      d                      ·                                              b                        3 I2 = 6.859 × 10−3 in4

The legs 702A and 702B are shown as extending beyond the reinforcing structure 216; however, the legs 702A and 702B may be arranged to not extend beyond the reinforcing structure 216 or the face 208. Although the bend 700 is shown as having a constant radius, it should be appreciated that the angle θ may be created in any manner, for example two plates may be welded at a point thus having no bend, or the radius of curvature could vary between the legs 702A and 702B. Further, each blade may have more than two legs 702 all at various angles relative to one another. This geometry of the blades 210 allows the height of the blades to increase well beyond 2″. In one embodiment, the height of the blades 210 is 4″ beyond the face of the milling tool 110. As shown, there are two blades 210; however, any number of blades 210 may be arranged on the face 208 of the milling tool 110.

A center void 704 between the one or more blades 210 in the center of the face 208 may be filled with the amorphous structure 214, and/or one or more inserts. Further, a space 706 between the legs 702A and 702B may be filled with the amorphous structure 214. As discussed above, the cutting side of the blades 210 may have one or more cutting inserts 212. The face 208 may further include a compact cutting inserts 800, shown in FIGS. 8-11 located between the blades. The compact insert may be located in the center void 704 to alleviate the effects of coring during milling. The compact insert in the center void 704 allows the coring mechanism to enter the void 704 and then deflect toward the edge of the face 208 after contacting the compact insert.

FIGS. 8-12 show end views of the milling tool 110 having multiple blade configurations. FIG. 8 shows two L shaped blades with an optional compact insert located in the center void. FIG. 9 shows two V shaped blades with an optional compact insert located in the center void. FIG. 10 shows three V shaped blades with an optional compact insert located in the center void. FIG. 11 shows two J shaped blades with two straight blades. FIG. 12 shows, the bends of the blades be continuous along the length of the blade and having an S shape, or wave shape. Further, the blades 210 could have any suitable shape and/or include a number of patterns.

Although not show, it should be appreciated that the bend 700 of the blades may be positioned toward a radial exterior of the milling tool 110. In this embodiment, the legs 702A and 702B may extend from the bend toward the interior of the face, and/or toward another location on the radial exterior of the face. Further, there may be multiple blades 210 having bends 700 on the radial exterior of the face. These, multiple blades may have legs 702A and 702B which terminate adjacent to one another, or overlap one another.

In an alternative embodiment, the each of the blades 210 could have a different height H, or the height H of the blade 210 could vary along blade. Further, the milling tool 110 may be designed as a milling and drilling tool. For example the blades 210 may be designed for milling and drilling members may be located at a lower height than the height H of the blades 210. This allows for milling until the blades 210 wear down to the height of the drilling members at which time drilling may begin.

The contact area (the L multiplied by the W) of any of the blades 210 described above has a direct effect on the cutting speed and life of the blade 210. As the contact area is increased, the life of the milling tool 110 will increase however the speed at which the milling tool 110 mills is decreased. A contact pressure is created at the blades 210 by putting weight on the milling tool 110. The contact pressure is the weight divided by the contact area. When the weight is constant any loss of the contact area due to wear will increase the contact pressure of the blades. The increased contact pressure wears the blades at a greater rate, thus, affecting the life of the milling tool. Thus, optimal results occur when little or no contact area is lost during milling. The blades 210 are designed to expose the same amount of carbide as the height H of the blades 210 is worn down. Therefore, as the blades 210 are worn down the contact area remains substantially the same allowing the milling tool 110 to perform the same as milling continues.

In operation the milling tool 110 is coupled to the conveyance 108, such as a section of drill pipe at the surface. The milling tool 110 is run into the wellbore 100 as additional pipe joints are couple to the conveyance 108. The milling tool 110 is lowered until it is adjacent the stuck item 112 in the wellbore 100. The milling tool 110 may then be rotated in a cutting direction either by a downhole motor, and/or by rotating the conveyance 108 at the surface. Preferably the milling tool 110 is rotated as it is lowered into contact with the item 112 in order to commence the milling operation. An operator controls the amount of weight placed on the milling tool 110 and the rotational speed of the milling tool 110. The weight may be increased or decreased. While milling fluid flows through flow path 300 and out the face 208. The fluid lubricates the milling end 204 of the tool and pushes the cuttings toward the wellbore surface.

With the milling tool 110 rotating and in contact with the item 112, the one or more cutting structures, the inserts 212 and the amorphous structure 214 begin to mill away the item 112. When the amorphous structure 214 is placed above the height H of the blades 210, the amorphous structure 214 begins the milling. The amorphous structure 214 mills and wears down as it mills. It wears down until it is close to the blades 210 at which point both the inserts 212 and the amorphous structure 214 mill away at the item. With the inserts 212 milling, a cutting force may be exerted on the one or more blades 210. The cutting force will wear away the blades 210, the inserts 212 and the amorphous structure 214 while milling. The geometry of the blades 210 resists the cutting force, thereby decreasing the deflection of the blades 210. As the cutting force transfers to the blades, the cutting force will be dispersed along the legs 702A and 702B and through the bend 700. The bend 700 and the legs 702 create multi-directional resistance to the cutting force. The geometry allows a 4″ blade to deflect less than 0.02″ at the lower end, and/or the deflection per inch of the blade height is less than 0.01″. The resistance to deflection may be increased by increasing the distance the blade 210 is embedded into the face 208 of the milling tool. Further, the amorphous structure 214 in the center void 204 and the space 706 increase the blades 210 resistance to deflection.

The milling tool 110 continues to rotate while the cutting structures are worn down. The configuration of the tool allows the milling tool 100 to operate up to 5 times longer than traditional milling tools. Therefore, the amount of rig time used to change milling tools 110 is reduced. When the milling operation is complete the milling tool 110 is run out of the wellbore 100. The wellbore 100 may then be accessed for continued production and drilling operations.

While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.

Claims

1. A milling tool for use in a wellbore, comprising: a body having a connector end and a milling end;the connector end configured to couple the body to a conveyance; andthe milling end comprising: a face;one or more blades coupled to the face, at least one of the blades having a height dimension which extends beyond the face and a length dimension, wherein at least a portion of the length dimension couples to the face in a non-planar configuration along one side of the blade.

2. The milling tool of claim 1, further comprising an angle in the one or more or the blades, wherein the angle is between two blade legs which extend from an interior of the face radially outward to an exterior edge of the face.

3. The milling tool of claim 1, further comprising one or more cutting structures coupled to the milling end of the milling tool.

4. The milling tool of claim 3, wherein one of the cutting structures comprises an amorphous cutting structure.

5. The milling tool of claim 4, wherein the amorphous cutting structure is located in a space between two or more legs of the one or more blades.

6. The milling tool of claim 5, wherein the amorphous cutting structure is located substantially in the center of the face between two or more blades.

7. The milling tool of claim 4, wherein the amorphous cutting structure is crushed carbide.

8. The milling tool of claim 3, wherein one of the cutting structures comprises an insert.

9. The milling tool of claim 8, wherein the insert is a layered carbide impregnated insert.

10. The milling tool of claim 9, wherein the layered carbide impregnated insert comprises one layer of hard tungsten carbide balls that are impregnated in a softer tungsten matrix.

11. The milling tool of claim 10, wherein the layered carbide impregnated insert comprises a second layer is a wear grade tungsten carbide.

12. The milling tool of claim 10, wherein the layered carbide is microwave sintered.

13. The milling tool of claim 2, wherein the at least one of the blades is embedded into the face so that a portion of the blade height is below the face and a portion extends beyond the face.

14. The milling tool of claim 1, wherein the height dimension is greater than 2″.

15. The milling tool of claim 1, wherein the height dimension is greater than 3.5″.

16. A method for milling an item in a wellbore, the method comprising: providing a milling tool having milling end, wherein the milling end comprises a face and one or more blades and wherein at least one of the one or more blades has a portion that couples to the face in a non planar configuration;coupling the milling tool to a conveyance;running the conveyance into a wellbore;rotating the milling tool;engaging the item with the milling end; andmilling the item with one or more blades.

17. The method of claim 16, further comprising providing an amorphous cutting structure on the face of the milling end.

18. The method of claim 16, further comprising flowing a fluid through one or more ports on the face of the milling tool while milling.

19. The method of claim 16, wherein the non planar configuration of the at least one blade further comprises a bend located between two legs of the blade.

20. The method of claim 19, further comprising dispersing a cutting force through a bend during milling.

21. An milling tool configured to mill in a wellbore, the milling tool comprising: a face; andone or more blades on the face, wherein at least one of the one or more blades comprises two legs and a bend located between the legs.

22. The milling tool of claim 21, wherein the bend is located toward a radial interior of the face and each of the legs extend radially outward along the face.

23. The milling tool of claim 21, wherein the bend is configured to disperse a cutting force from one of the legs to the other during a milling operation.

24. The milling tool of claim 21, wherein the bend is configured to resist deflection with the blade by distributing cutting forces in the legs.

25. The milling tool of claim 21, wherein the blades are integral with the milling tool.

26. A method for milling an item in a wellbore, the method comprising: providing a milling tool having milling end, wherein the milling end comprises a face and one or more blades;coupling the milling tool to a conveyance;running the conveyance into a wellbore;rotating the milling tool;engaging the item with the milling end;dispersing a cutting force through a bend in at least one of the one or more blades; andcutting the item with one or more blades coupled to the milling end.