The present invention relates to an apparatus and method for use in subterranean exploration. The present invention provides a rapid rig-up and rig-down pipe racking system that is capable of being retrofit to an existing drilling rig. In particular, the invention relates to a pipe drill floor mounted pipe racking system that is capable of controlled movement of pipe in three dimensions, and most importantly, capable of rapid and precise movement of multiple connected sections of pipe. The invention is capable of moving stands of connected pipe from a racked position on the drill floor to an accurate stabbing position directly above a drill string component held in a rotary table.
In the exploration of oil, gas and geothermal energy, drilling operations are used to create boreholes, or wells, in the earth. Subterranean drilling necessarily involves the movement of long lengths of tubular sections of pipe. At various intervals in the drilling operation, all of the drill pipe must be removed from the wellbore. This most commonly occurs when a drill bit wears out, requiring a new drill bit to be located at the end of the drill string. It can also be necessary to reconfigure the bottom-hole assembly or replace other downhole equipment that has otherwise failed. When the drill pipe has to be removed, it is disconnected at every second or third connection, depending on the height of the mast. On smaller drilling rigs used in shallower drilling, every other connection is disconnected, and two lengths of drill pipe, known as “doubles” are lifted off of the drill string, aligned in the fingers of the rack by the derrickman, and then lowered onto the drill floor away from the well center. On larger drilling rigs used for deeper drilling, every third connection is disconnected and three lengths of drill pipe, known as “triples” are lifted off of the drill string, aligned in the fingers of the rack by the derrickman, and then lowered onto the drill floor away from the well center. The doubles and triples are called a stand of pipe. The stands are stored vertically on the rig floor, aligned neatly between the fingers of the rack on the mast.
Removing all of the drill pipe from the well and then reconnecting it to run back into the well is known as “tripping the pipe” or “making a trip,” since the drill bit is making a round trip from the bottom of the hole to the surface and then back to the bottom of the hole. Tripping the drill pipe is a very expensive and dangerous operation for a drilling rig. Most injuries that occur on a drilling rig are related to tripping the pipe. Additionally, the wellbore is making no progress while the pipe is being tripped, so it is downtime that is undesirable. This is why quality drill bits are critical to a successful drill bit operation. Drill bits that fail prematurely can add significant cost to a drilling operation. Since tripping pipe is “non-drilling time,” it is desirable to complete the trip as quickly as possible. Most crews are expected to move the pipe as quickly as possible. The pipe stands are long and thin (about ninety feet long).
There are a number of variables that contribute to irregular and hostile movement of the pipe stand as it is disconnected and moved to the rack for setting on the drill floor, as well as when it is being picked up for alignment over the wellbore center for stabbing and connection to the drill string in the wellbore. For example, the vertical alignment and travel of the elevator and hoist connection which lift the drill string from the wellbore is cable connected, and capable of lateral movement which is translated to the drill string rising from the wellbore. Also, the drill string is supported from the top, and as the derrickman moves the drill string laterally, the accelerated lateral movement of the long length of the pipe stand away from the well center generates a wave form movement in the pipe itself. As a result of the natural and hostile movement of the heavy drill stand, which typically weighs between 1,500 and 2,000 lbs., and drill collars which weigh up to 20,000 lbs., it is necessary for crew members to stabilize the drill pipe manually by physically wrestling the pipe into position. The activity also requires experienced and coordinated movement between the driller operating the drawworks and the derrickman and floorhands. Needless to say, many things can and do go wrong in this process, which is why tripping pipe and pipe racking is a primary safety issue in a drilling operation.
Attempts have been made to mechanize all or part of the pipe racking operation. On offshore platforms, where funding is justifiable and where drill floor space is available, large Cartesian racking systems have been employed, in which the pipe stands are gripped at upper and lower positions to add stabilization, and tracked modules at the top and bottom of the pipe stand coordinate the movement of the pipe stand from the wellbore center to a racked position. Such systems are very large and very expensive, and are not suitable for use on a traditional land based drilling rig.
A previous attempt to mechanize pipe racking on conventional land based drilling rigs is known as the Iron Derrickman® pipe-handling system. The apparatus is attached high in the mast, at the rack board, and relies on a system of hydraulics to lift and move stands of drill pipe and collars from the hole center to programmed coordinates in the racking board. This cantilever mast mounted system has a relatively low vertical load limit, and therefore requires assistance of the top drive when handling larger diameter collars and heavy weight collars.
The movement of the pipe with this system is somewhat unpredictable and requires significant experience to control. It grasps the pipe from above the center of gravity of the tubular and fails to control the hostile movement of the pipe stand sufficiently to allow for safe handling of the stands or for timely movement without the intervention of drilling crew members. In particular, the system is not capable for aligning the lower free end of the drill stand accurately for stabbing into the drill string in the wellbore. As a result of these and other deficiencies, the system has had limited acceptance in the drilling industry.
An alternative system that is known provides vertical lifting capacity from the top drive and a lateral movement only guidance system located near the rack. The system still requires a floorman for stabbing the pipe to the stump as well as to the set-back position.
A primary difficulty in mechanizing pipe stand racking is the hostile movement of the pipe that is generated by stored energy in the stand, misaligned vertical movement, and the lateral acceleration and resultant bending and oscillation of the pipe, which combine to generate hostile and often unpredictable movements of the pipe, making it hard to position, and extremely difficult to stab.
A conflicting difficulty in mechanizing pipe stand racking is the need to move the pipe with sufficient rapidity that cost savings are obtained over the cost of manual manipulation by an experienced drilling crew. The greater accelerations required for rapid movement store greater amounts of energy in the pipe stand, and greater attenuated movement of the stand.
Another primary obstacle in mechanizing pipe stand racking is the prediction and controlled management of the pipe stand movement sufficient to permit the precise alignment required for stabbing the pipe to a first target location on the drill floor and to a second target location within the fingers of the racking board.
An even greater obstacle in mechanizing pipe stand racking is the prediction and controlled management of the pipe stand movement sufficient to achieve the precise alignment required for stabbing the tool joint of the tubular held by the racking mechanism into the receiving tubular tool joint connection extending above the wellbore and drill floor.
Another obstacle to land-based mechanizing pipe stand racking is the lack of drilling floor space to accommodate a railed system like those that can be used on large offshore drilling rigs.
Another obstacle to mechanizing pipe stand racking is the several structural constraints that are presented by the thousands of existing conventional drilling rigs, where the need to retrofit is constrained to available space and structure. For example, existing structures require orthogonal movement of the drill stand over a significant distance and along narrow pathways for movement.
Another obstacle to mechanizing pipe stand racking is the need to provide a reliable mechanized solution that is also affordable for retrofit to a conventional drilling rig. Still another obstacle to mechanizing pipe stand racking is the need to grip and lift pipe stands within the narrow confines of parallel rows of pipe stands in a conventional rack.
It is also desirable to minimize accessory structure and equipment, particularly structure and equipment that may interfere with transportation or with manpower movement and access to the rig floor during drilling operations. It is further desirable to ergonomically limit the manpower interactions with rig components during rig-up for cost, safety and convenience.
Thus, technological and economic barriers have prevented the development of a pipe racking system capable of achieving these goals. Conventional prior art drilling rig configurations remain manpower and equipment intensive to trip pipe and rack pipe when tripping. Alternative designs have failed to meet the economic and reliability requirements necessary to achieve commercial application. In particular, prior art designs fail to control the natural attenuation of the pipe and fail to position the pipe with sufficient rapidity and accuracy.
A goal of the racker invention is to achieve rapid and accurate unmanned movement of the pipe between the racked position and the over-well position. Thus, the racker must avoid storage of energy within the positioning structure. True verticality is critical to limiting the energy storage of the system. Additionally, controlled movement and positional holding of the stand is critical to allowing rapid movement by adding the stiffness to the system.
In summary, the various embodiments of the present invention provide a unique solution to the problems arising from a series of overlapping design constraints, including limited drill floor space, and obtaining sufficient stiffness from a retrofittable assembly to provide a controlled and precise automated movement and racking of drill pipe. More specifically, the various embodiments of the present invention provide for lateral movement of the pipe stand independent of assistance from the top drive, and without extension and retraction of the top drive for handing the pipe stand to the racking system. This provides free time for the top drive to move with the racker system in positioning the pipe without assistance from the top drive. Additionally, the various embodiments of the present invention provide a device capable of precise and accurate stabbing of the drill stand, resulting in faster trip time.
The present invention provides a new and novel pipe stand racking system and method of use. In one embodiment, an automatic pipe racker is provided, having a base frame connectable to a drill floor of a drill rig and extending upwards at a position offset to a V-door side of a drilling mast that is also connected to the drill floor. In one embodiment, the base frame is a C-frame design. A mast brace may be connected between the base frame and the drilling mast at a position distal to the drill floor for stabilizing an upper end of the base frame in relationship to the mast. A tensioning member may be connected between the base frame and the drilling floor for stabilizing the base frame in relationship to the substructure.
A lateral extend mechanism is pivotally connectable to the base frame. The lateral extend mechanism is extendable between a retracted position and a deployed position. A rotate mechanism is interconnected to the lateral extend mechanism and is rotatable in each of the left and right directions. A finger extend mechanism is connected to the rotate mechanism. The finger extend mechanism is laterally extendable between a retracted position and a deployed position.
A vertical grip and stab mechanism is attached to the finger extend mechanism. The grip and stab mechanism has grippers to hold a tubular or stand of pipe and is capable of moving the pipe vertically to facilitate stabbing. The lateral extend mechanism is deployable to move the rotating finger extend mechanism and grip and stab mechanism between a position beneath a racking board cantilevered from the mast and a position substantially beneath the mast.
In another embodiment, movement of the lateral extend mechanism between the retracted position and the deployed position moves the rotate mechanism along a substantially linear path. In a more preferred embodiment, movement of the lateral extend mechanism between the retracted position and the deployed position moves the rotate mechanism along a substantially horizontal path.
The rotate mechanism is rotatable in each of a left and right direction. In a more preferred embodiment, the rotate mechanism is rotatable in each of a left and right direction by at least ninety degrees. In another preferred embodiment, the pipe stand gripping mechanism is vertically translatable to vertically raise and lower the load of a stand of pipe.
In another embodiment, the automatic pipe racking system is series nesting. In this embodiment, the finger extend mechanism and grip and stab mechanism are substantially retractable into the rotate mechanism, which is substantially retractable into the pivot frame of the lateral extend mechanism, which is substantially retractable into the base frame.
As will be understood by one of ordinary skill in the art, the sequence of the steps disclosed may be modified and the same advantageous result obtained. For example, the wings may be deployed before connecting the lower mast section to the drill floor (or drill floor framework).
The objects and features of the invention will become more readily understood from the following detailed description and appended claims when read in conjunction with the accompanying drawings in which like numerals represent like elements.
The drawings constitute a part of this specification and include exemplary embodiments to the invention, which may be embodied in various forms. It is to be understood that in some instances various aspects of the invention may be shown exaggerated or enlarged to facilitate an understanding of the invention.
The following description is presented to enable any person skilled in the art to make and use the invention, and is provided in the context of a particular application and its requirements. Various modifications to the disclosed embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the present invention. Thus, the present invention is not intended to be limited to the embodiments shown, but is to be accorded the widest scope consistent with the principles and features disclosed herein.
In one embodiment, base frame 200 comprises a pair of deployable wings 208 (not shown), pivotally attached to base frame 200. When wings 208 are deployed outward, deployed ends of wings 208 are connected to base frame 200 by struts 210 (not shown). In this embodiment, mast braces 204 are connected to the deployed ends of wings 208, increasing the spacing between mast braces 204 to facilitate conflict free operation of racking mechanism 100. Retraction of wings 208 provides a narrower transport profile for transporting racking mechanism 100 between drilling sites.
As seen in
A lateral extend mechanism 300 is pivotally connected to base frame 200. Lateral extend mechanism 300 is extendable between a retracted position substantially within base frame 200, and a deployed position which extends in the direction of well centerline 70. In
Lateral extend mechanism 300 includes a pivot frame 400. A rotate mechanism 500 is connected to pivot frame 400. A finger extend mechanism 700 (not visible) is connected to rotate mechanism 500. A grip and stab mechanism 800 is connected to rotate mechanism 500.
In a preferred embodiment (best seen in
In another embodiment, racking mechanism 100 is further balanced such that upon failure of the power supply and/or hydraulic pressure, lateral extend mechanism 300 will be slightly more inclined to retract under gravitational force than to extend.
In another preferred embodiment, a tensioning member 206 connects each side of base frame 200 to drill floor 14 (not shown) of drilling rig 10 (not shown). Tensioning members 206 stabilize base frame 200 of racking mechanism 100. In a preferred embodiment, tensioning members 206 are adjustable to compensate for verticality of racking mechanism 100, and for the variable deflection of racking mechanism 100 when handling different sizes of drill pipe 50.
In the preferred embodiment illustrated, lateral extend mechanism 300 comprises an extend linkage 320 and level linkage 350. In a more preferred configuration, lateral extend mechanism 300 comprises an eight bar linkage as illustrated.
In the preferred embodiment illustrated, extend linkage 320 is comprised of an upper link 322, a lower link 324, and a long link 326. Also in this embodiment, level linkage 350 is comprised of an inboard link 352, an outboard link 354, and a coupler link 356.
Extend linkage 320 and level linkage 350 are pivotally connected to base frame 200 (not shown) on base connect side 304 via pin connections located at the ends of the extend linkage 320 and level linkage 350. Extend linkage 320 and level linkage 350 are pivotally connected to pivot frame 400 on mast side 302. Extend linkage 320 is pivotally connected to pivot frame 400 at connection 420. Level linkage 350 is pivotally connected to pivot frame 400 at connection 450. Extend linkage 320 and level linkage 350 are also pivotally connected to each other by coupler link 356.
A lateral extend cylinder 390 is pivotally connected between base frame 200 (not shown) and extend linkage 320. Controllable expansion of lateral extend cylinder 390 moves lateral extend mechanism 300 and thus pivot frame 400 between a retracted position substantially internal to base frame 200 (not shown) and an extended position external to base frame 200. In a preferred embodiment, inboard link 352 and upper link 322 are substantially the same length. The novel kinematic configuration of extend linkage 320 and level linkage 350 generates extension of pivot frame 400 along a stable and substantially horizontal path above drill floor 14 (not shown) when lateral extend mechanism 300 is deployed.
The lateral extend mechanism 300 is useful for other drilling rig applications in which it is desirable to horizontally translate another apparatus in a self-balancing manner in which maintaining the vertical alignment of the apparatus is desired. Such applications include positioning a gripping or torque device.
As seen in
In one embodiment as shown, at the top of pivot frame 400 is a right lock socket 412, right drive link socket 414, and a right cylinder socket 416 which are located near the top of pivot frame 400. A left lock socket 422, left drive link socket 424, and a left cylinder socket 426 are also located near the top of pivot frame 400.
A right lock socket 452, right drive link socket 454, and a right cylinder socket 456 are located near the bottom of pivot frame 400, and in respective axial alignment with right lock socket 412, right drive link socket 414, and right cylinder socket 416 at the top of pivot frame 400.
A left lock socket 462, left drive link socket 464, and a left cylinder socket 466 are located near the bottom of pivot frame 400, and in respective axial alignment with left lock socket 422, left drive link socket 424, and left cylinder socket 426 at the top of pivot frame 400.
In one embodiment illustrated in
As best seen in
As also seen in
A substantially matching configuration to the linkage and sockets of top rotate mechanism 510 is provided for bottom rotate mechanism 560. In this manner, top rotate mechanism 510 and bottom rotate mechanism 560 work in parallel relation to turn rotate frame 600 of rotate mechanism 500 in the desired direction.
To provide selectable rotation direction, or non-rotated direction, rotate mechanism 500 is connected to pivot frame 400, in part, by selectable rotate lock pins 530 and 540. Rotate frame 600 is clockwise rotatable about a first vertical axis centered on right lock socket 452 of pivot frame 400. Rotate frame 600 is counterclockwise rotatable about a second vertical axis centered on left lock socket 462 of pivot frame 400.
As illustrated in
Similarly, left rotation of rotate mechanism 500 is caused by actuation of left rotate lock pin 540 into left lock socket 422 (not shown) of pivot frame 400. Subsequent expansion of left cylinder 516 forces left driver 542 to push left coupler 544, which pushes out one end of rotate frame 600. Since the other end of rotate frame 600 is pivotally attached to pivot frame 400 by left rotate lock pin 540 in left lock socket 462, rotate frame 600 rotates to the left.
Rotate frame 600 can be locked into non-rotated position by actuation of right rotate lock pin 530 into right lock socket 412 of pivot frame 400, and actuation of left rotate lock pin 540 into left lock socket 422 of pivot frame 400.
As previously stated, the same kinematic relationships are engaged in top rotate mechanism 510 and bottom rotate mechanism 560 so that they may work in parallel relation to turn rotate frame 600 in the desired direction.
In the preferred embodiment, finger extend mechanism 700 is collapsible within rotate frame 600 such that rotate frame 600, finger extend mechanism 700 and vertical grip and stab mechanism 800 are collectively 180 degrees rotatable within a 48 inch distance.
Finger extend mechanism 700 includes an upper finger extend frame 702 pivotally connected on its upper end to rotate frame 600 and pivotally connected on its lower end to a vertical stab frame 802 of vertical grip and stab mechanism 800. Finger extend mechanism 700 includes a lower finger extend frame 704 pivotally connected on its upper end to rotate frame 600 and pivotally connected on its lower end to vertical stab frame 802. A finger extend cylinder 710 is pivotally connected on a first end to vertical stab frame 802, and connected on a second end to rotate mechanism 500. Extension of finger extend cylinder 710 causes extension of finger extend mechanism 700 and movement of vertical grip and stab mechanism 800 away from rotate frame 500 to position pipe 50 in the desired position.
As stated, vertical grip and stab mechanism 800 has a vertical stab frame 802. Vertical stab frame 802 has a lower end and an opposite upper end. A stab cylinder 804 is located on vertical stab frame 802.
A lower load gripper 820 is mounted in vertically translatable relation to vertical stab frame 802. A spacer 806 is attached above lower load gripper 820. An upper load gripper 830 is mounted above spacer 806, in vertically translatable relation to vertical stab frame 802. Load grippers 820 and 830 are capable of clamping onto the exterior of a drilling tubular and supporting the load of the tubular. Extension of stab cylinder 804 moves lower load gripper 820, spacer 806, and upper load gripper 830 vertically upwards in relation to vertical stab frame 802.
A spring assembly 808 is located between stab cylinder 804 and centering gripper 840. Spring assembly 808 is preloaded with the weight of the lower load gripper 820 and upper load gripper 830. The spring is further loaded when lower load gripper 820 and upper load gripper 830 are used to grip pipe 50, and stab cylinder 804 is extended. This reduces the power required for extending stab cylinder 804 to raise pipe 50. In one embodiment, spring assembly 808 is designed to achieve maximum compression under a weight of approximately 2,000 pounds, which is approximately the weight of a standard drill string.
Preloading spring assembly 808 allows for a gradual load transfer of the vertical forces from stab cylinder 804 to the target support of pipe 50, being either a receiving toll joint of drill pipe stump 52 located in wellbore 12, or on drill floor 14 for setting back the stand of drill pipe 50.
A centering gripper 840 is located on the lower end of vertical stab frame 802. Centering gripper 840 stabilizes pipe 50, while allowing it to translate vertically through its centering grip.
In an alternative embodiment (not illustrated), a gripper assembly is mounted in vertically translatable relation to vertical stab frame 802. At least one load gripper 830 is mounted on the gripper assembly. In this embodiment, extension of stab cylinder 804 moves the gripper assembly, including load gripper 830, vertically upwards in relation to vertical stab frame 802.
In
As described, the relationship of these elements has been shown to be extremely advantageous in providing an automatic pipe racking device 100 that can be mounted to a conventional drill floor, and that is capable of lifting and moving drill pipe between a racked position within a largely conventional racking board and a stabbed position over a wellbore.
Having thus described the present invention by reference to certain of its preferred embodiments, it is noted that the embodiments disclosed are illustrative rather than limiting in nature and that a wide range of variations, modifications, changes, and substitutions are contemplated in the foregoing disclosure and, in some instances, some features of the present invention may be employed without a corresponding use of the other features. Many such variations and modifications may be considered desirable by those skilled in the art based upon a review of the foregoing description of preferred embodiments. Accordingly, it is appropriate that the appended claims be construed broadly and in a manner consistent with the scope of the invention.
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