Not applicable.
Not applicable.
This invention relates to a tool wrench assembly for joining and separating segments of a segmented drill pipe in a blasthole drill.
A drilling rig is conventionally used in surface mining and quarrying operations. Many of these rigs are mounted on a vehicle that travels on wheels or tractor crawlers to move the drilling rig to the desired drilling location. Once positioned, a rotary head drives a drill bit to begin the drilling operation.
However, it is impractical for these rigs to have a one-piece drill bit. As these rigs drill deep into the earth, the bit would need to be as long as the deepest possible drill depth. At these lengths, it would be difficult to transport the bits and would require undesirably large masts for support. Moreover, the tip of the drill dulls during use, requiring frequent replacement. It is much more cost effective to replace only the drill tip portion of the drill bit on an as-needed basis.
Hence, most drilling rigs have segmented drill pipe strings. These drill pipe strings include multiple drill pipe segments that are attached together at screw threads. At the lowermost end of the pipe string, the drill bit is attached.
During joining or separation of the drill pipe segments, one of the segments must be held in place while an adjacent segment is rotated to thread or unthread the segments from one another. Typically, a tool wrench engages the flats on the lower segment or otherwise grips it to prevent it from rotating. See e.g., U.S. Pat. Nos. 3,980,143; 5,931,231; 5,996,444; and 6,298,926. See also, U.S. patent publication 2003/0056989. The tool wrench is extended to engage the flats as necessary and is then removed before the drill pipe string is again raised or lowered. The tool wrench may also temporarily support the weight of the drill pipe string when the drill pipe string is not directly attached to the rotary head.
However, particularly during the lifting or withdrawal of the drill pipe segments, an operator may forget to disengage the tool wrench from the flats of the drill pipe segment. This can potentially damage the tool wrench, the components that actuate the tool wrench, and/or the rotary head to which the drill pipe string is attached.
Hence, there is a need for an improved tool wrench assembly. In particular, there is a need for a drilling rig with a tool wrench assembly that is less prone to damage as a result of the inadvertent raising of the pipe string.
A tool wrench assembly is disclosed. The tool wrench assembly includes a base, a first actuator fixed to the base, and a second actuator fixed to the base. The second actuator is spaced from and is parallel to the first actuator. A fork is pivotally fixed relative to, and extends between, the first actuator and the second actuator. The first actuator and the second actuator move the fork relative to the base upon actuation of the first actuator and the second actuator.
Thus, a tool wrench assembly is provided with a fork that flips up to disengage the fork from the flats of the drill pipe when the drill pipe is lifted without first disengaging the fork by movement of the actuators. Further, the tool wrench assembly has a structure that provides for the fork to engage the flats of drill pipe segments when the actuators (such as, for example, hydraulic cylinders) are moved into a retracted position. In a retracted position, the actuators are less prone to bending damage resulting from inadvertent lifting. These features, as well as others that will be described below, make the tool wrench assembly less susceptible to damage than other tool wrench assemblies.
These and still other advantages of the invention will be apparent from the detailed description and drawings. What follows is merely a description of some preferred embodiments of the present invention. To assess the full scope of the invention the claims should be looked to as these preferred embodiments are not intended to be the only embodiments within the scope of the claims.
Referring first to
The mast 16 supports many of the drilling components. On the top of the mast 16, a rotary drill head 22 is mounted to a pull-down mechanism 24. The pull-down mechanism 24 travels up and down the side cords of the mast 16 on a rack of teeth. The rotary drill head 22 includes a rotary drive which engages the top of a drill pipe string 26. A drill pipe magazine 28 contains storage for drill pipe segments that can be added to or removed from the drill pipe string 26. At the lower end of the drill pipe string 26, a drill bit 29 is attached to the bottom segment of the drill pipe string 26.
Referring now to
The base 32 (and any underlying portion of the main deck frame 12) has a hole 40 extending there through. Although not shown in
It should be appreciated that although the hole 40 is shown in the base 32 and main deck frame 12, that a U-shaped cutout or other non-closed form could likewise provide the necessary path for the drill pipe string 26 or drill bit 29.
The components of the tool wrench assembly 30 are placed around the hole 40. The first hydraulic cylinder 34 and the second hydraulic cylinder 36 are attached to the base 32 on opposing sides of the hole 40. In particular, the first cylinder 34 and the second cylinder 36 are linked to the base 32 at a first bracket 42 and a second bracket 44, respectively. The first and second brackets 42 and 44 may be integrally formed with the base 32 or may be attached to the base 32. A pair of rails 45 extend over the brackets 42 and 44, the cylinders 34 and 36, and a portion of the fork carriage 38 to vertically restrain these components.
Generally speaking, each of the cylinders 34 and 36 have a body with an actuating piston that extends there from. In the embodiment shown, the body ends 34a and 36a of the each of the cylinders 34 and 36 are pivotally attached to the brackets 42 and 44 about vertical pivot axes. The piston ends 34b and 36b of each of the cylinders 34 and 36 connects to the fork carriage 38 to move the fork carriage 38 between an extended position and a retracted position.
The fork carriage 38 includes a fork 48 pivotally connected to a slidable carriage plate assembly 50. The fork 48 is interposed between a pair of end plates 46 fixed to the slidable carriage plate assembly 50. Each of the pair of end plates 46 is connected to one of the piston ends 34b and 36b to connect the fork carriage 38 to the cylinders 34 and 36. As shown, the connection between the cylinders 34 and 36 the brackets 42 and 44 and the cylinders 34 and 36 and the pair of end plates 46 are pivotally hinged to allow for some tolerance in the positioning of the cylinders 34 and 36 as the fork carriage 38 moves.
The fork 48 is shaped to engage the flats of a drill pipe segment or the drill bit 29. The fork 48 has a body 52 with two prongs 54 extending forwardly therefrom to provide a generally U-shaped engagement recess 56. The two prongs 54 are essentially parallel to one another and likewise form two flats 58 that are essentially parallel with one another. The back side of the fork 48 has a curved portion 60 formed between a rear face 62 and a bottom face 64 of the fork 48.
The pair of end plates 46 are positioned on the lateral sides of the fork 48 such that the fork 48 extends between the first hydraulic cylinder 34 and the second hydraulic cylinder 36. A shaft 66 runs through the pair of end plates 46 and the fork 48 and pivotally fixes the fork 48 relative to the first hydraulic cylinder 34 and the second hydraulic cylinder 36. The shaft 66 defines a pivot axis 68 about which the fork 48 pivots.
The pair of end plates 46 are also linked to the slidable carriage plate assembly 50. The slidable carriage plate assembly 50 has outwardly extending guides 70 on either side that are received in and travel along pair of slots 72 formed in the base 32. The outwardly extending guides 70 vertically restrain the slidable carriage plate assembly 50 against the vertical forces exerted on the fork 48 during operation.
During operation, the tool wrench assembly 30 can be actuated between the extended position (shown in
As the dual hydraulic cylinders 34 and 36 are in a retracted position when the fork 48 engages the drill pipe segment, the tool wrench assembly 30 is less prone to damage from the applied torque. Given the spatial arrangement of the components of the tool wrench assembly 30, when the fork 48 is drawn into engagement with the pipe segment, the dual hydraulic cylinders 34 and 36 are retracted. In the retracted position, the cylinders 34 and 36 are less susceptible to bending, tensile failure or the like as the piston is secured in the body.
Although the fork 48 is usually in an essentially horizontal position, it can flip up to a position that deviates from the essentially horizontal position as shown in
This flip-up action may be desirable, for example, when withdrawing the drill pipe string 26 from the ground. As each of the segments are unthreaded from one another, the fork 48 will temporarily support an unattached drill pipe string on the top face 74 of the fork 48 until the rotary drill head 22 is rethreaded to the pipe string. Once the rotary drill head 22 is attached to the pipe string, the string is again withdrawn. Although the operator typically removes the fork 48 from engagement with the flats of the segment before continuing to lift the drill pipe string 26, sometimes this step is forgotten. In the event that the fork 48 is not disengaged from the segment, the fork 48 can pivotally flip up to disengage the flats 58 of the fork 48 from the flats of the segment. In this way, the segment is freed from the fork 48, even thought the hydraulic cylinders 34 and 36 have not been actuated to disengage the fork 48 from the segment.
The tool wrench assembly 30 may be a component that is installed into a main deck frame 12 or the tool wrench assembly 30 could use the main deck frame 12 as the base. If the tool wrench assembly 30 is a separate component, then it may be secured to the main deck frame 12 by the bolting the tool wrench assembly 30 to the base 32 by inserting bolts into bolt holes in the base 32. The base 32 could also be welded or joined in some other way to the main deck frame 12.
It should be appreciated that the although the embodiment shown uses two hydraulic cylinders 34 and 36, that any actuator or actuation mechanism could be used in their place.
It should be appreciated that various other modifications and variations to the preferred embodiments can be made within the spirit and scope of the invention. Therefore, the invention should not be limited to the described embodiments. To ascertain the full scope of the invention, the following claims should be referenced.
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Number | Date | Country | |
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20100200258 A1 | Aug 2010 | US |