The present disclosure relates to drilling rigs, and specifically to rig structures for drilling in the petroleum exploration and production industry.
Land-based drilling rigs may be configured to be moved to different locations to drill multiple wells within the same area, traditionally known as a wellsite. In certain situations, the land-based drilling rigs may travel across an already-drilled well for which there is a well-head in place. Further, mast placement on land-drilling rigs may have an effect on drilling activity. For example, depending on mast placement on the drilling rig, an existing well-head may interfere with the location of land-situated equipment such as, for instance, existing wellheads, and may also interfere with raising and lowering of equipment needed for operations.
The present disclosure provides for a mast assembly for a drilling rig. The mast assembly may include a mast formed from a plurality of mast subunits, a lower drilling machine (LDM) coupled to and movable vertically relative to the mast; an upper drilling machine (UDM) coupled to and movable vertically relative to the mast; and an upper mud assembly (UMA) coupled to and movable vertically relative to the mast, wherein the mast subunits are separable when the mast is in a transport configuration such that the LDM is positioned in a first subunit and the UDM is in a second subunit of the mast when the mast is in the transport configuration.
The present disclosure also provides for a method of rigging-down a mast assembly. The method may include moving an LDM downward into a first subunit of a mast in a vertical position; moving a UDM downward into a second subunit of the mast; moving a UMA into a third subunit of the mast; moving the mast into a horizontal position; and disconnecting the first, second, and third subunits of the mast
The present disclosure also provides for a method. The method may include positioning a drilling rig at a wellsite. The drilling rig may include a mast assembly. The mast assembly may include a mast formed from a plurality of mast subunits; a lower drilling machine (LDM) coupled to and movable vertically relative to the mast; an upper drilling machine (UDM) coupled to and movable vertically relative to the mast; and an upper mud assembly (UMA) coupled to and movable vertically relative to the mast. The UMA may include a drilling mud supply pipe adapted to supply drilling fluid to a tubular member gripped by the UDM defining an upper flow path. The mast subunits may be separable when the mast is in a transport configuration such that the LDM is positioned in a first subunit and the UDM is in a second subunit of the mast when the mast is in the transport configuration. The method may include continuously drilling a wellbore using the drilling rig.
The present disclosure is best understood from the following detailed description when read with the accompanying figures. It is emphasized that, in accordance with the standard practice in the industry, various features are not drawn to scale. In fact, the dimensions of the various features may be arbitrarily increased or reduced for clarity of discussion.
It is to be understood that the following disclosure provides many different embodiments, or examples, for implementing different features of various embodiments. Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting. In addition, the present disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed.
Drilling rig 10 may include mast assembly 100.
In some embodiments, mast assembly 100 may include mast 101. Mast 101, as depicted in
In some embodiments, mast 101 may be formed from multiple mast subunits that are joined end-to-end during a rigging-up operation as described further herein below. For the purposes of this disclosure, five mast subunits, mast subunits 101a-101e, are described. However, one having ordinary skill in the art with the benefit of this disclosure will understand that any number of mast subunits may be utilized to form mast 101 without deviating from the scope of this disclosure. Mast subunits 101a-101e may be selectively disconnected when mast assembly 100 is configured in the transport configuration to allow each to be independently transported as discussed further below. In some embodiments, mast assembly 100 may be used with a drilling rig when in the rigged-up configuration for use in rig operations including drilling operations.
In some embodiments, mast assembly 100 may include jib boom 105 positioned at an upper end of mast assembly 100. Jib boom 105 may be used, for example and without limitation, for hoisting of drilling rig equipment or other auxiliary components.
In some embodiments, mast assembly 100 may include one or more pieces of drill rig equipment for use during drilling operations. For example, in some embodiments, mast assembly 100 may include a top drive (not shown). In some embodiments, as depicted in
In some embodiments, mast assembly 100 may include lower drilling machine (LDM) 131. LDM 131 may be used during a drilling operation to, for example and without limitation, raise and lower tubular members. As used herein, tubular members may include drill pipe, drill collars, casing, or other components of a drill string or components added to or removed from a drill string. In some embodiments, LDM 131 may include LDM clamps 133. LDM clamps 133 may be used, for example and without limitation, to engage a tubular member during a drilling operation. LDM 131 may be adapted to rotate the tubular member engaged by LDM clamps 133. In some embodiments, LDM 131 may include LDM slips 135. LDM slips 135 may be positioned to engage a tubular member to, for example and without limitation, allow LDM 131 to move the tubular member vertically relative to mast 101. In some embodiments, LDM 131 may include LDM pinions 137. LDM pinions 137 may engage racks 103 of mast 101. LDM pinions 137 may be driven by one or more motors including, for example and without limitation, hydraulic or electric motors, in order to move LDM 131 vertically along mast 101. In some embodiments, mast assembly 100 may include LDM drag chain 139. LDM drag chain 139 may, for example and without limitation, couple LDM 131 to one or more supply sources including, for example and without limitation, hydraulic connections, drilling fluid connections, electrical power, water, and compressed air supplies. LDM drag chain 139 may include one or more hoses or cables adapted to operatively couple LDM 131 to the supply sources as LDM 131 moves vertically relative to mast 101.
Referring briefly to
Referring again to
In some embodiments, mast assembly 100 may include upper mud assembly (UMA) 141. UMA 141 may include drilling mud supply pipe 143 adapted to supply drilling fluid to a tubular member gripped by UDM 121. Drilling mud supply pipe 143 may fluidly couple to the tubular member gripped by UDM 121 and may, for example and without limitation, be used to supply drilling fluid to a drill string during portions of a drilling operation. In some embodiments, UMA 141 may include mud assembly pinions 145. Mud assembly pinions 145 may engage racks 103 of mast 101. In some embodiments, mud assembly pinions 145 may be driven by one or more motors including, for example and without limitation, hydraulic or electric motors, in order to move UMA 141 vertically along mast 101. In other embodiments, UMA 141 may be moved by UDM 121. In other embodiments, UMA 141 may be moved using a separate hoist such as an air hoist. Such a hoist may include sheaves 147 positioned on mast 101.
In some embodiments, in order to rig-down mast assembly 100 for transport, components of mast assembly 100 may be repositioned within mast assembly 100 such that each is positioned within a specific mast subunit 101a-101e as discussed below. The following discussion is meant as an example of such a rigging-down operation and is not intended to limit the scope of this disclosure as other arrangements of components and mast subunits are contemplated within the scope of this disclosure.
In such a rigging-down operation, any tubular members may be removed from all components of mast assembly 100. In some embodiments, LDM 131 may be lowered into first mast subunit 101a as depicted in
In some embodiments, UDM 121 may be lowered into second mast subunit 101b as depicted in
In some embodiments, LDM drag chain 139 may be decoupled from LDM 131 and repositioned such that LDM drag chain 139 is positioned within third mast subunit 101c as depicted in
Similarly, in some embodiments, UDM drag chain 129 may be decoupled from UDM 121 and repositioned such that UDM drag chain 129 is positioned within third mast subunit 101c as depicted in
In some embodiments, mast assembly 100 may be lowered from the upright position into a lowered or horizontal position as depicted in
In some embodiments, mast subunits 101a-101e of mast assembly 100 may be decoupled as depicted in
In some embodiments, in order to rig-up mast assembly 100, the same operations may be carried out in reverse once mast subunits 101a-101e have arrived at the location where mast assembly 100 is to be used.
In some embodiments, CDU 161 may be mechanically coupled to an upper end of LDM 131 once mast assembly 100 is fully rigged up to drilling rig 10. As depicted in cross section in
Circulation housing 167 may mechanically couple to valve housing 171. Valve housing 171 houses valve 173 positioned to, when closed, isolate the interior of CDU 161 below valve 173, defining lower chamber 175, from the interior of CDU 161 above valve 173, defining upper chamber 177. Lower chamber 175 may be defined between valve 173 and lower seal 165 and may be in fluid communication with inlets 169. Valve 173 may, in some embodiments, be a flapper valve.
Valve housing 171 may mechanically couple to outer extension barrel 179. Outer extension barrel 179 may be positioned about inner extension barrel 181. Inner extension barrel 181 may slide telescopically within outer extension barrel 179 between a retracted configuration (as shown in
The upper end of inner extension barrel 181 may be mechanically coupled to inverted slips assembly 183. Inverted slips assembly 183 may include slips bowl 185 and one or more wedges 187 positioned to grip to a tubular member as further discussed below. Inner extension barrel 181 may also be mechanically coupled to upper seal 189. Upper seal 189 may be positioned to seal against the outer surface of a tubular member held by inverted slips assembly 183. Upper seal 189 may define an upper end of upper chamber 177. In some embodiments, lower seal housing 163, lower seal 165, circulation housing 167, valve housing 171, valve 173, outer extension barrel 179, inner extension barrel 181, inverted slips assembly 183, and upper seal 189 may define a rotating portion of CDU 161 and may be rotated as a unit by rotation of a tubular member held by inverted slips assembly 183.
In some embodiments, CDU 161 may include a nonrotating outer housing assembly 191. Outer housing assembly 191 may include lower housing 193 and upper housing 195. Like lower seal housing 163, lower housing 193 may be mechanically coupled to LDM 131. Upper housing 195 may be coupled to lower housing 193 by one or more linear actuators 197 to move upper housing 195 axially relative to lower housing 193. In some embodiments, linear actuators 197 may be hydraulic pistons, electromechanical actuators, or any other suitable devices.
In some embodiments, lower seal housing 163, lower seal 165, circulation housing 167, valve housing 171, valve 173, and outer extension barrel 179 may be rotatably mechanically coupled to lower housing 193. In some embodiments, inner extension barrel 181, inverted slips assembly 183, and upper seal 189 may be mechanically coupled to upper housing 195. In some embodiments, one or more bearings may be positioned between components of the rotating portion of CDU 161 and components of outer housing assembly 191.
Upper housing 195 may be moved axially between an extended configuration and a retracted configuration to define an extended configuration and a retracted configuration of CDU 161. As upper housing 195 moves, inner extension barrel 181 moves relative to outer extension barrel 179 while maintaining a seal and thereby maintaining upper chamber 177.
During operation, a tubular member may be inserted into CDU 161 such that the lower end of the tubular member is positioned above valve 173 within upper chamber 177 while upper housing 195 is in the extended configuration and gripped by inverted slips assembly 183, and upper seal 189. Upper housing 195 may then be moved axially with respect to lower housing 193 to the retracted configuration, thereby pushing the lower end of the tubular member through valve 173 into lower chamber 175. In some embodiments, the lower end of the tubular member may be positioned into contact with tubular member 40 in order to make-up a threaded connection therebetween. Likewise, once a connection is broken out, upper housing 195 may be moved to the extended configuration, moving the lower end of an upper tubular member from lower chamber 175 into upper chamber 177, allowing valve 173 to close and isolate lower chamber 175 from upper chamber 177.
In some embodiments, drilling rig 10 with mast assembly 100 as described above may be used during normal drilling operations including, for example and without limitation, conventional drilling, tripping in and out, or other operations. In some such embodiments, UDM 121 or LDM 131 may be used to hoist, position, and rotate a drill string. In some embodiments, UDM 121 and LDM 131 may be used to make up or break out pipe connections to add or remove tubular members from the drill string as discussed herein below with or without the use of UMA 141 and CDU 161. Pipe handler 20 may be used to add or remove tubulars during such operations.
In some embodiments, drilling rig 10 may be used during a continuous drilling operation. In such an embodiment, UDM 121, LDM 131, UMA 141, and CDU 161 may be used to continuously circulate drilling fluid through the drill string during drilling operations without stopping or slowing the rotation of or penetration by the drill string into the subsurface formation during the addition of additional tubular members to the drill string.
For example,
As shown in
Once LDM 131 is so aligned, LDM 131 may begin to rotate LDM clamps 133 and LDM slips 135 at a speed to match the rotation of drill string 50, i.e. drilling speed. Once the rotation rate is matched, LDM clamps 133 and LDM slips 135 may each be actuated to engage drill string 50. The weight of drill string 50 may thus be transferred from UDM 121 to LDM 131 while both engage drill string 50. Inverted slips assembly 183, and upper seal 189 may be actuated to engage quill extension 151 and lower seal 165 may be actuated to engage drill string 50 as shown in
The threaded connection between quill extension 151 and drill string 50 may then be broken-out. As LDM 131 rotates drill string 50 at the drilling speed, UDM 121 may slow rotation of quill extension 151 causing the threaded connection between drill string 50 and quill extension 151 to be broken-out as shown in
CDU 161 may then fully extend such that the lower end of quill extension 151 moves upward out of lower chamber 175 and into upper chamber 177 of CDU 161 as shown in
Pipe handler 20 may move a tubular to be added to drill string 50, defined as next drill pipe 55, into position and allow it to be threadedly coupled to the lower end of quill extension 151 as shown in
UDM 121 may move downward such that the lower end of next drill pipe 55 is stabbed into upper chamber 177 of CDU 161 as shown in
CDU 161 may then be partially retracted, extending the lower end of next drill pipe 55 into lower chamber 175 and opening valve 173 as shown in
A threaded connection between next drill pipe 55 and drill string 50 may then be made-up. UDM 121 may rotate quill extension 151 and next drill pipe 55 at a speed higher than the drilling speed at which drill string 50 is rotated by LDM 131, defining a make-up speed. UDM 121 may lower and CDU 161 may be retracted as next drill pipe 55 is threadedly coupled to drill string 50 as shown in
In some embodiments, a similar operation may be undertaken during trip-in or trip-out operations while maintaining continuous mud circulation or rotation of the drill string.
The foregoing outlines features of several embodiments so that a person of ordinary skill in the art may better understand the aspects of the present disclosure. Such features may be replaced by any one of numerous equivalent alternatives, only some of which are disclosed herein. One of ordinary skill in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. One of ordinary skill in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure and that they may make various changes, substitutions, and alterations herein without departing from the spirit and scope of the present disclosure.
This application is a non-provisional application which claims priority from U.S. provisional application No. 62/700,766, filed Jul. 19, 2018, the entirety of which is hereby incorporated by reference.
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Number | Date | Country | |
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20200024908 A1 | Jan 2020 | US |
Number | Date | Country | |
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62700766 | Jul 2018 | US |