The present disclosure relates generally to drilling rigs, and specifically to slingshot rig structures for land drilling in the petroleum exploration and production industry.
Land-based drilling rigs may be configured to be traveled from location to location to drill multiple wells within the same area known as a wellsite. In certain situations, it is necessary to 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 drilling rig. The drilling rig may include a right substructure and a left substructure. The substructures may be positioned generally parallel and spaced apart from each other. The drilling rig may also include a drill rig floor. The drill rig floor may include a V-door. The side of the drill rig floor including the V-door may define the V-door side of the drill rig floor. The V-door may be oriented to face perpendicular to the right substructure. The drilling rig may include a mast. The mast may include an open side which may define a mast V-door side. The open side may be oriented to face perpendicular to the right substructure. The mast may be pivotably coupled to the drill rig floor by one or more pivot points and one or more lower mast attachment points, the mast being pivotable in a direction parallel to the V-door side of the drill rig floor or the mast being pivotable in a direction perpendicular to the V-door side of the drill rig floor.
The present disclosure also provides for a method. The method may include providing a drilling rig. The drilling rig may include a right substructure and a left substructure. The right substructure may include a right lower box and a first strut, the first strut pivotably coupled to the drill rig floor and pivotably coupled to the right lower box. The left substructure may include a left lower box and a second strut, the second strut pivotably coupled to the drill rig floor and pivotably coupled to the left lower box. The substructures may be positioned generally parallel and spaced apart from each other. The drilling rig may include a drill rig floor. The drill rig floor may include a V-door. The side of the drill rig floor including the V-door may define the V-door side of the drill rig floor. The V-door may be oriented to face perpendicular to the right substructure. The method may include providing a mast. The mast may include an open side which may define a mast V-door side. The open side may be oriented to face perpendicular to the right substructure. The method may include mechanically coupling the mast to the drill rig floor and raising the mast into a raised position.
The present disclosure further provides for a hydraulic cylinder skid. The hydraulic cylinder skid includes a skid frame, the skid frame having a rig attachment point. The hydraulic cylinder skid also includes one or more raising cylinders, the raising cylinders pivotably coupled to the skid frame. In addition, the hydraulic cylinder skid includes a hydraulic power unit, the hydraulic power unit mechanically coupled to the skid frame and operatively coupled to the one or more raising cylinders.
The present disclosure provides for a method. The method includes providing a drilling rig. The drilling rig includes a right substructure and a left substructure, the substructures positioned generally parallel and spaced apart from each other. The right substructure includes a right lower box and a first strut, the first strut pivotably coupled to the drill rig floor and pivotably coupled to the right lower box. The left substructure includes a left lower box and a second strut, the second strut pivotably coupled to the drill rig floor and pivotably coupled to the left lower box. The drilling rig also includes a drill rig floor, the drill rig floor including a V-door. The side of the drill rig floor includes the V-door defining the V-door side of the drill rig floor. The V-door is oriented to face perpendicular to the right substructure. The method also includes providing a mast, the mast including an open side defining a mast V-door side. The open side is oriented to face perpendicular to the right substructure. The method also includes mechanically coupling the mast to the drill rig floor and positioning a hydraulic cylinder skid. The hydraulic cylinder skid includes a skid frame, the skid frame having a rig attachment point. The skid also includes one or more raising cylinders, the one or more raising cylinders pivotably coupled to the skid frame. The skid includes a hydraulic power unit, the hydraulic power unit mechanically coupled to the skid frame and operatively coupled to the one or more raising cylinders. The method includes mechanically coupling the skid frame to the drilling rig at the rig attachment point and raising the mast into a raised position using the raising cylinders.
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.
In some embodiments, drill rig floor 20 may include V-door 23. The side of drill rig floor 20 at which V-door 23 is referred to herein as V-door side 22. In some embodiments, V-door side 22 of side saddle slingshot drilling rig 10 may face the right substructure 30. In some embodiments, V-door 23 may be oriented to face perpendicular to right substructure 30. In some embodiments, V-door side 22 may be parallel to right substructure 30.
In some embodiments, mast 50 may include mast V-door side 52, defined as the open side of mast 50. In some embodiments, mast V-door side 52 may be aligned with V-door 23. In some embodiments, mast V-door side 52 may be oriented to face perpendicular to right substructure 30. In some embodiments, mast 50 may be pivotably coupled to drill rig floor 20 by one or more pivot points 60 and one or more lower mast attachment points 62. Lower mast attachment points 62 may be disconnected, allowing mast 50 to pivot on pivot points 60 as further discussed herein below. In some such embodiments, mast 50 may thus be lowerable from the upright position depicted in
In some embodiments, to move mast 50 from the lowered position to the mast raised position, mast 50 may be mechanically and pivotably coupled to drill rig floor 20 by one or more pivot points 60. One or more hydraulic cylinders 150 may be mechanically coupled to mast 50. In some embodiments, hydraulic cylinders 150 may mechanically couple to one or more corresponding upper mast attachment points 56 positioned on mast 50. In some embodiments, mast 50 may include one or more braces 58 positioned to, for example and without limitation, brace mast 50 at upper mast attachment points 56. In some embodiments, mast 50 may be moved into the mast raised position by extending hydraulic cylinders 150 such that mast 50 moves from a horizontal position to a vertical position as depicted in
In some embodiments, as depicted in
As shown in
In some embodiments, as depicted in
In some embodiments, to move mast 50 from the lowered position to the mast raised position, one or more mast hydraulic cylinders 150′ may be coupled to mast 50. In some embodiments, mast hydraulic cylinders 150′ may be positioned on cylinder sub box 152. In some embodiments, cylinder sub box 152 may be mechanically coupled to right substructure 30. In some embodiments, cylinder sub box 152 may include ballast weight 154 to, for example and without limitation, restrict cylinder sub box 152 from overturning. In some embodiments, mast hydraulic cylinders 150′ may be mechanically coupled to upper mast attachment points 56 positioned on mast 50. In some embodiments, mast 50 may be moved into the mast raised position as depicted in
In some embodiments, mast 50′ as depicted in
In some embodiments, hydraulic cylinder skid 200 may include hydraulic power unit 207. Hydraulic power unit 207 may be mechanically coupled to skid frame 201. Hydraulic power unit 207 may generate hydraulic pressure that may be used, for example and without limitation, to extend or retract raising cylinders 203 and cylinder positioning hydraulic cylinders 205. In some embodiments, hydraulic power unit 207 may include hydraulic pump 209. Hydraulic pump 209 may be used to pressurize hydraulic fluid. In some embodiments, hydraulic pump 209 may be powered mechanically by pump engine 211. Pump engine 211 may be, for example and without limitation, a combustion engine or electric motor.
In some embodiments, hydraulic power unit 207 may operatively couple to raising cylinders 203 and cylinder positioning hydraulic cylinders 205 through hydraulic cylinder skid controls 213. Hydraulic cylinder skid controls 213 may include one or more manifolds and valves positioned to control the flow of hydraulic fluid to raising cylinders 203 and cylinder positioning hydraulic cylinders 205 in order to control the extension or retraction of raising cylinders 203 and cylinder positioning hydraulic cylinders 205. In some embodiments, hydraulic cylinder skid controls 213 may be manually operated. In some embodiments, hydraulic cylinder skid controls 213 may be at least partially automated. In such an embodiment, hydraulic cylinder skid controls 213 may include programmable logic controller (PLC) 215 adapted to control the operation of raising cylinders 203 and cylinder positioning hydraulic cylinders 205.
In some embodiments, hydraulic cylinder skid 200 may include other components of a hydraulic system including, for example and without limitation, hydraulic reservoir 217 and hydraulic lines 219. In some embodiments, by including all components of a hydraulic system, hydraulic cylinder skid 200 may be transportable and usable without the need to disassemble or reassembly components of hydraulic cylinder skid 200.
In some embodiments, skid frame 201 may include rig attachment points 221. Rig attachment points 221 may be adapted to allow skid frame 201 to be mechanically coupled to a drilling rig in order to use raising cylinders 203 to interact with components of the drilling rig as discussed further below. Rig attachment points 221 may include, for example and without limitation, one or more holes that correspond to holes formed on the drilling rig to allow a pin-connection to be made to temporarily mechanically couple hydraulic cylinder skid 200 to the drilling rig.
For example,
In some embodiments in which mast 50 is lowerable in a direction parallel to V-door side 22 of side saddle slingshot drilling rig 10′, hydraulic cylinder skid 200 may be used to move mast 50 between the raised and lowered positions while mechanically coupled to side saddle slingshot drilling rig 10′ at an end of lower boxes 130′. In such an embodiment, upper end 203b of raising cylinders 203 may mechanically couple to one or more corresponding upper mast attachment points 56 of mast 50. Raising cylinders 203 may then be extended to move mast 50 from the lowered position to the raised position, or may be retracted to move mast 50 from the raised position to the lowered position. Once mast 50 is in the desired position, raising cylinders 203 may be decoupled from upper mast attachment points 56.
In embodiments in which mast 50 is lowerable in a direction perpendicular to V-door side 22 of side saddle slingshot drilling rig 10′, hydraulic cylinder skid 200 may be used to raise drill rig floor 20 as described above mechanically coupled to side saddle slingshot drilling rig 10′ at an end of lower boxes 130′. In order to raise mast 50 from the lowered position to the raised position, hydraulic cylinder skid 200 may be mechanically coupled to side saddle slingshot drilling rig 10′ at a side of one of lower boxes 130′ depending on the direction in which mast 50 is lowered, denoted in
One having ordinary skill in the art with the benefit of this disclosure will understand that the present disclosure does not limit the order of raising or lowering of mast 50 and drill rig floor 20.
Once drill rig floor 20 and mast 50 are in the desired raised or lowered positions, upper end 203b of raising cylinders 203 may be mechanically decoupled from drill rig floor lifting points 24 and upper mast attachment points 56, raising cylinders 203 may be fully retracted for storage, and hydraulic cylinder skid 200 may be mechanically decoupled from side saddle slingshot drilling rig 10′. During operation or transportation of side saddle slingshot drilling rig 10′, hydraulic cylinder skid 200 needs not remain mechanically coupled to side saddle slingshot drilling rig 10′. In some embodiments, hydraulic cylinder skid 200 may be removed from side saddle slingshot drilling rig 10′ to, for example and without limitation, reduce the weight of, footprint of, and number of components carried by side saddle slingshot drilling rig 10′ during operation or transportation of side saddle slingshot drilling rig 10′. In some embodiments, hydraulic cylinder skid 200 may be transported to a second drilling rig on the same or another wellsite to raise or lower the respective drill floor or mast of the second drilling rig.
In some embodiments, because hydraulic cylinder skid 200 includes raising cylinders 203, cylinder positioning hydraulic cylinders 205, hydraulic power unit 207, hydraulic pump 209, pump engine 211, hydraulic cylinder skid controls 213, hydraulic reservoir 217, and hydraulic lines 219 all mechanically coupled to skid frame 201, hydraulic cylinder skid 200 may be transported as a single unit without the need to disconnect any operative couplings between the components of hydraulic cylinder skid 200. In some embodiments, such as where pump engine 211 is a combustion engine, hydraulic cylinder skid 200 may operate independently without any additional connections to external equipment required.
Although described with respect to side saddle slingshot drilling rig 10′ as described herein, one having ordinary skill in the art with the benefit of this disclosure will understand that hydraulic cylinder skid 200 may be used with any drilling rig with a pivoting drilling floor, pivoting mast, or both
Certain embodiments of the disclosure are directed to a drilling rig. The drilling rig may include a right and a left lower box. The lower boxes may be positioned generally parallel and spaced apart from each other. The drilling rig may include a drill rig floor mechanically coupled to the right lower box by a first strut. The right lower box and first strut may define a right substructure. The drill rig floor may be mechanically coupled to the left lower box by a second strut. The left lower box and second strut may define a left substructure. The struts may be pivotably coupled to the drill rig floor and pivotably coupled to the corresponding lower box. The drill rig floor may include a V-door. The side of the drill rig floor including the V-door may define the V-door side of the drill rig floor. The V-door may be oriented to face perpendicular to the right substructure. The drilling rig may include a mast. The mast may be pivotably coupled to the drill rig floor by one or more pivot points and one or more mast attachment points. The mast may include an open side defining a mast V-door side. The open side may be oriented to face perpendicular to the right substructure.
Certain embodiments of the disclosure are directed to a drilling rig. The drilling rig may include a right and a left lower box. The lower boxes may be positioned generally parallel and spaced apart from each other. The drilling rig may include a drill rig floor mechanically coupled to the right lower box by a first strut. The right lower box and first strut may define a right substructure. The drill rig floor may be mechanically coupled to the left lower box by a second strut. The left lower box and second strut may define a left substructure. The struts may be pivotably coupled to the drill rig floor and pivotably coupled to the corresponding lower box. The drill rig floor may include a V-door. The side of the drill rig floor including the V-door may define the V-door side of the drill rig floor. The V-door may be oriented to face perpendicular to the right substructure. The drilling rig may include a mast. The mast may include one or more mast subcomponents. The mast subcomponents may be mechanically coupled together and to the drill rig floor. The mast may include an open side defining a mast V-door side. The open side may be oriented to face perpendicular to the right substructure.
Certain embodiments of the disclosure are directed to a method. The method may include providing a drilling rig. The drilling rig may include a right and a left lower box. The lower boxes may be positioned generally parallel and spaced apart from each other. The drilling rig may include a drill rig floor mechanically coupled to the right lower box by a first strut. The right lower box and first strut may define a right substructure. The drill rig floor may be mechanically coupled to the left lower box by a second strut. The left lower box and second strut may define a left substructure. The struts may be pivotably coupled to the drill rig floor and pivotably coupled to the corresponding lower box. The drill rig floor may include a V-door. The side of the drill rig floor including the V-door may define the V-door side of the drill rig floor. The V-door may be oriented to face perpendicular to the right substructure. The drill rig floor may include one or more pivot points. The method may include providing a mast. The mast may include an open side defining a mast V-door side. The open side may be oriented to face perpendicular to the right substructure. The method may include mechanically coupling the mast to the one or more pivot points, mechanically coupling one or more hydraulic cylinders to the mast, and raising the mast into a raised position.
Certain embodiments of the disclosure are directed to a method. The method may include providing a drilling rig. The drilling rig may include a right and a left lower box. The lower boxes may be positioned generally parallel and spaced apart from each other. The drilling rig may include a drill rig floor mechanically coupled to the right lower box by a first strut. The right lower box and first strut may define a right substructure. The drill rig floor may be mechanically coupled to the left lower box by a second strut. The left lower box and second strut may define a left substructure. The struts may be pivotably coupled to the drill rig floor and pivotably coupled to the corresponding lower box. The drill rig floor may include a V-door. The side of the drill rig floor including the V-door may define the V-door side of the drill rig floor. The V-door may be oriented to face perpendicular to the right substructure. The method may include providing a lower mast subcomponent. The lower mast subcomponent may include an open side defining a V-door side of the lower mast subcomponent. The V-door side of the lower mast subcomponent may be oriented to face perpendicular to the right substructure. The method may further comprise mechanically coupling the lower mast subcomponent to the drill rig floor. The method may further comprise providing a mast subcomponent, positioning the mast subcomponent within the lower mast subcomponent, hoisting the mast subcomponent, and mechanically coupling the mast subcomponent to the lower mast subcomponent.
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 divisional application of U.S. non-provisional application Ser. No. 16/246,472, filed Jan. 12, 2019, which is a continuation of and claims priority from U.S. non-provisional application Ser. No. 15/615,322, filed Jun. 6, 2017, which itself claims priority from U.S. provisional application No. 62/346,982, filed Jun. 7, 2016, each of which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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62346982 | Jun 2016 | US |
Number | Date | Country | |
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Parent | 16246472 | Jan 2019 | US |
Child | 16874288 | US |
Number | Date | Country | |
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Parent | 15615322 | Jun 2017 | US |
Child | 16246472 | US |