The present disclosure relates to improved automated floor wrenches for use on a drilling rig. More specifically, an improved automated floor wrench having power tong blocks for centering and gripping the drilling pipe around its circumference is provided.
Automated floor wrenches for drilling rigs are known. Conventionally, automated floor wrenches can comprise two rams opposed to one another, each ram having a pair of tong dies to contact and grip the drilling pipe, or three rams spaced 120 degrees apart around the circumference of the drilling pipe, each ram having a tong die to contact and grip the pipe.
To date, however, known wrenches have various deficiencies and shortcomings. For example, the force required for the dies to contact and grip the pipe can score or damage the pipe surface, resulting in premature pipe wear. The use of two or three rams also requires significant force placed on two, three or even four points on the drill pipe, which can cause the pipe to be squashed or deformed at those points, also resulting in premature wear and service life for the pipe.
Some drilling rig floor wrenches have been developed that can comprise an improved tong assembly having a plurality of articulated tong block, each tong block capable of being interlocked and interchangeable one with another, and each tong block having at least one die ram assembly, such as described in PCT/CA2014/000401.
According to a broad aspect of the present disclosure, there is provided a wrench comprising a tong assembly, the tong assembly comprising: an upper tong comprising a first upper tong half pivotably connected to a second upper tong half at their first ends, the first and second upper tong halves being releasably connectable at their second ends; a lower tong comprising a first lower tong half pivotably connected to a second lower tong half at their first ends, the first and second lower tong halves being releasably connectable at their second ends; a central bearing operatively coupling the upper tong and the lower tong to allow the upper tong to rotate relative to the lower tong; and a ram assembly for pushing or pulling the upper tong at a tangential location thereof; and wherein the ram assembly is configured to move the tong assembly between an open position where the second ends of the first and second upper tong halves and the second ends of the first and second lower tong halves are separated to define a mouth therebetween, and a closed position where the second ends of the first and second upper tong halves and the second ends of the first and second lower tong halves are engaged to defined an opening between the first upper and lower tong halves and the second upper and lower tong halves; wherein the ram assembly is fully retractable to place the tong assembly in the open position; and wherein the ram assembly is partially retractable to place the tong assembly in the closed position.
According to another broad aspect of the present disclosure, there is provided a method of operating a tong assembly of a wrench, the method comprising: opening a tong assembly to provide access to a pipe opening defined therein by retracting a ram assembly coupled to the tong assembly, the tong assembly comprising an upper tong and a lower tong and a central bearing operatively coupling the upper and lower tongs to allow relative rotational movement therebetween, and the ram assembly being coupled to the upper tong and the lower tong; closing the tong assembly by extending the ram assembly, thereby pushing the upper tong at a tangential location thereof; and locking the upper and lower tongs.
According to embodiments herein, an improved automated floor wrench used on a drilling rig floor is provided. The present wrench or improved apparatus 100 comprises a powerful, modular automated floor wrench operative to enhance accuracy and consistency of torque on the drill pipe, enabling easier and faster maintenance, and reducing downtime.
In some embodiments, the present apparatus 100 may provide 360 degrees of radial contact with the drill pipe, reducing slippage, tool joint wear and pipe distortion, and facilitating pipe alignment. Due to the large radial contact around the pipe circumference, the force required to be exerted by each die ram on the pipe during the operation of the wrench is reduced, thereby minimizing potential damage to both the pipe and the wrench itself. It is an advantage that the present apparatus 100 may accommodate varying pipe sizes and longer tool joints, while providing accurate torque on each section of drill pipe. It is a further advantage that the present apparatus 100 may be fully or partially automated, providing a wireless hands-free operating system, increasing overall safety, and allowing for remote measurement and monitoring of data at each pipe connection (thereby improving diagnostics and enabling preventative maintenance). The present apparatus will now be described having regard to
Having regard to
Having further regard to
Positioning system 2 may comprise at least two pivot arms 3a,3b; a first at least one pivot arm 3a operatively connected to and extending from base 8, while at least one second pivot arm 3b is configured to receive tong assembly 50 via lift assembly 4. In this regard, as the base 8 of the positioning system rotates about the first axis, at least two pivot arms 3a,3b and correspondingly the tong assembly 50, also rotates. The at least two pivot arms 3a,3b may be pivotable about pivot joint 5, such pivoting (i.e. extending and retracting) operably powered by at least one hydraulic cylinder, and preferably by at least two hydraulic cylinders 9a,9b.
In this regard, positioning system 2 may be operative to open or close (i.e. between extended or retracted positions) about joint 5; rotate about base 8; and move the lift assembly 4 up or down, so as to manoeuvre the tong assembly 50 about the drilling rig floor (i.e. to and away from the wellbore) with six degrees of freedom. As would be appreciated, the present positioning system 2 significantly reduces the overall footprint of the apparatus 100, and provides that when not in use, the apparatus 100 may be retracted into a closed position and rotated away from the wellbore, for example by about 90 degrees to about 180 degrees from the apparatus' operating position. In
Still with reference to
With reference to
To enable rotational movement between the tongs, tong assembly can comprise a hydraulic ram assembly 58 for pushing one tong at a tangential location relative to the other, and for pulling one tong at a tangential location relative to the other. In one embodiment, to rotate upper tong 52 counter-clockwise relative to lower tong 54 (when viewed from above) to break a pipe joint, the ram assembly 58 pushes the upper tong 52 tangentially. To rotate upper tong 52 clockwise relative to lower tong 54 to make a pipe joint, the ram assembly 58 pulls the upper tong 52 tangentially. It would be understood that the reverse motions could also be used in certain embodiments. The ram assembly 58 and the rotation of the tongs 52,54 relative to one another will be described in more detail below.
Referring to
In some embodiments, wrench 100 may comprise at least one tong torque sensor (not shown) mounted thereon for measuring axial stresses. The tong torque sensor can be mounted between rod pins 61a, 61b and upper and lower ram mounts 57a,57b. In some embodiments, a load cell is provided at each of the rod pins 61a,61b to measure true torque between the upper and lower tongs 52,54.
Referring to
Similarly, lower tong 54 comprises a first lower tong half 66a and a second lower tong half 66b. The first tong half 66a has a body portion having defined therein a substantially semi-circular arc. The second tong half 66b also has a body portion having defined therein a substantially semi-circular arc, which is substantially a mirror image of the arc in the first lower tong half 66a. In some embodiments, the lower ram mount 57b extends outwardly from the second lower tong half 66b near a first end of the arc. The first and second lower tong halves 66a,66b are hinged together and pivotably connected at their respective first ends via pin 69. In some embodiments, the second end of the arc of the second lower tong half 66b comprises a locking pin assembly 68b and the second end of the arch of the first lower tong half 66a comprises a pin pocket 70b having a bore for receiving a pin of the locking pin assembly 68b therethrough. In some embodiments, pin 69 may extend into the mounting pivot 22 of carrier 6 (shown in
Of course, the configuration of the second ends of each of the first and second upper and lower tong halves 56a,56b,66a,66b described above is only one possible configuration. In other embodiments, the placement of the locking pin assemblies and pin pockets may be reversed. In alternative embodiments, the ends of the upper and lower tong halves may comprise connectable male and/or females ends. As one skilled in the art can appreciate, a number of different configurations is possible as long as the second ends of the first and second upper tong halves 56a,56b are connectable and the second ends of the first and second lower tong halves 66a,66b are connectable.
The tong assembly 50 has an open position, shown in at least
In the open position, the second ends of the first upper and lower tong halves 56a,66a are separated from the second ends of the second upper and lower tong halves 56b,66b to define a mouth 90 therebetween. In the open position, the upper and lower rams 58a,58b are in the fully retracted position. In other words, the upper and lower rams 58a,58b are fully retracted to place the tong assembly 50 in the open position.
In the closed position and the rotated closed position, the second ends of the first upper and lower tong halves 56a,66a can be releasably coupled to the second ends of the second upper and lower tong halves 56b,66b, respectively. In the illustrated embodiment, as best shown in
In the closed position and the rotated closed position, the arcs of the first and second upper tong halves 56a,56b form a substantially circular opening 89a. Similarly, the arcs of the first and second lower tong halves 66a,66b form a substantially circular opening 89b.
In the closed position, as shown for example in
In some embodiments, with reference to
In some embodiments, with reference to
Each die ram 74 is disposed in the body portion of each of the tong halves 56a,56b,66a,66b between the first and second ends thereof. The die rams 74 may be evenly spaced throughout the tong halves such that the space between adjacent die rams is substantially the same in each of the upper and lower tongs 52,54. In the illustrated embodiment, as shown in
In some embodiments, as best shown in
With reference to
In some embodiments, the upper and lower cartridge plates 34 have one or more aligning pairs of torque reaction pockets 28, each pair for matingly receiving a corresponding torque reaction bar 17 of the upper or lower tong 52,54. The torque reaction pockets 28 and torque reaction bars 17 are for facilitating the transfer of torque from the cartridge 79 to the upper and lower tongs 52,54 when the wrench 100 is in operation, as will be explained in more detail below. More specifically, in operation, torque is transferred from the dies 80 through the die guides 76 into cartridge plates 34 and then into the upper and lower tongs 52,54.
With reference to
When a die cartridge 79 is received in each of the tong halves 56a,56b,66a,66b, and when the tong assembly 50 is in the closed position and the rotated closed position, the die cartridges in the upper and lower tongs 52, 54 define an open cylindrical space or “pipe opening” 88 therebetween. The diameter of the pipe opening 88 depends on the inner radius of the die cartridges 79. Preferably, all four die cartridges 79 used in the tong assembly 50 at any one time are similarly sized such that they all have about the same inner radius to provide concentric closure into opening 88. Accordingly, the diameter of pipe opening 88 can be increased or decreased by selecting die cartridges 79 with a larger or smaller inner radius, respectively.
As best shown in
Since the diameter of pipe opening 88 depends on the inner radius of the die cartridge 79 and/or since the dies 80 in the die cartridge have a grip range, one size and configuration of die cartridges 79 can be used to handle and manipulate a range of pipes of different sizes, without modifying any component of the wrench 100. In some embodiments, the diameter of pipe opening 88 can range from about 3″ to about 113/4″ to accommodate pipe sizes of about 23/8″ to about 11″. Further, since die cartridges 79 are removable, one set of die cartridges can be replaced with another set having a different inner radius and/or grip range to accommodate smaller or larger diameter pipes. In some embodiments, the inner radius and/or the grip range of the die cartridges 79 are selected depending on the size of the rig in order to eliminate or minimize the need to switch out the die cartridges.
In some embodiments, hydraulic fluid is supplied to all the die ram housings 82 in each tong 52,54 simultaneously such that the corresponding dies 80 can all extend synchronously. In further embodiments, hydraulic fluid is supplied to all the die ram housings 82 through a volumetric flow divider to each tong 52,54 simultaneously to help equalize the volume of oil delivered to each die ram 74. Referring to
To open mouth 90 of the tong assembly 50 to receive a drill pipe in pipe opening 88, as shown for example in
With reference to
Referring to
To make a joint, the dies 80 in the lower tong 54 are extended substantially synchronously by their corresponding die rams 74 to contact the drill pipe using a predetermined minimum hydraulic pressure, after the upper and lower tongs are locked. The upper and lower rams 58a,58b are then extended to the extended position, thereby rotating the upper tong 52 counterclockwise relative to the lower tong 54 and placing the tong assembly in the rotated closed position as best shown in
To break a joint, the dies 80 in the lower tong 54 are extended substantially synchronously by their corresponding die rams 74 to contact the drill pipe using a predetermined minimum hydraulic pressure, after the upper and lower tongs are locked. The dies 80 in the upper tong 52 are extended substantially synchronously by their corresponding die rams 74 to contact the drill pipe, either simultaneously with or immediately after the extension of dies 80 in the lower tong 54 using a predetermined minimum hydraulic pressure. Once the drill pipe is gripped by both the upper and lower tongs 52,54, the upper and lower rams 58a,58b are extended to the extended position, as best shown in
The synchronization of the extension of the dies 80 in tong assembly 50 helps to keep the section of the drill pipe in upper tong 52 aligned and concentric with the other section of the drill pipe in the lower tong 54.
After making or breaking the joint, the upper and lower tongs 52,54 are unlocked by deactivating lock pins 72a,7b. Once unlocked, the tong assembly 50 can be opened by fully retracting the rams 58a,58b, as shown in
The incorporation of six die rams 74 in each tong, as shown in the illustrated embodiment, can enable the equal distribution of gripping force around the circumference of drill string 48 and prevent the crushing or squashing of drill string 48 such it becomes out of round when gripped by die rams 74. In addition, by distributing the gripping forces in multiple locations around the circumference of the drill string, less force per die ram 74 can be used to prevent deep scoring on the drill string caused by dies 80, which can occur if fewer die rams are used to grip the drill string, such as are found on similar apparatuses using only two or three die rams.
The mounting pivot 22 of carrier 6 is configured to allow the lower tong 54 to rotate in the event of slippage in the interface between the dies 80 and the pipe or when the lower tong 54 is improperly used as a backup for the spinner assembly (i.e., where the tong assembly 50 is used as a backup wrench such that all the torque is transferred to the positioning system 2 and into the rig floor).
In some embodiments, wrench 100 may comprise at least one carrier torque sensor mounted thereon for measuring rotational stresses. The carrier torque sensor can be mounted between positioning system 2 and tong assembly 50. In a sample embodiment shown in
In some embodiments, wrench 100 comprises a control system for controlling the operation of hydraulic rams and motors of the wrench 100. The control system can comprise one or more components selected from the group consisting of hydraulic fluid cylinders, hydraulic fluid pumps, hydraulic fluid tanks, hydraulic fluid coolers, hydraulic fluid filters, hydraulic fluid hoses, hydraulic fluid control valves and programmable logic controllers as well known to those skilled in the art.
In operation, by placing the carrier torque sensor between one of the pins extending downwardly from tong assembly 50 and carrier 6 at pivot 22, rotational force between tong assembly 50 and carrier 6 can be monitored. It is known that when automated floor wrenches are used on drilling rigs using top drives for rotating the drill string, drilling operators have been known to use the top drive to make joints between sections of drill pipe instead of using the automated floor wrench. Top drives can produce large amounts of torque, far more than what is necessary to properly torque sections of drill pipe together. Using the top drive to make the joints can apply excessive rotational force to the automated floor wrench, which is still being used to grip to lower section of drill pipe, and cause damage to the floor wrench. By incorporating the carrier torque sensor in the mounting of tong assembly 50 to carrier 6 at pivot 22, the carrier torque sensor can be used to sense when excessive rotational force is applied to the wrench 100. When excessive rotational force is applied to lower tong 54, carrier torque sensor can send a signal to the control system that can, in turn, cause tong assembly 50 to release any pipe gripped by it. In the instance when wrench 100 is used with a top drive drilling rig, and its operators simply use wrench 100 to grip the drill string with lower tong 54 and use the top drive to make joints with the drill string, the carrier torque sensor can be used to sense when the rotational force is applied to longer tong 54 by the top drive exceeds a predetermined threshold, and send a signal to the control system to cause lower tong 54 to release the drill string, thereby preventing damage to wrench 100. In further embodiments, the control system can also shut down the operation of the top drive and any other system that was operating prior to the carrier torque sensor sending the signal to the control system.
In other operational situations, such as during break-out operations, it is known that a drill string can slip in a lower tong when the upper tong is trying to break a joint in adjacent sections of pipe in the drill string. When this occurs, excessive rotational forces can occur in lower tong 54, which can damage carrier 6 and positioning system 2. By connecting the carrier torque sensor between lower tong 54 and carrier 6 at pivot 22, such rotational forces can be detected by the carrier torque sensor. When the rotational forces exceed a predetermined threshold, the carrier torque sensor can send a signal to the control system to, in turn, cause tong assembly 50 to release the drill string. In further embodiments, the control system also shut down the operation of the top drive and any other system that was operating prior to the carrier torque sensor sending the signal to the control system. Using a single ram assembly to both (i) open and close the tong assembly and (ii) rotate the upper tong relative to the lower tong provides the tong assembly 50 of the present disclosure more capacity in terms of rotational engagement and torque than previous floor wrenches of the same footprint. Further, the synchronous movement of the upper and lower rams 58a,58b of the tong assembly 50 allows the wrench 100 to provide more torque as well as more rotational per grip than its predecessors. In one embodiment, the wrench 100 can provide a maximum break out torque of about 150,000 lbs , a maximum make up torque of about 130,000 lbs, a nominal pressure of about 2500 (dif) psi, and a maximum pressure of about 3000 psi.
The tong assembly 50 of the present disclosure only has two tong halves in each tong as opposed to at least four tong sections in each tong of the predecessors. The simplicity of the configuration of tong assembly 50 may reduce manufacturing and/or maintenance costs.
Accordingly, a wrench for making up or breaking up a pipe joint is provided. The wrench comprises a tong assembly comprising: an upper tong comprising a first upper tong half pivotably connected to a second upper tong half at their first ends, the first and second upper tong halves being releasably connectable at their second ends;
a lower tong comprising a first lower tong half pivotably connected to a second lower tong half at their first ends, the first and second lower tong halves being releasably connectable at their second ends; a central bearing operatively coupling the upper tong and the lower tong to allow the upper tong to rotate relative to the lower tong; and a ram assembly for pushing or pulling the upper tong at a tangential location thereof; and wherein the ram assembly is configured to move the tong assembly between an open position where the second ends of the first and second upper tong halves and the second ends of the first and second lower tong halves are separated to define a mouth therebetween, and a closed position where the second ends of the first and second upper tong halves and the second ends of the first and second lower tong halves are engaged to defined an opening between the first upper and lower tong halves and the second upper and lower tong halves; wherein the ram assembly is fully retractable to place the tong assembly in the open position; and wherein the ram assembly is partially retractable to place the tong assembly in the closed position.
In one embodiment, the tong assembly further comprises a first rotated closed position where the second ends of the first and second upper tong halves are securely connected; the second ends of the first and second lower tong halves are securely connected; and the ram assembly is extended to rotate the upper tong counterclockwise relative to the lower tong.
In one embodiment, the tong assembly further comprises a second rotated closed position where the second ends of the first and second upper tong halves are securely connected; the second ends of the first and second lower tong halves are securely connected; and the ram assembly is partially retractable or fully retractable to rotate the upper tong clockwise relative to the lower tong.
In one embodiment, the wrench further comprises a die cartridge removably receivable in each of the first and second upper tong halves and the first and second lower tong halves, the die cartridge comprising one or more dies, and the one or more dies are extendable radially inwardly substantially toward a center of the opening and retractable therefrom; and wherein when the tong assembly is in the closed position, a pipe opening is defined between the die cartridges.
In one embodiment, each of the first and second upper tong halves and the first and second lower tong halves comprises one or more die rams configured to extend and retract the one or more dies.
In one embodiment, the one or more die rams in the first upper tong half and the one or more die rams in the second upper tong half are configured to synchronously extend the one or more dies in the first upper tong half and the one or more dies in the second upper tong half and the one or more die rams in the first lower tong half and the one or more die rams in the second lower tong half are configured to synchronously extend the one or more dies in the first lower tong half and the one or more dies in the second lower tong half.
In one embodiment, the ram assembly comprises an upper ram and a lower ram, the upper ram being pivotably coupled at a first end to the upper tong and at a second end to the lower tong, and the lower ram being pivotably coupled at a first end to the lower tong and at a second end to the upper tong.
In one embodiment, the upper and lower rams are extendable or retractable substantially synchronously.
In one embodiment, the first end of the upper ram is pivotably coupled to the upper tong at or near the first end of the first upper tong half and the second end of the upper ram is pivotably coupled to the lower tong at or near the first end of the second lower tong half.
In one embodiment, the first end of the lower ram is pivotably coupled to the lower tong at or near the first end of the second lower tong half; and the second end of the lower ram is pivotably coupled to the upper tong at or near the first end of the first upper tong half
In one embodiment, the upper ram is coupled to the lower tong by a first rod pin and the lower ram is coupled to the upper tong by a second rod pin.
In one embodiment, the wrench further comprises a torque sensor disposed at the first rod pin and/or the second rod pin.
In one embodiment, the second ends of the first and second uppers tong halves and/or the second ends of the first and second upper tong halves are securably connectable by a lock pin.
In one embodiment, the wrench further comprises a rotatable positioning system, and wherein the tong assembly is secured to and supported on the positioning system, the positioning system being mountable to a drilling rig floor.
In one embodiment, the wrench further comprises a torque sensor disposed between the tong assembly and the positioning system.
In one embodiment, the wrench further comprises a control system for controlling the operation of the tong assembly.
In one embodiment, the wrench further comprises a carrier, and wherein the lower tong is secured to and supported on the carrier.
A method of operating a tong assembly of a wrench is also provided. The method comprises: opening a tong assembly to provide access to a pipe opening defined therein by retracting a ram assembly coupled to the tong assembly, the tong assembly comprising an upper tong and a lower tong and a central bearing operatively coupling the upper and lower tongs to allow relative rotational movement therebetween, and the ram assembly being coupled to the upper tong and the lower tong; closing the tong assembly by extending the ram assembly, thereby pushing the upper tong at a tangential location thereof; and locking the upper and lower tongs.
In one embodiment, the method further comprises inserting and securing a die cartridge in each half of the upper and lower tongs, wherein the die cartridge comprises one or more dies and each half having one or more die rams for operatively engaging the one or more dies.
In one embodiment, the ram assembly comprises an upper ram and a lower ram, the upper ram being pivotably coupled at a first end to the upper tong and at a second end to the lower tong, and the lower ram being pivotably coupled at a first end to the lower tong and at a second end to the upper tong.
In one embodiment, the upper and lower rams are extendable or retractable substantially synchronously.
In one embodiment, the method further comprises, after opening the tong assembly and before closing the tong assembly, receiving a pipe joint in the pipe opening.
In one embodiment, the method further comprises, after locking the upper and lower tongs, securely engaging the pipe joint by extending the one or more dies in the lower tong radially inwardly using the one or more die rams in the lower tong.
In one embodiment, the method further comprises: rotating the upper tong counterclockwise relative to the lower tong by extending the ram assembly; securely engaging the pipe joint by extending the one or more dies in the upper tong radially inwardly using the one or more die rams in the upper tong; rotating the upper tong clockwise relative to the lower tong by retracting the ram assembly; retracting the one or more dies in the upper and lower tongs; unlocking the upper and lower tongs; and reopening the tong assembly to remove the pipe joint from the tong assembly.
In one embodiment, the method further comprises: securely engaging the pipe joint by extending the one or more dies in the upper tong radially inwardly using the one or more die rams in the upper tong; rotating the upper tong counterclockwise relative to the lower tong by extending the ram assembly; retracting the one or more dies in the upper tong; rotating the upper tong clockwise relative to the lower tong by retracting the ram assembly; retracting the one or more dies in the lower tong; unlocking the upper and lower tongs; and reopening the tong assembly to remove the pipe joint from the tong assembly.
Although a few embodiments have been shown and described, it will be appreciated by those skilled in the art that various changes and modifications can be made to these embodiments without changing or departing from their scope, intent or functionality. The terms and expressions used in the preceding specification have been used herein as terms of description and not of limitation, and there is no intention in the use of such terms and expressions of excluding equivalents of the features shown and described or portions thereof.
This Application claims priority to U.S. Provisional Patent Application No. 62/578,676, entitled “An improved automated floor wrench for a drilling rig”, filed Oct. 30, 2017, the entirety of which is hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/CA2018/051379 | 10/30/2018 | WO | 00 |
Number | Date | Country | |
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62578676 | Oct 2017 | US |