1. Technical Field
The present disclosure relates generally to a tool for making or breaking a threaded connection between adjacent drilling components, such as drill rods.
2. Related Technology
Drilling rigs are often used for drilling holes into various substrates. Such drill rigs often include a drill head mounted to a generally vertically oriented mast. The rig can include mechanisms and devices that are capable of moving the drill head along at least a portion of the mast. The drill head may include mechanisms that receive and engage the upper end of a drilling rod or pipe. Conventional drilling processes include the utilization of specialized lengths of pipe with threaded ends, commonly referred to as drill rods. These drill rods are screwed together at the ends to form a continuous length of pipe, sometimes referred to as a rod string or drill string. The end of the rod string coupled to the drill head may be referred to as the head end or box end. The drill string may further include a cutting bit or other device on the end opposite the head end, referred to as the bit end or pin end of the drill string. The drill string may include multiple rods each having a length that is shorter than the usable length of the mast. Screwing two lengths of drill pipe together is commonly referred to as making the joint, while unscrewing two rods is commonly referred to as breaking the joint.
The drill head may apply a force to the drilling rod or pipe which in turn is transmitted to the drill string. If the applied force is a rotational force, the drill head may thereby cause the drill string to rotate within the bore hole. The rotation of the drill string may include the corresponding rotation of the cutting bit, which in turn may result in a cutting action. The forces applied by the drill head may also include an axial force, which may be transmitted along the drill string to facilitate penetration into the substrate.
In a conventional drill string, the head end of a drill rod is coupled to the drill head and the bit end of the drill rod is coupled to the head end of the next drill rod in the drill string and so on. During the drilling process, the drill head is typically advanced from an upper position on the mast until the drill head approaches the lower end of the mast. Once the drill head has reached the lower end, a clamp or other device is used to maintain the drill string in position relative to the mast. A breakout tool may then be used to break the joint between the drill string and the drill head. The drill head may then be disconnected from the drill string via counter-rotation of the drill head. The drill head is then raised to the upper end of the mast in preparation to receive another drilling pipe. A new length of drilling pipe is then positioned along the centerline of the mast and the drill head is rotatingly coupled to the new drilling pipe to a manufacturer-specified torque. The drill head may then be lowered such that the bit (male) end of the drill pipe may be engaged into the head (female) end of the drill string and the new drill pipe is rotated into the top of the exposed drill pipe in order to accurately make the joint. The new joint may be rotated until a manufacturer-specified torque is achieved. A breakout tool may also be used in the process of making the new joint. This process is continually repeated as the drilling of the borehole continues until the desired depth is reached. Following the achievement of the desired depth, or if the bit wears out and needs to be replaced, the lengths of drill pipe must be withdrawn from the bore hole.
In order to remove the lengths of drill pipe, a clamp is applied below the joint between the drill string and the drill head with the drill head being located at the lower end of the drill rig mast. Once again, a break out tool may be applied to break the joint between the drill head and the drill string. Once the drill head is disconnected from the drill string, a hoisting device may be used to raise the drill string until a full length of drill rod is exposed out of the bore hole. The drill string is then clamped below an exposed lower joint to be broken. The exposed lower joint may be broken and the drill rod removed via the hoisting device or other particular rod handling means on the drilling rig.
Many tools have traditionally been used for making and breaking threaded drill rod joints as discussed above. Conventional methods include the use of hand tools, such as wrenches, or modified hand tools attached to hydraulic cylinders. One additional conventional method includes the use of a rod spinner. A rod spinner is a device usually fixed to the mast of a drill rig and through the center of which passes the rod string. The rod spinner may include a motor and corresponding mechanism for gripping and rotating the outer surface of a drill rod in order to make and break joints. Accordingly, a rod spinner may grip and rotate the drill rod located above a joint, while a lower drill rod or drill string located below the joint is clamped to the mast using a foot clamp or other similar clamping device.
Conventional rod spinners often are unable to selectively engage a rod string when needed and retract when not in use. This results from the fact that the drill string typically passes through the center of conventional rod spinners thereby requiring that a drill string joint be broken prior to engaging or retracting the rod spinner. Conventional rod spinners normally stay in place while the rod string is being removed from or replaced back into the drill hole. As such, the rod string is pulled or fed through the center of the rod spinner until all the required lengths of rods were removed from the hole, which may inconvenience and hinder the drilling process and limit the use of rod spinners. Disadvantages also exist in relation to conventional mechanisms used in rod spinners for gripping and rotating drill rods to make and break joints.
The subject matter claimed herein is not limited to embodiments that solve any disadvantages or that operate only in environments such as those described above. Rather, this background is only provided to illustrate one example technology area where some embodiments described herein may be practiced.
The present disclosure relates to open-faced rod-spinning devices, systems, and methods configured for making and breaking connections between threaded drill rods. In particular, the open-faced rod-spinning devices may allow for the selective engagement and disengagement of a drill string when desired to make or break a drill rod joint. For example, the open face of the rod-spinning device allows it to be stored in a disengaged position and then selectively brought forward to engage a drill string when necessary to make or break a joint and then conveniently retracted away when not in use. Because the rod-spinning device may not engage the drill string throughout the drilling process, the durability and maintenance of the rod-spinning device may be improved. In addition, the process of making and breaking joints, as well as the process adding drill rods to or removing drill rods from a drill string, may be quicker, easier, and more efficient.
In one example embodiment, an open-faced rod-spinning device may include a drive gear including an open face for receiving and rotating about a drill rod. In addition, the rod-spinning device may include a plurality of drive pins coupled to the drive gear. The rod-spinning device may also include an open-faced carriage assembly including a plurality of gripping lobes configured to be engaged by the drive pins.
In a further embodiment, an example drill mast may include a support structure. An open-faced rod-spinning device may be coupled to the support structure. The open-faced rod-spinning device may be configured for making and breaking connections between threaded drill rods. In particular, the open-faced rod-spinning device may include a casing having an open face for receiving a drill rod. The casing may also contain a gear system and a carriage assembly. For example, the gear system may include a drive gear having an open face for receiving and rotating about a drill rod. In addition, the gear system may further include a plurality of drive pins configured to engage and rotate the carriage assembly. In turn, the carriage assembly may include a plurality of gripping lobes configured to grip and rotate a drill rod when engaged by the drive pins. Finally, a clamping device may be coupled to the support structure and configured to selectively clamp a drill string.
In a yet further embodiment, an example drill rig in accordance with the present disclosure may include a base structure coupled to a mast. An open-faced rod-spinning device configured for making and breaking connections between threaded drill rods may be coupled to the base structure or mast. In particular, the open-faced rod-spinning device may include a gear system and a carriage assembly. In one embodiment, the gear system may include a drive gear having an open face for receiving and rotating about a drill rod and a plurality of drive pins coupled to the drive gear and configured to engage and rotate the carriage assembly. The carriage assembly may include an open face for receiving and rotating about a drill rod and may further include a plurality of gripping lobes configured to grip and rotate a drill rod when engaged by the drive pins.
These and other embodiments of the present disclosure will become more fully apparent from the following description and appended claims, or may be learned by the practice of the disclosure as set forth hereinafter.
To further clarify the above and other embodiments of the present disclosure, a more particular description will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is appreciated that these drawings depict only typical examples and are therefore not to be considered limiting of the disclosure's scope. Examples will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
The present disclosure includes systems, methods, and apparatuses configured for making and/or breaking joints between drill rods. In particular, the present disclosure includes an open-faced drill rod-spinning device as well as corresponding systems and methods. The open-faced rod-spinning devices may allow for the selective engagement and disengagement of a drill string when desired to make or break a drill string joint. For example, the open face of the rod-spinning device allows it to be stored in a disengaged position and then selectively brought forward to engage the drill string when necessary and then retracted when not needed. In addition, the process of making and breaking joints, as well as the process adding drill rods to or removing drill rods from a drill string, may be quicker, easier, safer, and more efficient.
Reference is now made to the Figures which illustrate various example embodiments of the present disclosure. For example,
As illustrated, the drill mast 110 is in a substantially horizontal position. However, once the drill rig 100 is positioned to begin the drilling process, the drill rig 1100 may raise the drill mast 110 to any desired angle for the bore hole to be drilled. In one example embodiment, the angles at which the drill mast 110 may be positioned may include a range from about directly vertical or 0° to about a 45° angle. A rod-spinning device 200 may be coupled directly to the drill mast 110, may be coupled directly to the base structure 105 of the drill rig 100, or may be coupled to a rod-handling device associated with the drill rig 100 or drill mast 110. In a further embodiment, the rod-spinning device 200 may be used during the drilling process to selectively engage and disengage a drill string in order to make and/or break drill rod joints.
Reference is now made to
In one embodiment, the support structure 115 of the drill mast 110 may be configured to extend and retract between a first length and a second length greater than the first length. For example, the support structure 115 may be configured to move to a lower first length to facilitate transportation of the drill mast 110 and then move to a second length when in position to drill in order to extend the usable length of the drill mast 110, thereby increasing the capability of handling longer drill rods during the drilling process. In one embodiment, the second length may be equal to or greater than twice the first length.
As mentioned, in one embodiment, the support structure 115 may be coupled with and support a drill head 120. In particular, the support structure 115 may support the drill head 120 as the drill head 120 translates between an upper end 115a and a lower end 115b of the support structure 115.
In a further embodiment, the drill head 120 may be operatively associated with a drill string including any number of drill rods. The drill head 120 may include mating features configured to engage corresponding mating features in the head or upper end of a drill rod. In at least one example embodiment, the drill head 120 may include male features, such as external threads while a head or box end of the drill rod may include female features, such as internal threads configured to couple with the external threads of the drill head 120. Accordingly, in at least one example, a box end of a drill rod may be rotated into engagement with the drill head 120. A bit or pin end of the drill rod may include male features, such as external threads, such that multiple drill rods may be coupled together to form a drill string.
A drill bit may be operatively associated with a lower or pin end of the drill string. In one example embodiment, the drill head 120 applies forces to the drill string, which are at least partially transmitted to the drill bit to cause the drill bit and drill string to advance through a substrate. The forces applied to the drill string may include, without limitation, rotary, axial, percussive, and/or vibratory forces as well as any combination of forces. For ease of reference, the following examples will be discussed in the context of a drill head that is configured to apply rotary and axial forces to the drill string and thence the drill bit. For case of reference, the rotary forces may be described herein as rotation in a clock-wise or first direction.
In one embodiment, the drill mast 110 and/or drill head 120 may also include machinery and/or devices for translating the drill head 120 relative to the support structure 115 from the upper end 115a to a lower end 115b of the support structure 115 and vice versa. For example, in one embodiment, the drill mast 110 or drill head 120 may include a chain drive, belt drive, or screw drive for translating the drill head 120 along the support structure 115. As a result, the drill head 120 may advance as the drill bit and drill string penetrate the substrate.
As introduced above,
As discussed above, the drill mast 110 may include a clamping device 130, such as a foot clamp, operatively associated with the support structure 115. During normal drilling operations, both the clamping device 130 and the rod-spinning device 200 may be disengaged from the drill string. During a drilling operation where the drill head 120 has reached the lower end 115b of the support structure 115, the drill string may be clampingly retained to the lower end 115b of the support structure 115 by the clamping device 130 and the drill head 120 may be reversed to break the joint between the drill head 120 and the clamped drill string. For example, the clamping device 130 may apply sufficient force to minimize rotation of the drill string as the drill head 120 is rotated in a counter-clockwise or second direction, the second direction being opposite the first direction.
The drill head 120 may be raised to the upper end 115a of the support structure 115 and a new length of drill pipe may be loaded into the drill mast 110. The drill head 120 may then be lowered into proximity with the box end of the new length of drill pipe and rotated to engage the drill pipe. The drill head 120 may then lower slowly until the pin end of the new length of drill pipe engages the box end of the drill string being clamped by the clamping device 130. During this process, the rod-spinning device 200 may be brought forward to engage and rotate the new length of drill pipe in order to make the joints between the new length of drill pipe and the drill string and/or between the new length of drill pipe and the drill head 120. In a further embodiment, the rod-spinning device 200 may apply a specified torque to the new length of drill pipe to achieve a specified torque in the joints with the drill head and/or drill string.
In one implementation, the rod-spinning device 200 may be horizontally extended on a plane perpendicular to the support structure 115 to engage the new length of drill pipe in a position which is just above the joint to be made between the new drill pipe and the drill string. After the joint is made, the rod-spinning device 200 may be retracted to a disengaged position.
In a further embodiment, the rod-spinning device 200 may be rotated from a vertical, disengaged position to a horizontal, engaged position. Once a joint is made or broken as desired, the rod-spinning device 200 may then rotate from the horizontal, engaged position to a vertical, disengaged position. In a yet further embodiment, the rod-spinning device 200 may be independent of the drill mast 110 and may be configured to be rolled, moved, and/or rotated into place to engage a drill rod and rolled or moved away to disengage the drill rod.
Reference is now made to
As further illustrated in
Once the rod-spinning device 200 is in the parked position, the rod-spinning device 200 may be brought forward to a working position, wherein the rod-spinning device 200 receives and engages a drill rod. Once in the working position, the motor 204 may selectively operate the drive gear 226 and carriage assembly 210 to engage and rotate the drill rod in a clockwise or counter-clockwise direction.
With continuing reference to
In one example embodiment, the motor (i.e., 204,
The drive gear 226 may include or be coupled to drive pins 228 configured to engage and rotate the carriage assembly (i.e., 210,
Torque generated by the rod-spinning device 200 may be a function of the torque output of the motor 204 and the gear reduction between the pinion gear 222 and the drive gear 226. In one implementation, the amount of torque applied by the rod-spinning device 200 to a drill rod may be controlled by adjusting the torque output of the motor 204. Accordingly, a specified desired torque may be achieved in making drill rod joints.
Reference is now made to
In one embodiment, the drive gear 226 may include a recess 227 or cavity configured for receiving the bottom plate 214 of the carriage assembly 210. The carriage assembly 210 may also be configured to rotate within the recess 227 and relative to the drive gear 226. Accordingly, as the drive gear 226 rotates relative to the carriage assembly 210, the drive pins 228 may engage the gripping lobes 218 and rotate the gripping lobes 218 about the pivot pins 216. Rotation of the gripping lobes 218 may move the gripping surface 219 and/or gripping elements 219a inward toward a drill rod. Once the gripping lobes 218 have engaged the outside diameter of the drill rod, the drive gear 226, carriage assembly 210, and engaged drill rod may rotate together.
A carriage assembly bearing 230 may also be included and placed in the recess 227 between the drive gear 226 and the bottom plate 214 of the carriage assembly 210. In one implementation, the carriage assembly bearing 230 may be configured to facilitate the rotation of the carriage assembly 210. The carriage assembly bearing 230 may be manufactured using any material that will allow the bottom plate 214 of the carriage assembly 210 to rotate within the recess 227 relative to the drive gear 226. In one implementation, the carriage assembly bearing 230 is manufactured using a polymer, such as polyethylene. In a further embodiment, the rod-spinning device 200 may include a friction element (i.e., 232,
As shown in
The waist 218c and flared tail end 218b may be configured to be engaged by the drive pins 228 to rotate the gripping lobes 218 about the pivot pins 216. In particular, the waist 218c and flared tail end 218b may define one or more indentations 218d along the sides of the gripping lobe 218 configured for receiving a drive pin 228. Accordingly, a drive pin 228 may engage the gripping lobe 218 to rotate the gripping lobe 218 about the pivot pin 216 into engagement with a drill rod. In turn, the entire carriage assembly 210 rotates once the gripping lobes 218 engage the outside surface of a drill rod, thereby resisting any further rotation by the gripping lobes 218 about the pivot pins 216.
In one embodiment, the indentations 218d may be located on each side of the gripping lobe 218 in order to receive drive pins 228 from either side. As a result, drive pins 228 may engage and rotate the gripping lobe 218 in either a clockwise or counter-clockwise direction. In one implementation, the indentations 218d may be either curved and/or angular shape.
As is further illustrated, each of the gripping lobes 218 may be symmetrically shaped about a centered, vertical plane extending through the centers of each of the tail end 218b and head end 218a. This symmetric configuration may allow the gripping lobes 218 to operate similarly whether engaged by a drive pin 228 rotating in a clockwise or counter-clockwise direction. Accordingly, the gripping lobes 218 may engage and rotate a drill rod in different rotational directions to selectively make and/or break drill rod joints.
Reference is now made to
Reference is now made to
As is further illustrated by
For example, as illustrated in
As a result and referring again to
Reference is now made to
Reference is now made to
In one embodiment, the carriage assembly 210′ may have a flared open face 208′ have a flared opening to facilitate engagement of a drill rod. In particular, the top plate 212′ and bottom plate 214′ may each include an open face with flared edges 212a′, 214a′. For example, the flared edges 212a′, 214a′ may provide a wider dimension near the mouths of the openings in order to more easily receive a drill rod into the carriage assembly 210′. In one embodiment, the flared edges 212a′, 214a′ may facilitate engaging a drill rod into a rod-spinning device (i.e., 200,
In a further embodiment, the top plate 212′ of the carriage assembly may include one or more gaps 213′ for receiving a mounting plate (i.e., 240,
Reference is now made to
In one embodiment, the rod-spinning device 200″ may include a collar 280″ coupled to the casing 202″. As illustrated, the open face 208″ of the rod-spinning device 200″ may extend to the collar 280″ to facilitate engaging and/or releasing a drill rod. In one embodiment, the collar 280″ may couple to the casing cover 203″ on top of the rod-spinning device 200″. In a further embodiment, the collar 280″ may couple to any location of the rod-spinning device 200″. In a yet further embodiment, a plurality of collars 280″ may be used. For example, in one embodiment, one collar 280″ may be positioned on top of the rod-spinning device 200″ and one collar 280″ may be positioned on bottom of the rod-spinning device 200″.
Reference is now made to
In one embodiment, the rod-spinning device 400 may include a casing 402 and casing cover 403 that at least partially enclose one or more components of the rod-spinning device 400. In particular, the casing 402 and casing cover 403 may at least partially enclose one or more gear bearings 450 that facilitate the rotation of one or more pinion gears 422, idler gears 424, and/or drive gears 426. The drive gear 426 may be coupled to one or more drive pins 428. For example, the drive pins 428 may be disposed within one or more recesses within the drive gear 426. The drive pins 428 may also be configured to drive one or more gripping lobes 418 of a carriage assembly 410.
The carriage assembly 410 may include a top plate 412 and bottom plate 414 with the one or more gripping lobes 418 disposed therebetween. The carriage assembly 410 may further include one or more pivot pins connecting the top plate 412 to the bottom plate 414 and about which the one or more gripping lobes 418 may rotate. The carriage assembly 410 may be configured to rotate relative to the drive gear 426. In particular, the carriage assembly 410 may be disposed within a recess 427 in the drive gear 426 configured to allow rotation of the carriage assembly 410 relative to the drive gear 426. In addition, a carriage assembly bearing 430 may be positioned within the recess 427 between the carriage assembly 410 and drive gear 426 to facilitate the relative rotation of the carriage assembly 410.
The rod-spinning device 400 may further include a braking mechanism 490. In particular, the braking mechanism 490 may include a braking disc 491 and one or more braking calipers 492 operatively associated with the braking disc 491. The braking disc 491 may be coupled to the top plate 412 of the carriage assembly 410. The braking calipers 492 may be fixed in place, and the braking disc 491 may be configured to rotate and/or otherwise move relative to the braking calipers 492. For example, the braking calipers 492 may be connected to the casing 402 or casing cover 403 and the braking disc 491 may be connected to and rotate with the top plate 412 of the carriage assembly 410. Accordingly, an operator may activate the braking calipers 492 in order to prevent rotation of the braking disc 491 and carriage assembly 410 when it is desired to prevent the carriage assembly 410 from rotating. In a further embodiment, the operator may selectively engage and disengage the braking calipers 492 in order to selectively hold and release the braking disc 491 and carriage assembly 410.
With continued reference to
As shown, the braking mechanism 490 may be coupled to the carriage assembly 410. In particular, the braking disc 491 may be connected to the top plate 412 of the carriage assembly 410. In turn, the braking calipers 492 may be connected to a casing 402 or casing cover 403 or other component. The braking disc 491 may be disposed at least partially within the braking calipers 492, such that activation of the braking calipers 492 applies a pressure and/or frictional force on the braking disc 491 to prevent or resist movement by the braking disc 491 and carriage assembly 410 relative to the braking calipers 492. Accordingly, activating the braking calipers 492 may at least partially prevent the braking disc 491 and carriage assembly 410 from rotating.
The braking calipers 492 and braking disc 491 may include any number of materials. For example, the braking calipers 492 and braking disc may include metals, composites, plastics, other similar materials, and/or combinations of the same. In addition, the braking calipers may be configured to be activated with any of a number of different instrumentalities. For example, the operator may active the braking calipers 492 using pneumatics, hydraulics, electricity, magnetic forces, mechanical forces, other similar instrumentalities, and/or combinations of the same.
A manufacturer may connect the braking disc 491 to the carriage assembly 410 using any number of fastening techniques. For example, the manufacture may connect the braking disc 491 to the carriage assembly using bolts, welds, adhesives, other fasteners, and/or combinations of the same. In a further embodiment, the braking disc 491 may be an integral part of the top plate 412 of the carriage assembly 410.
A manufacturer may also configure the rod-spinning device 400 to resist relative motion between the carriage assembly 410 and drive gear 426. For example, in one implementation, one or more drive pins 428 may include a detent mechanism configured to resist movement between the carriage assembly 410 and drive gear 426. In particular, the detent mechanism may include a detent member that is configured to extend upwards from the top of a drive pin 428 and move longitudinally, back and forth relative to the drive pin 428. The detent member may also extend towards the bottom surface of the top plate 412 of the carriage assembly 410. The top plate 412 may further include one or more corresponding indentations or holes configured to at least partially receive the detent member. The detent mechanism may be further configured to apply an upward force to the detent member so as to push the detent member into an indentation in the top plate 412 and resist relative movement between the drive pin 428 and top plate 412 of the carriage assembly 410.
With continued reference to
In one implementation, the drive pin 428 may include a detent mechanism 495. The detent mechanism may include a detent member 496 movable relative to the drive pin 428 and extending upward from the pin portion 428a. The shape, size, and configuration of the detent member 496 may be configured to be received by a corresponding indentation or hole in the top plate 412 of the carriage assembly 410. For example, the detent member 496 may have one end that is rounded in shape. In further implementations, the detent member 496 may have any shape, size, and/or configuration desired for a particular application.
The detent mechanism 495 may be further configured to provide an upward force on the detent member 496 in order to move the detent member 496 in a longitudinal direction into an indentation of the top plate 412 to resist movement between the drive pin 428 and top plate 412, and thereby resist movement between the drive gear 426 and carriage assembly 410. For example, the detent mechanism 495 may include a spring 497 that applies a constant force to the detent member 496. In a further implementation, the drive pins 428 and/or indentations in the top plate 412 may be positioned such that the indentations receive the detent members 496 when the openings of the drive gear 426 and carriage assembly 410 are in alignment.
In further embodiments, the detent mechanism 495 may be configured to apply selective forces to the detent member 496. For example, the detent mechanism 495 may be configured to apply selective hydraulic, mechanical, pneumatic, magnetic, electrical, and/or other forces to the detent member 496. As a result, an operator may selectively activate the force on the detent member 496 when she desires to resist movement between the drive gear 426 and the carriage assembly 410 and deactivate the force on the detent member 496 when she desires to allow relative movement between the drive gear 426 and carriage assembly 410. In a yet further implementation, the detent mechanism 495 may be configured to retract the detent member 496 when relative movement between the drive gear 426 and carriage assembly 410 is desired.
Any number of the drive pins 428 may include a detent mechanism 495. For example, in one implementation, as many as all of the drive pins 428 and as few as one drive pin 428 may include a detent mechanism 495. In a further example, two drive pins 428 may each include a detent mechanism 495 while the remaining drive pins 428 do not.
As a result, and with continued reference to
The braking calipers 492 may apply pressure to the braking disc 491 in order to maintain the carriage assembly 410 stationary as the drive gear 426 begins to rotate. In so doing, the torque applied to the drive gear 426 in conjunction with the friction applied by the braking mechanism 490 may overcome the resistance to relative movement between the carriage assembly 410 and drive gear 426 created by the detent mechanisms 495 of the drive pins 428. The relative rotation of the drive gear 426 with respect to the carriage assembly 410 may cause the drive pins 428 to engage and rotate the gripping lobes 418 until they engage the drill rod. Once the gripping lobes 418 engage the drill rod, the braking calipers 492 may deactivate as the drive gear 426 continues to rotate in order to allow the drive gear 426, carriage assembly 410, and drill rod to rotate together to make or break a joint in a drill rod string.
Once the drill rod joint is either made or broken as desired, the braking calipers 492 may activate and apply pressure to the braking disc 491 to resist movement of the carriage assembly 410 and facilitate relative movement between the carriage assembly 410 and the drive gear 426. The operator may then reverse the motor 404 in order to reverse the direction of and rotate the drive gear 426 until the open face of the drive gear 426 aligns with the open face of the carriage assembly 410. As the drive gear 426 and carriage assembly 410 are aligned, the detent member 496 of the detent mechanism 495 may be received by the indentations in the top plate 412 of the carriage assembly 410 to thereby resist further relative movement between the drive gear 426 and the carriage assembly 410. Once the drive gear 426 and carriage assembly 410 are aligned, the braking calipers 492 may deactivate to release the braking disc 491 to allow the carriage assembly 410 to rotate with the drive gear 426. The operator may further reverse the motor 404 in order to align the openings of the carriage assembly 410 and drive gear 426 with the open face 408 of the casing 402 in order to release the drill rod.
In order to facilitate this process, the braking mechanism 490 may further include a timing device that selectively activates and deactivates the braking calipers 492. For example, in one implementation, the braking mechanism 490 may include a hydraulic timer that selectively activates and deactivates the braking calipers 492 when desired to resist movement of the braking disc 491 and carriage assembly 410. In particular, the hydraulic timer may apply hydraulic pressure to and relieve hydraulic pressure from the braking calipers 492 at appropriate times during the process of making and breaking drill rod joints in order to ensure the proper relative rotation between the drive gear 426 and carriage assembly 410. In a further implementation, the timing device, such as a hydraulic timer, may automatically activate and deactivate at appropriate times during the process of making and breaking drill rod joints.
In one example, the hydraulic timer may include a variable flow controller in series with an accumulator. An operator may adjust the flow controller to control the time it takes for the accumulator to fill with fluid. As the accumulator fills with fluid, pressure may increase in the accumulator. Once fluid pressure within the accumulator achieves a particular level, it may trigger a sequence valve, which then allows pressure to be applied to a pilot-operated check valve, which, when opened, releases pressure from and deactivates the braking calipers 492. An operator may adjust flow through the flow controller and the pressure of the sequence valve in order to achieve the desired timing of activation and deactivation of the braking calipers 492.
The rod-spinning device 400 may further include a switch that automatically deactivates or applies a brake to the motor 404 once the drive gear 426 and carriage assembly 410 are aligned with the open face 408 of the casing 402. For example, the rod-spinning device 400 may include a directional control valve coupled to the motor 404 to stop rotation of the motor 404 once the drive gear 426 and carriage assembly 410 are aligned with the open face 408 of the casing 402.
Reference is now made to
In one embodiment, the rod-spinning device 500 may include a gate 599 configured to at least partially close the open face 508 of the casing 502 and casing cover 503. In particular, the gate 599 may be configured to at least partially cover the open face 508 to protect the inner components of the rod-spinning device 500 and to prevent any unwanted objects from becoming caught in the rod-spinning device 500. The gate 599 may be coupled to a closing mechanism in order to selectively open and close the gate 599 as desired. For example, the gate 599 may be coupled to a hydraulic device configured to close and open the gate 599 as desired during the process of making or breaking a drill rod joint. Accordingly, the gate 599 may improve the integrity and safety of the rod-spinning device.
The present disclosure may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the disclosure is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
This application claims the benefit of and priority to U.S. Provisional Patent Application Ser. No. 61/052,577, filed May 12, 2008, entitled “OPEN-FACED ROD SPINNER,” the entire contents of which are incorporated herein by reference.
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