Method and apparatus for milling a window in a well casing or liner

TECHNICAL FIELD

This invention relates to methods and apparatus for milling windows in well casings or liners.

BACKGROUND

Wellbores drilled through the earth's subsurface may be vertical, deviated or horizontal. Moreover, the wells may have one or more lateral branches that extend from a parent wellbore into the surrounding formation. After a wellbore has been drilled, it is typically lined with a casing and/or another liner. The casing extends from the well surface to some distance within the wellbore. Liners on the other hand may line other portions of the wellbore. The casing or liner is typically cemented in the wellbore.

In some cases, it may be desirable to change the trajectory of a wellbore after a casing or liner has been installed. Also, to form a multilateral well, one or more lateral branches are drilled and completed after a casing has been installed.

To change the trajectory of a well or to form a lateral branch from a cased or lined wellbore, a window is formed in the casing or liner to enable drilling of the surrounding formation. Generally, the casing is cut by one or more mills that are mounted on a mandrel at the bottom of a drill string. The mills may have abrasive elements made of sintered tungsten carbide brazed to their surface. When the drill string is lowered into the wellbore, it is deflected toward the casing by a deflection tool with a slanted surface, such as a whipstock. The whipstock may be set in the wellbore either during that run or a prior run. The whipstock is placed at a location in the well where the window will be formed.

Typically, as shown in

FIG. 1

, a milling assembly

10

includes a pilot mill

18

at the end of a mandrel

16

to provide an initial cut in the casing or liner

13

. One or more spaced apart gauge mills or reaming mills

20

,

22

,

24

may follow the pilot mill

18

. The peripheral surface of each mill has abrasive or cutting inserts (not shown) that are made of a hard material such as sintered tungsten carbide compounds. After the initial cut made by the pilot mill

18

in the casing or liner

13

, the mills

20

,

22

, and

24

behind the pilot mill

18

enlarge the pilot window to form a full gauge window.

The mills

20

,

22

,

24

mounted on the mandrel

16

are able to ultimately form a continuous window in the casing or liner

13

. However, because of the arrangement of spaced apart mills on a conventional milling tool, this window is first formed in discrete zones. As shown in

FIG. 2

, the cuts

26

,

28

,

30

, and

32

formed by the mills

18

,

20

,

22

,

24

at one point are discontinuous and will remain so until the milling process is near completion. That is, each mill

18

,

20

,

22

, and

24

enlarges a discrete opening

26

,

28

,

30

, and

32

in the casing

13

that lengthens and deepens over time. These openings are lengthened and widened until they eventually become one continuous full gauge window. This process may create large cuttings when the zones begin to overlap. The large debris may be difficult to remove from the well.

Moreover, milling operations may require different sized mandrels and mills to mill full gauge window. For example, a casing having a first size may require the use of a mandrel having a first diameter whereas a casing having a second size may require the use of a mandrel having a second larger diameter. Alternately, the same mandrel may be utilized in both casings; however, mills may need to be exchanged for differently sized casings.

Thus, a need for an improved milling apparatus and method continues to exist.

SUMMARY

In general, according to one embodiment, a method of milling a window in a liner comprises arranging a plurality of milling elements substantially continuously along a rotatable mandrel and actuating the mandrel to cut a window through the liner. The window is cut substantially continuously using the milling elements to a desired size.

Other or alternative features will become apparent from the following description, from the drawings, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

illustrates an example conventional milling assembly.

FIG. 2

illustrates openings in a casing or liner that are produced by the milling assembly of

FIG. 1

during a milling operation.

FIG. 3A

illustrates an embodiment of a milling assembly according to one embodiment of the present invention.

FIG. 3B

illustrates another embodiment of a milling assembly.

FIG. 4

illustrates the opening in a casing or liner made by the milling assembly of FIG.

3

A.

FIG. 5

illustrates a milling assembly milling a window in surrounding casing.

FIG. 6

is a cross-sectional view of the milling assembly of FIG.

5

.

FIG. 7

illustrates a portion of the milling assembly of FIG.

5

.

FIG. 8

is a longitudinal sectional view of a milling element channel in the milling assembly of FIG.

5

.

FIG. 9

illustrates a continuous milling bar in accordance with an embodiment of the invention.

FIG. 10

is a cross-sectional view of a milling assembly according to another embodiment in a cased wellbore.

FIGS. 11 and 12

are partial cross-sectional views of the milling assemblies to illustrate the use of milling elements that protrude outwardly by different radial distances.

FIGS. 13 and 14

are cross-sectional views of milling assemblies according to other embodiments.

DETAILED DESCRIPTION

As used in this description, positional terms such as “up,” “down,” “upwardly,” “downwardly,” “upper,” and “lower,” and “above” and “below,” and other such terms that indicate position are used to describe some embodiments of this invention. These terms are for reference only and should not be considered as limiting.

As shown in

FIG. 3A

, a milling assembly

40

according to one embodiment, which may be disposed at the end of a drill string, includes a “continuous” milling tool

42

that may be used in combination with one or more mills

48

and

50

to create a window in a surrounding casing or liner

56

. As used here, a “liner” refers to a casing, liner, or any other downhole structure (tubular or otherwise) that is insertable into a wellbore to provide a flow path to the well surface.

The milling assembly

40

is driven by a rotary drive located at surface or by a downhole motor (not shown). The continuous milling tool

42

includes a rotatable mandrel

44

(rotatable by the rotary drive motor) with milling elements

46

disposed thereon. The mandrel

44

is a tubular structure that has threaded connections at each end (not shown). The threaded connection at one end may provide for the attachment of the mandrel

44

to a drill string via an articulated or flexible joint. This joint allows for the deflection of the milling tool

42

off of the well casing's longitudinal axis. Typically, the mandrel

44

is made from alloyed steel, although other materials can also be used.

The milling elements

46

may be disposed along the length of the mandrel

44

in a generally helical or any other desired arrangement. In this embodiment the milling elements

44

generally have a rectangular face

52

. However, any other suitable shape may be utilized, such as a square, diamond, or any other geometrical shape. The embodiment illustrated in

FIG. 3A

has generally a left-handed double helical arrangement of milling elements

46

. In other embodiments, a single-helical or a triple-helical (or other multi-helical) arrangement may be employed. In other embodiments, other predetermined patterns of milling elements

46

may be used.

Thus, generally, the milling tool according to some embodiments of the invention includes a rotatable mandrel having some length, with milling elements arranged substantially continuously along substantially the entire length of the rotatable mandrel. Moreover, milling elements typically encompass substantially less than the circumference of the mandrel. This is contrasted with conventional milling assemblies, such as the one shown in

FIG. 1

that have discrete mills circumferentially mounted on a rotatable mandrel.

The term “substantially continuously” refers to an arrangement of milling elements that enables the milling elements to continuously mill a window in a portion of the surrounding liner, as opposed to milling discrete portions of a window, with further cuttings made to the discrete portions to form the final continuous window. Thus, the substantially continuous arrangement of milling elements enables the milling tool to continuously form a window in a portion of the liner.

The milling elements

46

may be fixedly or removeably attached to the mandrel

44

. For example, the elements

46

may be fixedly attached by brazing the elements

46

onto the outer surface of the mandrel

44

. In another embodiment, the elements

46

may be removeably attached to the mandrel

44

by using any one of a variety of attachment mechanisms. Although the elements

46

may be redressed regardless of how they are attached to the mandrel

44

, removable elements

46

advantageously enable redressing.

The milling elements are also referred to as “milling inserts.” The milling inserts are adapted to be arranged on a surface of the mandrel

44

(either directly on the surface or in a slot or channel formed in the surface). Each milling insert extends less than a fall circumference of the mandrel.

The milling elements are arranged along a “substantial length” of the milling tool. A substantial length refers to a length that is greater than that of a mill (such as a pilot mill, gauge mill, or reaming mill) used in conventional milling tools.

Removable elements

46

have the additional advantage of allowing the tool

42

to be adapted to mill casings or liners of various sizes and to mill windows of various gauges and lengths. Thus, the use of removable milling elements

46

may optimize the milling assembly

40

as a function of, but not limited to, milling conditions such as casing or liner material and hardness, hardness of the surrounding formation, cement characteristics, and the speed and torque of the work string.

In the embodiment of

FIG. 3A

, a pilot mill

48

and a gauge mill

50

are placed ahead of the continuous milling tool

42

. In other words, the pilot mill

48

and gauge mill

50

are more distally arranged on the milling assembly

40

than the continuous milling tool

42

. Other embodiments of the invention may include a pilot mill only (without a gauge mill) or more than two mills.

In yet another embodiment, as shown in

FIG. 3B

, a pilot mill

48

and gauge mill

50

may be placed ahead of the continuous milling tool

42

and one or more reaming mills

51

may be mounted on the milling tool

42

. Alternatively, one or more reaming mills

51

may be placed between adjacent milling tools

42

. In the arrangement of

FIG. 3B

, the continuous milling tool

42

is divided into two continuous milling tool portions. In each continuous milling tool portion, the milling elements

46

are arranged substantially continuously.

Typically, the pilot mill

48

has a diameter that is smaller than the diameter of the gauge mill

50

, as shown in

FIGS. 3A and 3B

. When the pilot mill

48

is engaged with the inner wall of the liner

56

, it provides a pilot opening through the downhole structure.

The gauge mill

50

may or may not be gauged at the full diameter of the desired opening in the casing. The diameter of the gauge mill

50

may be selected to be substantially identical to the inner diameter of the liner to cut a full gauge window. Typically, the gauge mill

50

is placed behind the pilot mill

48

and enlarges the pilot opening to the desired diameter.

The pilot mill

48

and gauge mill

50

may have tungsten carbide cutting inserts (not shown) brazed or otherwise attached to their outer surface to form a cutting surface. Other materials suitable for cutting through a casing may also be utilized. In addition to cutting an opening in the liner, the pilot mill

48

and gauge mill

50

may guide and stabilize the bottom end of the milling assembly on the face of a whipstock.

As shown in

FIG. 4

, the pilot mill

48

produces a pilot opening

54

through the casing or liner

56

, while the gauge mill

50

in conjunction with the milling tool

42

produce one substantially continuous cut

58

through the casing or liner

56

. Like the pilot mill in a conventional milling assembly, the pilot mill

48

in this assembly

40

provides a first cut

54

to initiate the window. Thereafter, the gauge mill

58

, if provided, and the continuous milling tool

42

are deflected to contact the wall of the liner

56

along the length of the milling tool

42

. As a result, a continuous opening

58

is cut in the liner

56

that may form a full gauge window. Moreover, the milling is concentrated on the liner

56

and not on the cement layer and surrounding formation. Thus, the size of milling debris and other particulate material may be reduced to reduce the amount of debris that needs to be removed.

Referring to

FIG. 5

, the milling assembly

40

with the continuous milling tool

42

is positioned in a cased wellbore

60

. An annular cement layer

62

is between the casing

56

and the wellbore

60

. A deflection tool

64

, such as a whipstock, may have been set in the wellbore

60

by conventional means in either a prior run or in the same run as the milling assembly

40

. The deflection tool

64

has an elongated body

66

and a slanted surface

68

to deflect the milling assembly

40

toward the wall of the liner

56

to be cut. Thus, the positioning of the deflection tool

64

will determine where the window will be formed in the liner

56

. Generally, as the milling assembly

40

comes in contact with the deflection tool

64

, a lateral force is placed on the milling assembly

40

that pushes or deflects the milling assembly

40

toward the liner

56

wall. As a result, the milling assembly

40

engages the liner

56

wall that is opposite the force to mill the window. Note that, in an alternative embodiment, the milling assembly may be a whipstock-less milling assembly that does not need the deflection tool

64

. Examples of whipstock-less milling tools are described in U.S. Ser. No. 09/713,048, filed Nov. 15, 2000.

The mandrel

44

may be in one or more sections to support the pilot mill

48

, gauge mill

50

, and the plurality of milling elements

46

. For example, one section may support the pilot mill

48

and gauge mill

50

whereas another section may support the milling elements

46

. In this embodiment, the mandrel

44

has a pair of milling element channels

70

(see

FIGS. 6 and 7

) and fluid circulation grooves

72

. The channels

70

and grooves

72

alternate and are separated by lands

74

. The channels

70

are adapted to receive the milling elements

46

and the circulation grooves

72

allow for the flow of fluid for cooling and/or removal of milling debris. As shown in

FIG. 5

, the milling elements

46

disposed in the channels

70

, the lands

74

, and the grooves

72

form generally parallel helices along the mandrel

44

.

The upper end of the mandrel

44

, as it is oriented in the vertical wellbore

60

, may be connected to a flexible section

76

that in turn connects to the work string. Additionally, the flexible section

76

may connect, either directly or indirectly to a power source such as a positive displacement motor, turbine, a rotary drive at the surface, or mud motor. The flexible section

76

has a pivoting portion to enable the mandrel

44

and its attached mills to be deflected towards the casing or liner wall.

The pilot mill

48

and gauge mill

50

are generally cylindrical and have lands

78

and fluid transfer channels

80

. Abrasive or cutting elements

82

of tungsten carbide may be brazed on the surface of the lands

78

. Fluid flows through the fluid transfer channels

80

to cool the mills

48

and

50

and/or to remove milling debris.

Generally, in operation, as the rotating milling assembly

40

encounters the deflecting tool

64

, it is forced laterally against the wall of the liner

56

. The pilot mill

48

, at the distal end of the assembly

40

, initiates the milling operation by cutting a pilot opening in the casing

56

. The gauge mill

50

and continuous milling tool

42

, behind the pilot mill

48

, engage the pilot opening to enlarge the opening to its desired diameter and length. The deflected gauge mill

50

and continuous milling tool

42

contacts the liner

56

wall along the length of the mill

50

and the tool

42

. Thus, one uninterrupted (or continuous) window is formed in the liner

56

.

FIG. 6

illustrates the cross-sectional view of one example embodiment of the milling tool

40

. The milling elements

46

are disposed within the channels

70

to provide the cutting surface of the continuous milling tool

42

. Each milling element

46

has a face

52

, a base

90

, and two sides

92

. Cutting inserts

94

are mounted on the face

52

of the milling elements

46

. The cutting inserts

94

may be brazed or otherwise embedded on the face

52

of the milling elements

46

. The cutting inserts

94

may be tungsten carbide or any other material suitable for milling a liner.

The sides

92

of the milling elements

46

have upper

96

and lower

98

segments that meet at about the midpoint

100

of each side

92

. The lower segment

98

slopes outwardly from the midpoint

100

to the base

90

. However, the lower segment

98

may take on any configuration that is complementary to the configuration of the milling element channels

70

. The upper segment

96

may also slope outwardly from the midpoint

100

to the face

52

of the element

46

. Alternately, the upper segments

96

may have a substantially straight wall from the midpoint

100

to the face

52

of the elements

46

. The milling element

46

is engaged in the channel

70

in a tongue and groove arrangement.

Once disposed within the channels

70

, individual milling elements

46

may be secured in place with a clamping element

102

such as a wedge. Generally, one side

92

of an element

46

abuts one wall

86

of the channel

70

. As a result, a gap is created between the opposite side

92

of the element

46

and the other complementary wall

86

of the channel

70

. The clamping element

102

is then positioned to fill the gap, securing the element

46

to prevent it from moving within the channel

70

. Because milling elements

46

may be positioned within the channels

70

as desired, the continuous milling tool

42

may be adapted to mill windows of various lengths. Moreover, the number of milling elements

46

per desired length may be varied. Thus, the desired number of milling elements

46

per length of mandrel

44

may be provided for a particular milling job.

In addition to a pair of opposed circulation grooves

72

, the mandrel

44

may also include a central bore

84

for the transport of fluid. The circulation grooves

72

may be generally U-shaped, or some variation thereof, and extend the length of the mandrel

44

in a generally helical arrangement. The circulation grooves

72

and the central bore

84

make up the drilling fluid circulation system. Thus, circulating fluid may flow through the central bore

84

to cool the milling tool

42

and/or transport the milling debris to the surface of the well.

The mandrel

44

also includes a pair of opposed milling element channels

70

. The channels

70

are adjacent to the circulation grooves

72

with the lands

74

between each channel

70

and groove

72

. The channels

70

also extend the length of the mandrel

44

as a helix. In this embodiment the walls

86

of the channels slope inwardly. Thus, the openings of the channels

70

narrow as they extend radially. In this embodiment, the configuration of the channels

70

and the milling elements

46

is complementary. In other embodiments, the channels

70

may take a different form to complement a differently shaped milling element

46

.

An enlarged view of how a series of milling elements

46

are arranged in the channel

70

is illustrated in FIG.

7

. As noted above, the milling elements

46

are secured in place by the clamping element

102

. In addition, spacers

104

are provided to control the density of the milling elements

46

in the channel

70

.

As shown in the longitudinal sectional view of

FIG. 8

, each clamping element

102

is generally L-shaped. A first portion

106

of the clamping elements

102

is disposed between one wall

86

of the channel

70

and one side

92

of the milling element

46

so that the opposite side

92

of the milling element

46

and the channel wall

86

are flush. A second portion

108

of the clamping element

102

extends the width of the channel

70

to fill in any gap between the channel

70

and the milling element

46

.

In another embodiment, individual milling elements

46

may be replaced by a bar

110

, as shown in FIG.

9

. In one embodiment, the bar

110

is formed of a soft iron. Like the milling elements

46

, the bar

110

has a face

112

, two sides

114

and a base

116

. The face

112

of the bar

110

includes a plurality of cutting inserts

94

brazed thereon. The cutting inserts

94

may be tungsten carbide or any other material suitable for milling a liner. The sides

114

and base

116

of the bar

110

are shaped to engage the channel

70

as described above. Thus, the bar

110

may take on a generally helical arrangement as defined by the channel

70

. One end of the bar

110

may have a receptacle

118

for a locking mechanism

120

that includes a locking pin. Therefore, the bar

110

may be inserted into a channel

70

to spiral around the mandrel

44

. Thereafter, the bar

110

may be secured within the channels

70

by positioning a pin

120

within the receptacle

118

.

In yet another embodiment of a milling assembly, shown in

FIG. 10

, a milling element

46

A is secured to a mandrel

44

A by a nut and bolt assembly

122

. In this embodiment, the mandrel

44

A includes a central bore

84

A and circulation grooves

72

A. In addition, the mandrel

44

A includes a channel

124

to receive the milling element

46

A, as well as a bolt bore

126

into which a bolt

130

can be inserted. The milling element

46

A is held in place by a nut

128

when the nut

128

is threaded onto one end of the bolt

130

.

The channel

124

includes a slanted surface

134

that receives the milling element

46

A. The milling element

46

A has a face

138

, two sides

140

and a base

142

. The face

138

of the milling element

46

A includes cutting inserts

94

brazed or otherwise attached thereto.

The bolt

130

may be any conventional bolt that has a threaded connection on one end. The nut

128

is adapted to engage the upwardly depending shoulder

146

of the milling element

46

A and a ridge

136

of the mandrel

44

A.

The continuous milling tools according to some embodiments are adapted to mill windows of various diameters. For example, as shown in

FIG. 11

, the same mandrel

44

may be adapted to have at least two different milling radii R

1

and R

2

. In this example, R

1

is smaller than R

2

. The milling radius of the milling tool

42

depends upon the size of the milling elements

46

that are disposed within the milling element channels

70

. In this example, the milling element

46

having the height H

1

is smaller than the milling element

46

having the height H

2

. Thus, when fitted with milling elements

46

of the height H

1

, the mandrel

44

will have the smaller milling radius R

1

. Additionally, when fitted with milling elements

46

of the height H

2

, the mandrel

44

will have a larger milling radius R

2

.

In an alternate embodiment, the milling radius may be increased by providing a shim

152

to increase the height of the elements

46

, as shown in FIG.

12

. In this embodiment, the elements

46

may all be of the same size. However, the height of a milling element

46

may be increased by positioning the shim

152

between the base

90

of the element

46

and the bottom of the channel

70

. Thus, by placement of the shim

152

the milling radius may be increased from R

1

to R

2

.

Referring to

FIG. 13

, a mandrel

44

B having a different shape (different than that of the mandrel

44

of

FIG. 6

) is shown. Like the mandrel

44

, two channels

70

are provided to carry two rows of milling elements

46

in a generally double-helix arrangement.

Alternatively, more than two channels

70

can be provided to carry more than two rows of milling elements. As shown in

FIG. 14

, three channels

70

are formed in a mandrel

44

C to provide a generally triple-helix arrangement (having three rows of milling elements

46

each arranged generally in a helix).

While the present invention has been described with respect to a limited number of embodiments, those skilled in the art will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover all such modifications and variations as fall within the true spirit and scope of this present invention.

Number	Name	Date	Kind
2207920	Hughes	Jul 1940	A
4710074	Springer	Dec 1987	A
4717290	Reynolds et al.	Jan 1988	A
5445222	Pritchard et al.	Aug 1995	A
5657820	Bailey et al.	Aug 1997	A
5887668	Haugen et al.	Mar 1999	A
5984005	Hart et al.	Nov 1999	A
5988272	Bruce	Nov 1999	A
6070665	Singleton et al.	Jun 2000	A
6155349	Robertson et al.	Dec 2000	A
6202752	Kuck et al.	Mar 2001	B1

Method and apparatus for milling a window in a well casing or liner

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (11)

Foreign Referenced Citations (1)