The present invention relates generally to a tool that may be used in connection with a horizontal directional drilling rig that advances a drill string, comprised of a plurality of drill pipes that are joined together in threaded engagement, through the ground to create a borehole, and to a method for using such a tool. More particularly, the invention comprises a tool that is used to perform various functions on or with respect to the drill pipe sections of the drill string on the exit side of the borehole.
Many utility lines, pipelines and other underground components are installed in or under the ground by boring a borehole in a generally-horizontal direction in the ground rather than by digging a trench. This type of construction, which is sometimes referred to as “horizontal boring”, “directional drilling” or “horizontal directional drilling”, eliminates the need to excavate earth in order to install an underground component, and thereby saves several steps in the installation process. If no trench is dug, there will be no trench to fill, and no disturbed surface to reclaim. A directional drilling machine may be operated to drill a borehole along a desired path underground. The planned path is generally arcuate in shape from the entry point at the surface of the ground to an exit point remote from the entry point at the surface. The path of the borehole may take the drill string under or around an obstacle such as a roadway, river or other existing utility.
A typical directional drilling machine includes a thrust frame that can be aligned at an oblique angle with respect to the ground. Mounted on a drive carriage on the thrust frame is a pipe-rotation mechanism that is adapted to rotate the drill string and boring tool connected to the downhole end of the drill string. The drive carriage also includes a carriage drive assembly that is adapted to push the carriage along the thrust frame. The combination of rotation of the drill string and longitudinal movement of the drive carriage along the thrust frame causes the drill string to be advanced into or withdrawn from the ground along the desired path.
To drill a hole using a directional drilling machine, the thrust frame is oriented at an angle relative to the ground, and the drive carriage is positioned at an upper end of the frame. A drill pipe section is coupled to the pipe-rotation mechanism on the drive carriage. A boring tool or cutting head is mounted to the terminal end of the pipe section, and the drive carriage is driven downward along the thrust frame. As the drive carriage is driven downward, the pipe-rotation mechanism rotates the pipe about the boring axis, thereby causing the pipe (with boring tool mounted thereon) to drill or bore a hole.
As the drilling operation proceeds, pipe sections are added to the uphole (entry-side) end of the drill string to lengthen the drill string. The pipe sections are provided with a male threaded connector on one end and a female threaded connector on the other end. Each time a pipe section is added to the drill string, the pipe section being added is aligned with the drill string and the threaded connector on its far end is mated with the threaded connector on the near end of the drill string. Either the pipe section being added or the drill string must be restrained against rotation while the other component is rotated to engage the threaded connector on the far end of the pipe section with the threaded connector on the near end of the drill string to create a secure threaded connection between the components.
Hydraulically actuated wrenches or vises are typically mounted on the directional drilling machine to tighten the threaded connections between drill pipes as pipe sections are added to lengthen the drill string. These wrenches typically comprise two pairs of opposed jaws, one for the male-threaded pipe and the other for the female-threaded pipe of the adjacent components of the drill string. Each pair of jaws is adapted to clamp around a pipe section, one on the far side and the other on the near side of the threaded connection. At least one pair of jaws of the wrench assembly will pivot with respect to the other pair of jaws to twist one of the pipe sections with respect to the other.
After the boring tool reaches a desired depth during the drilling operation, it can be directed along a generally horizontal path and back up to break the surface of the ground at the exit point. To control the direction of the boring tool, a boring tool with an angled-face may be used. When the direction of the boring tool must be changed, the boring tool is positioned with the angled-face oriented to cause the boring tool to deflect in the desired direction and the drill string is pushed forward without rotation. The capability to change the direction of travel of the boring tool allows the operator to steer the boring tool and drill string around underground obstacles.
When the pilot bore is complete, the boring tool may be removed from the end of the drill string, and the pipe sections disconnected from each other to disassemble the drill string on the exit side of the borehole. Additionally, the borehole may be enlarged using a backreamer in place of the boring tool. If a backreamer is used, it will be connected to the far end of the drill string in place of the boring tool and moved through the pilot bore back towards the directional drilling machine, either with or without rotation of the drill string. The backreamer expands and stabilizes the walls of the bore, generally while pulling a utility line or other underground component through the enlarged bore behind it.
Movement of the backreamer towards the drilling machine is accomplished by driving the drive carriage in a rearward direction on the thrust frame to withdraw a pipe section, disconnecting the withdrawn pipe section from the drill string, connecting the next pipe section remaining in the drill string to the pipe rotation mechanism on the drive carriage and repeating the process until all of the pipe sections have been withdrawn from the ground. As each pipe section in the drill string is uncoupled from the drill string using the same wrench assembly that is used to connect the drill pipes when boring is being carried out, the disconnected pipe sections are placed in a stack or loaded into a pipe section magazine of the directional drilling machine.
There are several operations that may be performed on the exit side of the borehole. For example, the boring tool may be disconnected from the end of the drill string and the pipe sections of the drill string may be disconnected one by one from the drill string. If a backreamer is used, it must be installed in place of the boring tool. High torque is typically required in order to loosen the boring tool or a pipe section for removal from the drill string or to install the backreamer on the drill string. Most commonly, the drill crew will use a pair of large wrenches such as pipe wrenches or oil field tongs to remove the boring tool and each pipe section, or to install a backreamer. Frequently, the drill crew will connect the handle of the wrench to the bucket of a hydraulic excavator using a chain or strap, and then use the excavator to apply a vertical force to the bucket while the drilling rig operator rotates the drill string to loosen the boring tool or a pipe section or to tighten the backreamer on the end of the drill string. If the drill string is to be disassembled on the exit side, the individual pipe sections must be placed in a stack or in a pipe section magazine. These pipe sections are heavy and long, and it is labor-intensive to disconnect them manually on the exit side of the drill site.
It would be desirable, therefore, if a tool could be provided that could perform various functions with respect to the drill string on the exit side of the borehole. It would also be desirable if a preferred embodiment of such a tool could be provided that could connect to the arm of a hydraulic machine such as a hydraulic excavator so as to employ the excavator's auxiliary hydraulic power circuit to operate the tool.
Some tools have recently become available for exit-side makeup and breakout. For example, see the tools described in U.S. Patent Publication No. 2014/0151124, issued to Randall, et. al., the entire contents of which are each incorporated herein by reference. The following disclosure provides improvements to the design and operation of such devices.
The invention is directed to an apparatus comprising an elongate frame, first and second vise assemblies, a retainer assembly and a positioning assembly. The frame has a frame axis. The vise assemblies are supported in side-by-side relationship on the frame. One vise assembly is configured to grip and rotate a pipe section, and the other vise assembly is configured to grip a pipe section without rotation. The retainer assembly is supported on the frame in spaced relationship to the vise assemblies and configured to grip a pipe section without rotation. The positioning assembly is configured to move the retainer assembly in a direction transverse to the frame axis.
In another embodiment, the invention is directed to an apparatus comprising an elongate frame, a first vise assembly, a second vise assembly, opposed first and second roller assemblies, a roller positioning assembly, and a retainer assembly. The elongate frame has a frame axis. The vise assemblies are disposed on the frame in side-by-side relationship for connecting and removing a pipe segment from a pipe string. The roller assemblies are supported on the frame and configured to rotate a pipe section without gripping. The roller positioning assembly causes relative movement between the opposed roller assemblies in a direction transverse to the frame axis. The retainer assembly is supported on the frame in spaced relationship to the vise assemblies and configured to grip a pipe section without rotation.
In another embodiment, the invention is directed to an apparatus comprising a first roller assembly, a second roller assembly, and a cylinder. The first and second roller assembly are opposed to one another and each comprise at least one roller. The cylinder is disposed between the first and second roller assemblies and configured to cause relative movement between the opposed roller assemblies. A spiral ramp is formed on the external surface of at least one roller.
Referring now to the drawings,
With reference now to
The tool 30 comprises an elongate frame 34. The frame 34 defines a frame axis 35 (
In
The frame 34 must generally be aligned parallel with the drill string 22 at the exit side 28 in order to be properly oriented. Therefore, it is provided with the attachment assembly 42 to orient the frame 34. The attachment assembly 42 comprises a base 46 and an attachment bracket 48. The attachment assembly 42 provides a pivotal connection such that the tool 30 may be properly oriented to the drill string 22 for makeup or breakout of pipe sections 80 to or from adjacent pipe sections 81.
The frame 34 is pivoted about a first axis 52 by a hydraulic cylinder 50 disposed between the base 46 and the frame. The attachment bracket 48 comprises an external gear 49. The frame 34 and base 46 rotate about a second axis 54 relative to the attachment bracket 48. As shown, two motorized gear drives 61 supported by the base 46 actuate this rotation. The drives 61 interact with geared connection 49. This interaction causes relative rotation between the base 46 and gear 49. A hydraulic swivel 51 may be provided within the assembly as shown in
Alternative means of rotation of the base 46, such as an internal gear drive, slewing drive, hydraulic cylinder or the like may be used. The gear 49 and gear drives 61 allows for full 360 rotation the tool 30 about the attachment bracket 48. The frame 34 is manipulated by hydraulic cylinder 50 and gear drives 61 such that it is substantially parallel with a section of pipe 80 to be removed.
With continued reference to
With reference to
Each actuator 88a-h causes its adjacent jaw 87 to extend or retract. When opposing pair of jaws 87 are moved to a gripping position, a pipe section 80 disposed within the vise 62, 64 is gripped. Each jaw is mounted so as to be moveable with respect to each other between an gripping position and a non-gripping position in which the jaws may grip a pipe section. Thus, the jaws 87 of the first vise assembly 62 will cooperate to grip a pipe section when in the gripping position.
Each jaw 87 supports one or more die holders 89. The die holders 89 aid in increasing the friction between the jaws 87 and the pipe section 80, preventing slippage during makeup and breakout. By providing two die holders 89 per jaw, the vise assemblies 62, 64 can accommodate various sizes of pipe by contacting the pipe section at four distinct points.
The first vise assembly 62 is fixed relative to the frame 34 and the second vise assembly 64 is rotating with respect to the first vise assembly in order to apply a twisting force to a pipe section with respect to an adjacent pipe section that is gripped by the first vise assembly. The tool 30 comprises a linear actuator 100 for moving the second vise assembly 64 relative to the first vise assembly 62. The linear actuator 100 may be a hydraulic cylinder. As shown, there is a linear actuator on each side of the second vise assembly 64, though a single actuator may be used. Extension and retraction of the linear actuator 100 when the first vise assembly 62 is in the closed position will rotate the pipe section 80 relative to an adjacent section 81 in the drill string 22 causing the pipe joint formed between these sections to loosen or tighten, depending on the direction of rotation (
With reference to
The second vise assembly 64 may alternatively be fixed and the first vise assembly 62 may be moveable with respect thereto. Rotation of the pipe section 80 away from the pipe string within the ground is advantageous, as it eliminates the need to overcome frictional force due to the subsurface. In another embodiment of the invention (not shown), each of the vise assemblies 62, 64 is independent respect to each other to apply a twisting force to the drill string 22 (
With reference now to
As shown, rollers 118 are incorporated into the legs 110, 104 and bracket frame 102 to enable rotation of the pipe sections without frictional resistance due to the retainer assemblies 66, 68 during makeup and breakout. As shown, the rollers 118 comprise bogey wheels. Alternatively, rollers 118 incorporated within the retainer assemblies 66, 68 may be powered (not shown).
The position cylinder 106 is configured to move the retainer assembly 66, 68 in a direction transverse to the longitudinal axis of the frame 34. Two rails 108 provide support for the bracket frame 102 while allowing the cylinder 106 to adjust the position of the frame. The cylinder 106 allows the pipe section 80 to be centered within the retainer assembly 68.
The first retainer assembly 66 may have identical components as the second retainer assembly 68. As shown, the second retainer assembly 68 is proximate the second end 40 of the frame and the first retainer assembly 66 is proximate the first end 38 of the frame
With reference again to
The roller assembly 70 comprises first roller arm 130 comprising a first roller 130 and second roller arm 132 comprising a second roller 136. First roller arm 130 and second roller arm 132 are suspended from one or more rails 133. The rails extend transverse to the frame 34. The rails 133 allow the arms 130, 132 to move laterally with respect to the frame 34. Preferably, each roller arm 130, 132 comprises a plurality of rollers that are rotationally driven by rotation motors 138. As shown in
The powered rollers 134, 136 each comprise a spiral ramp 200 (
Roller assembly 70 may be operated to impart a tightening spin to a pipe section or other component on the exit side of the bore by rotating the first and second rollers in the opposite direction to that which is used to disengage the pipe section 80. Therefore, motors 138 are preferably bidirectional.
A positioning assembly such as roller assembly cylinder 140 extends between the first roller arm 130 and the second roller arm 132. The roller assembly cylinder 140 is configured to cause relative movement between the opposed roller assemblies in a direction transverse to the frame axis. The cylinder 140 extends parallel to the rails 133. Thus, retraction of the cylinder 140 causes first roller arm 130 and second roller arm 132 to slide along rails 133 toward one another. Changing the separation distance between the first roller arm 130 and second roller arm 132 allows the tool 30 to accommodate multiple diameters of pipes.
In an alternative embodiment of the roller assembly 70, as shown in
The tool 30 may further comprise a control valve assembly (not shown) that is connected to an auxiliary hydraulic circuit of a hydraulic machine such as hydraulic machine 32 (
The control valve assembly may include a radio control receiver that is operatively connected to the hydraulic actuators of the tool 30 and the cylinders 50, 60 (
With reference to
In operation, an operator or automatic controller may utilize the features of the tool 30 to make up and break out sections of pipe from the exit end of drill string 22. Typically, the first phase of operation is breakout, after a drilling machine 20 (
After exiting the borehole, the drill string 22 has a pipe section 80 at its exposed end. The pipe section 80 contacts its adjacent pipe section 81 at a joint. To disconnect the pipe section 80 from the drill string 22, the tool 30 is first moved to position the joint between the first and second vise assemblies 62 and 64.
The attachment assembly 42 permits any pivoting and rotation of the frame 34 that might be needed to position the tool 30 as required. When in position, the first retainer assembly 66 is closed about the pipe segment 81. The second retainer assembly 68 may likewise be closed about the pipe segment 80. The level of the frame 34 relative to the pipe segments 80, 81 may be adjusted using the position cylinders 106 (
The first vise assembly 62 and second vise assembly 64 then grip the pipe segments 80, 81. Pipe segment 80 is rotated by the second vise 64, breaking its high-torque connection with adjacent segment 81. Once this high-torque connection is broken, the second vise 64 is released and roller assembly 70 may rotate the pipe segment 80. Preferably, the ramp 200 on each roller 118 of the roller assembly 70 helps to translate the pipe segment 80 away from adjacent pipe segment 81. When the pipe segment 80 is fully unthreaded, the first retainer 66 and first vise 62 may be opened, and the pipe segment 80 moved to a storage location while being held in second retainer 68.
The second phase of operation, typically, is makeup of product pipe which is pulled back through the borehole 24 by the drilling machine 20, usually behind a backreamer or other hole enlarging mechanism. During makeup, a pipe segment 80 is placed in the second retainer 68 and moved proximate the exit side of the drill string 22 generally, and an adjacent pipe segment 81 specifically. The frame 34 should be rotated and tilted relative to arm 33 in order to orient the pipe segment 80 with a longitudinal axis of the adjacent pipe section 81, as shown in
The first retainer 66 and second retainer 68 may be used in concert to properly position the frame 34 relative to the pipe sections 80, 81 such that they are centered within the vise assemblies 62, 64 and roller assembly 70. The first retainer 66 should close about pipe segment 81 such that it is centered within first vise 62. First vise 62 may then be closed about the pipe segment 81. The pipe segment 80 is then advanced toward pipe section 81 and threaded thereto by operation of the roller assembly 70.
Once threaded, pipe section 80 may be gripped by second vise 64, then rotated by second vise 64 to create a high-torque connection. Once the high-torque connection between segments 80, 81 is complete, the retainer assemblies 66, 68 and vises 62, 64 may be released and the drill string 22 advanced into the exit side 28 of borehole 24 by the drilling machine 20.
While the preferred modes of operation and configurations are disclosed herein, one of ordinary skill in the art could envision alternative designs which would not depart from the spirit of the disclosed and claimed invention.
This application claims the benefit of U.S. Provisional Patent Application Ser. No. 62/288,551 filed on Jan. 29, 2016, the entire contents of which are incorporated herein by reference.
Number | Date | Country | |
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62288551 | Jan 2016 | US |